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THEORY OF CALORIMETRY
Hot Topics in Thermal Analysis and Calorimetry
Volume 2
Series Editor:Judit Simon, Budapest University of Technology and Economics, Hungary
The titles published in this series are listed at the end of this volume.
Theory of Calorimetry
by
Wojciech Zielenkiewicz Institute of Physical Chemistry,
Polish Academy of Sciences, Warsaw, Poland
and
Eugeniusz Margas Institute of Physical Chemistry,
Polish Academy of Sciences, Warsaw, Poland
KLUWER ACADEMIC PUBLISHERS NEW YORK, BOSTON, DORDRECHT, LONDON, MOSCOW
eBook ISBN: 0-306-48418-8 Print ISBN: 1-4020-0797-3
©2004 Kluwer Academic Publishers New York, Boston, Dordrecht, London, Moscow
Print ©2002 Kluwer Academic Publishers Dordrecht
All rights reserved
No part of this eBook may be reproduced or transmitted in any form or by any means, electronic, mechanical, recording, or otherwise, without written consent from the Publisher
Created in the United States of America
Visit Kluwer Online at: http://kluweronline.com and Kluwer's eBookstore at: http://ebooks.kluweronline.com
Contents
Preface ix
Chapter 1The calorimeter as an object with a heat source 1
1.1. The Fourier law and the Fourier-Kirchhoff equation 21.2. Heat transfer. Conduction, convection and radiation 101.3. General integral of the Fourier equation. Cooling and heating processes 141.4. Heat balance equation of a simple body. The Newton law of cooling 20 1.5. The heat balance equations for a rod and sphere 261.6. General heat balance equation of a calorimetric system 33
Chapter 2Calorimeters as dynamic objects 37
2.1. Types of dynamic objects 392.2. Laplace transformation 412.3. Dynamic time-resolved characteristics 472.4. Pulse response 552.5. Frequential characteristics 582.6. Calculations of spectrum transmittance 612.7. Methods of determination of dynamic parameters 66
2.7.1. Determination of time constant 662.7.2. Least squares method 742.7.3. Modulating functions method 762.7.4. Rational function method of transmittance approximation 792.7.5. Determination of parameters of spectrum transmittance 81
vi
85
CONTENTS
Chapter 3Classification of calorimeters. Methods of determination
of heat effects 3.1.Classification of calorimeters 85 3.2. Methods of determination of heat effects 97
3.2.1. General description of methods of determination of heat ef-
3.2.2. Comparative method of measurements 101
3.2.4. Multidomains method 1043.2.5. Finite elements method 1093.2.6. Dynamic method 1113.2.7. Flux method 1143.2.8. Modulating method 1143.2.9. Steady-state method 1163.2.10. Method of corrected temperature rise 119
3.2.11.1 Harmonic analysis method 1233.2.11.2. Method of dynamic optimization 1243.2.11.3. Thermal curve interpretation method 1253.2.11.4. Method of state variables 1273.2.11.5. Method of transmittance decomposition 1283.2.11.6. Inverse filter method 129
fects 97
Adiabatic method and its application in adiabatic and scanning adiabatic calorimetry 103
Numerical and analog methods of determination
of thermokinetics 123
Evaluation of methods of determination of total heat effectsand thermokinetics 131
3.2.11.7.
3.2.11.
3.2.3.
3.3. Linearity and principle of superposition 136
Chapter 4Dynamic properties of calorimeters 139
4.1. Equations of dynamics 1394.2. Dynamic properties of two and three-domain calorimeters with
cascading structure 1434.2.1. Equations of dynamics. System of two domains in series 1434.2.2. Equations of dynamics. Three domains in series 1484.2.3. Applications of equations of dynamics of cascading systems 151
CONTENTS vii
4.3. Dynamic properties of calorimeters with concentric configuration 154 4.3.1. Dependence of dynamic properties of two-domain calorimeter
with concentric configuration on location of heat sources and temperature sensors 155
4.3.2. Dependence between temperature and heat effect as a function of location of heat source and temperature sensor 165
4.3.3. Apparent heat capacity 168 4.3.4. Energy equivalent of calorimetric system 171
Final remarks 177
References 179
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Preface
Calorimetry is one of the oldest areas of physical chemistry. The date on which calorimetry came into being may be taken as 13 June 1783, the day on which Lavoisier and Laplace presented a contribution entitled ,,Memoire de la Chaleur“ at a session of the Academie Française. Throughout the existence of calorimetry, many new methods have been developed and the measuring techniques have been improved. At present, numerous laboratories worldwide continue to focus attention on the development and applications of calorimetry, and a number of companies specialize in the production of calorimeters.
The calorimeter is an instrument that allows heat effects in it to be determined by directly measurement of temperature. Accordingly, to determine a heat effect, it is necessary to establish the relationship between the heat effect generated and the quantity measured in the calorimeter. It is this relationship that unambiguously determines the mathematical model of the calorimeter. Depending on the type of calorimeter applied, the accuracy required, and the conditions of heat and mass transfer that prevail in the device, the relationship between the measured and generated quantities can assume different mathematical forms.
Various methods are used to construct the mathematical model of a calorimeter. The theory of calorimetry presented below is based on the assumption of the calorimeter as an object with a heat source, and as a dynamic object with well-defined parameters. A consequence of this assumption is that the calorimeter is described in terms of the relationships and notions applied in heat transfer theory and control theory. With the aim of a description and analysis of the courses of heat effects, the method of analogy is applied, so as to interrelate the thermal and the
x PREFACE
dynamic properties of the calorimeter. As the basis on which the thermal properties of calorimeters will be considered, the general heat balance equations are formulated and the calorimeter is taken as a system of linear first-order inertial objects.
The dynamic properties of calorimeters are defined as those corresponding to proportional, integrating and inertial objects. Attention is concentrated on calorimeters as inertial objects. In view of the fact that the general mathematical equations describing the properties of inertial objects contain both integrating and proportional terms, a calorimeter with only proportional or integrating properties is treated as a particular case of an inertial object.
The thermal and dynamic properties that are distinguished are used as a basis for the classification of calorimeters. The methods applied to determine the total heat effects and thermokinetics are presented. For analysis of the courses of heat effects, the equation of dynamics is formulated. This equation is demonstrated to be of value for an analysis of various thermal transformations occurring in calorimeters.
The considerations presented can prove to be of great use in studies intended to enhance the accuracy and reproducibility of calorimetric measurements, and in connection with methods utilized to observe heat effects in thermal analysis.
Chapter 1
The calorimeter as an object with a heat source
A calorimeter can be treated as a physical object with active heat sources inside it. An analysis of the thermal processes occurring inside the calorimeter, and those between the calorimeter and its environment, requires utilization of the laws and relations defined by heat transfer theory [1–5].
The relations arising from heat transfer theory are applied to design the mathematical models of calorimeters, which express the dependence of the change in temperature measured directly as a function of the heat effect produced. There is an understandable tendency to attempt to express these models in the simplest way. In practice, this is achieved by applying simplifications to the original formulas. To make use of them wisely, one has to understand precisely the assumptions made. This chapter will present a detailed consideration of this topic.
Selected problems from heat transfer theory are also presented. Special attention is paid to a discussion of the processes occurring in a non-stationary heat transfer state. An understanding of these processes is of importance for a proper interpretation of calorimetric measurements. The general heat balance equation is introduced into the considerations. Particular forms of this equation will be applied to consider problems that form the subject of this book.
2 CHAPTER 1
1.1 The Fourier law and the Fourier-Kirchhoffequation
Heat transfer by conduction in a homogenous, isotropic body is mathematically described by the Fourier law [1]:
qture gradient q
Q P per
which assumes proportionality between the heat flux and the tempera grad T. The heat flux , in is a vector determin
ing the rate of heat transferred through unit surface at pointunit time dt (Fig. 1.1):
or
Quantity T in Eq. (1.1) is a function of the coordinates x, y, z and time t. For any time t the value of T determines the scalar temperature field. At every point upon it, the temperature at this instant is the same. Such a surface is called the isothermal surface for temperature T.
The gradient of temperature, grad T, is a vector:
At points of an isothermic surface, the absolute gradient values are equal to
where -drawn line normaldenotes differentiation along an outwardto the surface. The value of is an experimentally determined coefficient called the thermal conductivity, expressed in
3 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
defines the amount of heat conducted through unit area in unit time if a unit of temperature gradient exists across the plane in which the area is measured. The value of for isotropic materials is a scalar, its value depending on pressure and temperature changes. If the range of temperature is limited, the variation in may not be large and as a reasonable approximation it can be assumed to be constant. The reciprocal of the thermal conductivity of a material is called its thermal resistivity.
The relation between the heat energy, expressed by the heat flux q, and its intensity, expressed by temperature T, is the essence of the Fourier law, the general character of which is the basis for analysis of various phenomena of heat considerations. The analysis is performed by use of the heat conduction equation of Fourier-Kirchhoff. Let us derive this equation. To do this, we will consider the process of heat flow by con
ronment of temperature duction from a solid body of any shape and volume V located in an envi-
[5,6]. When heat is generated in the body, two processes can occur: the ac
cumulation of heat and heat transfer between the body and its environment. Thus, the amount of heat generated, dQ, corresponds to the sum of the amount of heat accumulated, and the amount of heat exchanged,
4 CHAPTER 1
The heat flux through a surface element dS in time dt, in conformity with Eq. (1.5), corresponds to
where dS = ndS is a normal vector to a surface element in the external direction, so that the amount of heat transferred through the whole
surface S in time dt is equal to
On application of the Gauss-Ostrogrodsky theorem, which states that the surface integral of a vector is equal to the volume integral of the divergence of the vector, Eq. (1.8) becomes
The amount of heat generated in the body by the inner heat
sources of density g (the amount of heat developed by unit volume in unit time) in element dV of volume V in time dt is equal to
Thus, the heat generated in the total volume V of the body in time dt is equal to
The amount of heat accumulated, according to Eq. (1.6), is equal
to
When Eqs (1.9) and (1.11) are taken into account, Eq. (1.12) can be written in the form
5 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
According to the First Law of Thermodynamics, the amount of heat accumulated, can be described for each volume element of the body as
where dh is the increase in specific enthalpy (due to unit volume), and p is pressure.
The increase in specific enthalpy is proportional to the increase dT in temperature T:
where is the specific heat capacity at constant pressure, in
and is the density, expressed in The increase in enthalpy in
the body of volume V is equal to
The second term on the right-hand side of Eq. (1.14) may be written as
With regard to Eqs (1.16) and (1.17), Eq. (1.12) becomes
Comparison of both sides of Eqs (1.13) and (1.18) gives
Equation (1.19) is valid in any element of the body if
Division of both sides of Eq. (1.20) by dt gives
6 CHAPTER 1
On introduction of Eqs (1.15) and (1.1), Eq. (1.21) can be written in the form
For a solid body with a distribution of temperature T at time t given by
we have
Thus, the substantial derivative of temperature takes the form
Introduction of the velocity vector w
into Eq. (1.25) lends to
In a similar way, pressure changes as a function of (x, y, z, t) can be expressed by
7 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
Substitution of Eqs (1.27) and (1.28) into Eq. (1.22) yields
Equation (1.29) is called the Fourier-Kirchhoff equation. When the process takes place under isobaric conditions, i.e.
the Fourier-Kirchhoff equation (Eq. (1.29)) takes the form
When the velocity vector is equal to zero, i.e.
Eq. (1.31) becomes
Equation (1.33) is called the Fourier equation or the equation of conduction of heat.
Let us use the Fourier equation to consider the following processes: a) Stationary (steady-state) heat transfer, which occurs when the changes in temperature T are not time-dependent:
and the distribution of temperature is a function only of the Cartesian coordinates (x,y, z). Relation (1.34) is fulfilled, when g = const, b) A non-stationary (non-steady-state) heat transfer process, which takes place when the changes in temperature T are time-dependent:
8 CHAPTER 1
When g = 0, the temperature changes depend only on the initial distribution of temperature. They characterize the heating or cooling processes occurring in the thermal by passive body.
The investigation of heat processes for which
is the subject of great numbers of calorimetric determinations. When and are constants independent of both pressure and
temperature, parameter a is often applied:
This is called the thermal diffusivity coefficient, expressed in Introduction of coefficient a into Eq. (1.33) gives
where is a Laplace operator: The Fourier-Kirchhoff differential equation and the equation of con
duction of heat describe the transfer of heat in general form. In order to obtain the particular solutions of these equations, it is necessary to determine the initial and boundary conditions.
The initial conditions are be to understood in that the temperature throughout the body is given arbitrarily at the instant taken as the origin of the time coordinate t. It is usually assumed that the temperature at the beginning of the process is constant. For steady-state processes, the course of the temperature changes does not depend on the initial conditions.
The boundary conditions prescribe:
9 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
a) Dimensionless parameters which characterize the shape and dimensions of the body. An example is a homogenous ball with radius R, where
In the spherical system, is expressed by
In the case of a cylinder, it is convenient to operate with cylindrical coordinates r, x in which the Laplacian has the form
where
b) Physical parameters such as specific heat density and thermalconductivity coefficient which characterize the properties of the bodyand the environment. It is determined that they are constant or a functionof temperature. In all the problems discussed in this book, it is consid-ered that and are constants.c) Surface conditions. These conditions are as follows:
1. The prescribed temperature distribution on the surface S of the body:
2. The prescribed distribution of the heat flux or temperature gradient on the surface of S of the body:
3. The defined relation between the temperature and the heat flux on the surface S of the body:
10 CHAPTER 1
where is the surface heat transfer coefficient (see § 1.2). Mixed boundary conditions, which are subsequent to the assumption
that particular parts of surface S are characterized by various types of boundary conditions, can also be used. d) The form of function g, which describes the inner heat sources.
When the initial and boundary conditions are known, the physical problem of heat conduction is to find adequate solutions of the Fourier-Kirchhoff equation or the Fourier equation.
1.2 Heat transfer.Conduction, convection and radiation
“When different parts of a body are at different temperatures, heat flows from the hotter to the colder parts. The transfer of heat can take place in three distinct ways: conduction, in which the heat passes through the substance of the body itself; convection, in which heat is transferred by relative motion of portions of the heated body; and radiation, in which heat is transferred directly between distant portions of the body by electromagnetic radiation” [1].
Heat conduction is a type of transfer of heat in solids and liquids, interpreted as the imparting of kinetic energy resulting from collisions between disorderly moving molecules. The process occurs without any macroscopic motions in the body. The conductivity of diamond without
high. The lowest conductivity is that of a gas.traces of isotope is the highest. The conductivity of a metals is also
Heat transfer by conduction is defined by the Fourier equation (1.1). The application of Eq. (1.1) in calculations encounters difficulties because the temperature gradient of the wall must be defined, as well as its increments around the whole surface S of the body. Accordingly, for practical reasons the Newton equation is usually applied:
11 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
where coefficient is called the surface conductance or the coefficient of surface heat transfer. It defines the amount of heat transferred in unit time through unit surface when the existing temperature gradient is 1 deg. For using of the Newton equation, there is no need to introduce any simplifying assumptions. All the complicated character of the heat-transfer phenomenon is enclosed in the value of coefficient which depends on many parameters. When the heat transfer conditions are described, appropriate attention must be paid to the proper choice of and the definition of the influence of different factors on its value.
For a description of the heat flow phenomenon on the border of the body, a differential equation is used:
Equation (1.47) results from the Fourier law [Eq. (1.1)] and the Newton equation [Eq. (1.46)], expressed by Eqs (1.48) and (1.49), respectively
by equating the right-hand sides. When the geometry of the considered system is simple, an exact solution of Eq. (1.47) can easily be deduced.
The value of surface heat transfer coefficient is strongly affected by the presence of heat bridges and thermal resistances. Imperfect contact between touching surfaces which are at different temperatures causes a lack of thermal equilibrium inside the free space between them. The magnitude of the thermal resistance depends on the surface conditions, the number and shape of surface irregularities and the conditions of heat conduction through the gas present in the space between the contact points. Temperature variations appear even though the thickness of the gas layer may be close to the size of the free distance in the gas molecule. It has been found [6] that even surface irregularities within the range of tens of microns influence the value of the surface heat transfer
12 CHAPTER 1
coefficient. The variations in thermal resistance between two solid bodies are the cause of errors in the heat determination.
The coefficient of surface heat transfer by conduction also depends on the existence of heat bridges in the system. If a layer of substance of low heat conductivity isolates two objects, then the heat exchange is not intensive. If a third object with heat conductivity higher than that of an insulating substance joins those two objects, then through this object (called a “heat bridge”) heat will flow, intensively enhancing the total heat exchange. Unfortunately, it is often very difficult in calo-rimetric practice to eliminate the existence of unwanted heat bridges and thermal resistances. It is crucial to decrease their contribution to the value of
Heat transfer by convection occurs in liquids and gases where there is a velocity field caused by extorted fluid motion or by natural fluid motion caused by a difference in density. The former case involves forced convection, and the latter case free convection. Combined convection occurs when both forced and free convection are present. The convection coefficient of surface heat transfer, defining the heat exchange in the contact boundary layer between fluid and solid, is determined. Coefficient is often expressed by equations containing criteria numbers, such as those of Nusselt (Nu), Prandtl (Pr), Reynolds (Re) and Grashof(Gr):
The criteria numbers are calculated by use of material constants such as – thermal conductivity coefficient; a – thermal diffusity coefficient;
and v – kinematic viscosity. In the expressions in (1.50), l is a distinctive dimension of the body; w is the distinctive velocity; g is the acceleration due to gravity; is the difference in temperature, and is the thermal expansivity coefficient.
Coefficient usually depends on the difference in temperature between the body and its environment. In the microcalorimeter described by Czarnota et al. [7], free convection occurs in the spherical space around the calorimeter, and as a result the coefficient is defined by the equation
13 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
A frequent goal in calorimetry is to obtain a constant value of irrespective of existing temperature gradients. A more common trend is to decrease or eliminate the heat transfer by convection. A very effective way to achieve this is the creation of a vacuum. The contribution of the heat transfer by convection can also be reduced by increasing the share of heat conduction in the total heat transfer.
Radiation is the transfer of thermal energy in the form of electromagnetic waves; it occurs in processes of emission, reflectivity and absorptivity. The quantity of heat radiated through a transparent gas layer from surface at temperature to surface at temperature completely enclosing the first surface, is
where
constant
is a substitute emission coefficient depending on the emission from a surface, the geometry and the reflectivity, and is a radiation
Introduction of the relation expressing the total radiant energy leaving unit surface area:
yields
or, on analogy with Eq. (1.47):
where
is called the radiation heat transfer coefficient. When the temperature difference
14 CHAPTER 1
is much lower than the temperatures and can be expressed by
where higher–power exponents of ratio are neglected. If the value of this fraction is very small, then a simplified formula is often valid:
The heat transfer in calorimeters is described in terms of the effective heat transfer coefficient, involving the heat transfer of convection, conduction and radiation. In calorimetry, it is more common to use coefficient G, called the heat loss coefficient, which is equivalent to the effective heat transfer coefficient calculated for the whole surface S.
1.3. General integral of the Fourier equation.Cooling and heating processes
Let us consider the temperature changes in a body, due to the initial temperature difference between the body surface S and the environment [1, 6, 8]. The initial condition is defined as
Additionally, it is assumed that
In the examined case, the solution of the Fourier equation will refer to the heating or cooling processes of a thermally passive body. Any assumptions made will not impose any restrictions on the solution. When heat is generated in the body and the expression of g (x, y, z, t) is known, the particular solution of the Fourier equation, can be found, on the assumption that the initial conditions are zero, T(x, y, z) = 0. Accord
15 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
ing to the superposition rule, the solution will be the sum of the separately determined solutions.
Let the heat transfer between the body and its environment proceed through the surface S according to the boundary condition of third kind, i.e.
If it is assumed that the physical parameters are constants and the Fourier equation (Eq. (1.38)) becomes
and can be written in the form
To solve the differential Eq. (1.63), the Fourier method of separated variables will be used. According to this function, T(x, y, z, t) can be described as
Then
and
Substituting the above equations into Eq. (1.63) gives
or, after transformation
16 CHAPTER 1
The right–hand side of Eq. (1.69) is a function only of coordinates (x, y, z), whereas the left–hand side is a function only of the independent variable t. To satisfy Eq. (1.69), both sides must be equivalent to the same constant value. This means that this value should be negative. Thus, when the initial temperature of the body is higher than the environment temperature, a cooling process occurs and
whereas, when the initial temperature of the body is lower than the environment temperature, the heating process is characterized by
Thus:
In order to fulfil this condition, let us denote by the value of the sides of Eq. (1.69). Thus, instead of one differential equation, we obtain the two following differential equations:
Equation (1.73) may be written as
17 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
and its solution is
which can easily be checked.Equation (1.74) may be written in the form
Solving this equation gives a set of values
equivalent to the set of solutions of the function
whereas the compatible function is equal to
The magnitudes are called the eigenvalues of the differential Eq. (1.65). The functions in Eq. (1.80) corresponding to the particular eigenvalues are called eigenfunctions. Since Eq. (1.62) is a linear differential equation, its solution is also the sum of eigenfunctions:
or, with regard to Eq. (1.80), it can be written in the form
On introduction of the notation
Equation (1.82) can be written as
18 CHAPTER 1
or
We see that the course of the temperature T (x, y, z, t) changes at any point of the body is the sum of infinite number of exponential functions. Whereas the sequence of eigenvalues is an increasing sequence, the sequence of constants monotonously decreases [9]. As a higher accuracy of determination of temperature T (x, y, z, t) is needed, a greater number of exponential terms must be used for a proper description of the changes in temperature of the body within time. In the limit-
one having in the exponent the smallest value of the constanting case, it is possible to neglect all the exponential terms, excluding the
Equation (1.84) then transforms to an equation equivalent to the mathematical expression of Newton’s law. This type of description is mostly used in calorimetry and thermal analysis.
The expression given by Eq. (1.85) was used for the first time in mi crocalorimetry to describe short–duration heat processes investigated in a Calvet microcalorimeter [10–13]. The temperature T rise caused by heat effect was expressed by the following equation:
where the adopted relations made possible the determination of T for an exponential temperature course of second or third order. The excellent monograph by Camia [14] is one of the most important works on this field. A number of methods are currently used to determine the heat effects and thermokinetics of short–duration processes, based on the assumption of a multiexponential course of temperature changes. These methods are disscused in Chapter 3.
The question of the determination of total heat effects for a multiexponential temperature course in time was investigated by Hattori et al. [15] and Tanaka and Amaya [16].
19 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
Hattori et al. [15] consider the calorimeter in terms of a one-dimensional model of distributed parameters. The objects distinguished are the calorimetric vessel A, the heat conductor B and the medium C, at constant temperature, that surrounds the calorimeter (Fig. 1.2). For the solution of the Fourier equation, the following assumptions were made: heat power is generated in the calorimetric vessel at homogenous temperature and with constant heat capacity; the heat conductor along which the heat flows has a well-insulated lateral surface. Its ends are defined as x = 0 and x = L; there exists a heat bridge of the calorimetric vessel with the conductor; the environment is kept at constant temperature. The heat transfer takes place only through the cross-section for x = 0.
Tanaka and Amaya [16] consider the calorimeter as a concentric model of three domains, and (Fig. 1.3), which are solids. Domain in which heat q heat is generated or adsorbed, is surrounded by domain Domain is surrounded by domain at constant temperature. These three domains represent the calorimetric vessel, and the heat conductor between the vessel and the shield.
In both of the above papers, it was shown that, independently of the
20 CHAPTER 1
number of exponential terms that describe the temperature course in time, it is possible to calculate the total heat effect determining the surface area between the registrated temperature course in time and the time axis below the temperature course in time if the measurement starts from equilibrium conditions and the initial and final temperatures are equal.
1.4. Heat balance equation of a simple body.The Newton law of cooling
Linear differential equation of first order called the heat balance equation of a simple body, has found wide application in calorimetry and thermal analysis as mathematical models used to elaborate various methods for the determination of heat effects. It is important to define the conditions for correct use of this equation, indicating all simplifications and limitations. They can easily be recognized from the assumption made to transform the Fourier-Kirchhoff equation into the heat balance equation of a simple body.
Let us consider [1, 6, 8, 17] that the heat transfer process takes place under isobaric conditions, without mass exchange and that the thermal parameters of the body are constant. The Fourier-Kirchhoff equation can then be written as
Integration of both sides of Eq. (1.87) with respect to the volume V of the body of extremal surface S gives
21 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
The left–hand side of Eq. (1.88) can be transformed as follows:
where
is the average temperature of the body of volume V. The first term on the right–hand side of Eq. (1.88) can be trans
formed by using the Gauss-Ostrogradsky theorem for the vector gradient:
where dS is an oriented element of the surface S of the body. Application of the average value theory gives
where is the average flux of heat across the surface S of the body.
Application of the boundary condition of the third kind leads to
where is the average temperature of the external surface S of the body, is the heat transfer coefficient, and is the temperature of the environment.
The integral of the second term on the right–hand side of Eq. (1.88):
corresponds to the change in the heat power dQ/dt within time t. Thus, the second term on the left–hand side of Eq. (1.88) can be written in the form
22 CHAPTER 1
From Eqs (1.89) – (1.95) and Eq. (1.88), and putting
where C is the total heat capacity of the body, we have
Equation (1.97) is accurate, but does not give an explicit solution, because the relation between temperature and the temperature on the surface is not defined.
If it is assumed that
Equation (1.97) becomes
or
Equations (1.99) and (1.100) are commonly known as the heat balance equations of a simple body. From the above considerations, it is clear that these heat balance equations and the Fourier-Kirchhoff equation [Eq. (1.87)] are equivalent to each other when:
1. the temperature in the total volume of the body is homogenous and only a function of time;
2. the temperature on the whole surface is homogenous and only a function of time;
3. the above temperatures are identically equal to one another at any moment of time;
4. the heat capacity C and the heat loss coefficient G are constant and not functions of time and temperature.
23 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
When
Equation (1.99) becomes
If it is assumed that
Equation (1.102) becomes
Equation (1.104) is equivalent to Newton’s law of cooling. The coefficients and of Eqs (1.97) and (1.104) can be characterized as follows [9]. Coefficient determines the amount of heat transfer by unit surface in unit time when the temperature difference is equal to 1 deg. Constant is called the cooling constant and characterizes the rate of body cooling. This quantity is the reciprocal of the body time constant It has the same value for any point of the body. Constant does not depend on the initial temperature field, but depends on the shape and dimensions of the body, the thermal parameters of the body (e.g. the
ficientthermal diffusivity coefficient) and the conditions of heat transfer. Coef-
is a quantity describing the measure of the ability of the given body to react to cooling or heating of the environment. The influence of this environment on the body is characterized by the heat transfer coefficient and/or the heat loss coefficient G.
given by Eq. (1.103) is appropriate only when
The dependence between quantities G, C andWhen these temperatures are
different, Eqs (1.97) and (1.105) can be supplemented by a new parameter, the coefficient of heterogenity of the temperature field
24 CHAPTER 1
Thus, Eq.( 1.97) becomes
In order to solve this non–stationary differential equation, it would be necessary to know the function This condition is difficult to fulfil. To solve the theory of the problem of ordered state heat transfer [9], two periods of cooling or heating process of the body are specified.
The first period is characterized by a disordered course of temperature field changes in time. The second, the well-ordered heat transfer period, comes after a certain period of time (Fig. 1.4). It is assumed that, for the ordered state heat transfer, the relation between heat capacity C, heat loss coefficient G, cooling constant and coefficient is expressed as follows:
25 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
Coefficient is a dimensionless quantity; its value can vary between one and zero. The more differs from unity, the greater is the inequality in the field of temperature. This coefficient is a function of Biot’s number Coefficient decreases to zero as constant Bi increases to infinity. Let us assume that the same body is observed under various conditions of heat transfer from the body to the environment and that as a result there are various values of the surface heat transfer coefficient
For the sequence of increasing values of
there is a sequence of increasing values of the constants
According to the discussed theory of the ordered state heat transfer, together with the increase in the value the reaction of the body becomes weaker and the value of the cooling constant drifts towards the limit value (Fig. 1.5). Only in the case of certain small values of coefficient can it be assumed that a homogenous temperature distribution exists in the examined body. It also indicates that the range where the heat balance equation can be accurately used for determination of the heat power changes within time (the P(t) function called thermokinetics) is limited. However, this equation is also used as a mathematical model in determining the P(t) function in instruments with
26 CHAPTER 1
different values of coefficient It is applied as a mathematical model in conduction microcalorimeters, in which heat exchange between the body and environment is extensive and coefficient is significant. For these reasons, it is very important to verify the accepted model experimentally.
If a maker of a calorimetric system decides to apply the method of determining the heat effect resulting from Eq. (1.99), it would be most convenient to establish a set of parameters (e.g. such that the calorimeter in which the heat is generated fulfils the conditions needed to apply this equation. A probe to determine such a set of parameters was undertaken by Utzig and Zielenkiewicz [18] for a simple physical model as an approximation of a real calorimetric system. The relation between the dimensionless parameter the physical parameters of the system and was elaborated. In the parameter the value corresponds to the time interval after which the body temperature changes can be described by one exponential term, while is a time constant.
1.5. The heat balance equationsfor a rod and sphere
A real calorimeter is composed of many parts made from materials with different heat conductivities. Between these parts one can expect the existence of heat resistances and heat bridges. To describe the heat transfer in such a system, a new mathematical model of the calorimeter was elaborated [8, 19] based on the assumption that constant temperatures are ascribed to particular parts of the calorimeter. In the system discussed, temperature gradients can occur a priori. Before defining the general heat balance equation, let us consider the particular solutions of the equation of conduction of heat for a rod and sphere. For a body treated as a rod in which the process takes place under isobaric conditions, without mass exchange, the Fourier-Kirchhoff equation may be written as
27 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
( ):Consider the above equation for Fig. 1.6
If we put
Eq. (1.109) becomes
If we expand the function T(x, t) as a Taylor series in the neighborhood of the point and neglect terms of higher order than the second, we have
Consideration of the function T(x, t) at points and gives the following set of equations:
28 CHAPTER 1
If we put
this set of equations becomes
The solutions of the equation set defined by Eq. (1.115) are
Substitution of Eq. (1.116) in Eq. (1.111) gives
29 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
Let the volume of the n-th element be
where F is the cross–sectional area of the rod. Multiplication of both sides of Eq. (1.118) by gives
where defined by
is the heat capacity of domain n, whereas defined by
is the heat power generated in domain n. The quantities
are the heat transfer coefficients between domains n and n+l, and domains n–1 and n, respectively. The quantities
denote the heat loss coefficients. Thus, Eq. (1.120) may finally be written as
30 CHAPTER 1
where
denote the amounts of heat exchanged between domains n and n+1 and between domains n–1 and n in time interval dt, respectively. Equation (1.125) is the desired heat balance equation for a rod considered as a system of domains arranged in a row. The same procedure is applied to deduce the equation of heat conduction for a homogenous sphere of radius r, where an isobaric process without mass exchange takes place. The Fourier-Kirchhoff equation written with spherical coordinates becomes
for Let us consider the above equation with
The expansion of the function T(r, t) into a Taylor series in the neighborhood of the point neglecting terms of higher order than the second, leads to
Substitution of and gives the set of equations
31 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
Let us put
and neglect derivatives of higher order than the second:
The solutions of the above set of equations are
32 CHAPTER 1
From Eqs (1.132), (1.134), (1.135) and (1.128) we have
whereMultiplication of both sides of Eq. (1.13 6) by
and putting
gives the following differential equation
The heat balance equations for the rod and sphere described as Eqs (1.125) and (1.138) are identical in form. They are derived on the basis of the same assumptions: in the examined bodies several elements (parts, domains) are distinguished; each is characterized by a constant heat capacity and homogenous temperature in the total volume; the heat exchange between these parts is characterized by heat loss coefficient G. The first term on the left–hand side of these equations determines the amount of accumulated heat in the domain of the body of indicator n; the second and third terms are the amounts of heat exchanged between this part and the neighboring domains of indicators
33 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
n+1 and n–1. The heat exchange between the body and environment is characterized by the boundary condition of the third kind.
1.6. General heat balance equationof a calorimetric system
Let us assume Eqs (1.126) and (1.139) as the basis on which to derive the generalized heat balance equation of the calorimeter treated as a multidomain (elements, parts) system of various configurations [19-21]. Let us also assume that the heat transfer in the body can take place not only between the neighboring domains, but also between any domains characterized by heat capacities and temperatures Each of the separate domains has a uniform temperature throughout its entire volume; its temperature is a function only of time t, and the heat
characterized by loss coefficientcapacity of domain is constant. The domains are separated by centers
and the heat exchange between the
takes place through these centers. Temperature gradients appear only in these centers and between the domains and the environment; their heat capacities are, by assumption, negligibly small. Furthermore, a heat source or temperature sensor may be positioned in any of the domains.
domains and between the domains and the environment of temperature
The amount of heat exchanged between domains j and i in the time interval dt is proportional to the temperature difference of these domains; the heat loss coefficient is the proportionality factor:
The condition is fulfilled. The amount of heat exchanged between domain j and the environment in time interval dt is equal to
Thus, the total amount of heat dQ”(t) exchanged between domain j and the remaining domains and the environment is equal to
34 CHAPTER 1
Taking into account Eqs (1.140) and (1.141), we have
The amount of heat dQ´(t) accumulated in domain j is equal to
The amount of heat generated in domain j in time interval dt is equal to the sum of the heat accumulated in this domain dQ´(t) and the heat exchanged between this domain and the remaining domains and the environment dQ´´(t). Thus:
From Eqs (1.143) and (1.144), we have
Dividing both sides of the above equation by dt gives
or
where
v–n,
35 THE CALORIMETER AS AN OBJECT WITH A HEAT SOURCE
is the heat power generated in domain j. In Eq. (1.148), the first term on the right–hand side determines the
amount of heat accumulated in domain j, the second term the amount of heat exchange between domain j and the environment, and the last term the amount of heat exchange between domain j and remaining N–1 domains.
The differential equation Eq. (1.148) is called the general heat balance equation of domain j, and the set of these equations is the general heat balance equation of a calorimetric system. The heat balance equation Eq. (1.147) describes in general form the courses of the heat effects in a calorimeter of any configuration of domains and any localization of heat sources.
The general heat balance equation corresponds to the formalization of the general calorimetric model by means of the set of equations with lumped parameters. To consider the thermal properties of a calorimeter, the detailed form of this equation has to be derived. It is necessary to define in it the number and configuration of the distinguished domains and the centers which separate these domains and where heat transfer takes place.
The representation of the calorimeter by mathematical models described by a set of heat balance equations has long traditions. In 1942 King and Grover [22] and then Jessup [23] and Churney et al. [24] used this method to explain the fact that the calculated heat capacity of a calorimetric bomb as the sum of the heat capacities of particular parts of the calorimeter was not equal to the experimentally determined heat capacity of the system. Since that time, many papers have been published on this field. For example, Zielenkiewicz et al. applied systems of heat balance equations for two and three distinguished domains [25-48] to analyze various phenomena occurring in calorimeters with a constant– temperature external shield; Socorro and de Rivera [49] studied micro-effects on the continuous-injection TAM microcalorimeter, while Kumpinsky [50] developed a method or evaluating heat-transfer coefficients in a heat flow reaction calorimeter.
36 CHAPTER 1
The calorimeter as a system of several domains has often been presented by using a method based on thermal-electric analogy [51–53]. This is based on the similarity of the equations describing heat conduction and electric conduction. Such a study generally involves both the use of circuit theory and the principle of dimensional similarity. In a corresponding network analog, the thermal resistances and capacities are simulated by electric resistors and capacitors, respectively. In constructing such circuits, it is considered that there is an equivalence between the quantities: electric current and heat flow; electric voltage difference and temperature difference; electric resistance and thermal resistance; and electric capacity and heat capacity.
The thermal–electric analogy method has been used to analyze and represent the operation mode of a number of calorimetric and thermal analysis devices. For example, Rouquerol and Boivinet [54] presented analogs of electric circuits for the following heat-flux and power compensation devices: the conventional DTA instrument of Mauras [55], the differential scanning microcalorimeter of Arndt and Fujita [56], and the Tian-Calvet microcalorimeter [57]. Wilburn et al. [58] used both passive and active analogs to investigate the effect of the holder design on the shape of DTA peaks. The thermal-electric analogy was applied by Nicolaus [59] to analyze the problem of reconstruction of the heat flux curve. Ozawa and Kanari [60] illustrate the discussed heat balance equations for constant heating rate DSC by an equivalent electrical circuit. The method of analogy is also used in the papers of Claudy et al. [61–63].
The thermal-electric analogy method is useful to represent the accepted structures, which distinguish the domains and the modes of their connection with themselves and the environment. It is also useful to formulate a suitable system of the balance equations for the bodies (domains). The increase in the number of its applications is related to the development of analog computer calculation methods.
It will be demonstrated below that the extended information range relating to the investigated calorimeter allows analysis of both its thermal and dynamic properties. The use of the method based on the analogy of the thermal and dynamic properties of the investigated systems is profitable in this case.
Chapter 2
Calorimeters as dynamic objects
Calorimeters are physical objects that can be described in different ways. The steering theory treats a calorimeter as a dynamic object, in which the generated heat effects (input signals) are transformed to the quantity measured directly in the calorimeter, e.g. temperature (output signal). Let us describe the input signals by the functions
and the output signals by the functions In fact, in calorimetry the output function never reproduces the input function directly. The calorimeter is a kind of transducer, which transforms the input functions into the output functions. Thus, to reproduce
with the required accuracy on the basis of the relation between these two types of functions should be determined:
and the procedure should be selected so as to allow the inverse operation, i.e.
which permits determination of the input function on the basis of a given course of the output function of the calorimeter. When the unchanging relation between the input and output functions is determined, it furnishes an explicit description of the dynamic properties of the calorimeter.
A calorimeter is usually regarded as an object that can be described by one differential equation or a system of linear differential equations with constant coefficients. These equations are treated as the mathematical models of calorimeters. If there are many output functions, then the dynamic object (calorimeter) is described by a system of n differential equations. Assuming linearity and applying the superposition rule, one
38 CHAPTER 2
may reduce two or n objects to one. On analysis of an object described by one input and one output function, we do not lose generality.
A convenient method for solving linear equations is to apply the Laplace or Fourier transform. In the transfer function (transmittance), the dynamic properties are encoded. The function is defined as the quotient of the Laplace transforms of the output and input functions. The spectrum transmittance is defined as the quotient of the Fourier transforms of the output and input functions under zero initial conditions.
The transmittance (transfer function) of the object has the form
where s is a complex variable; x(s) and y(s) are the Laplace transforms of the output signal x(t) and the input signal y(t), respectively.
Equation (2.3) written in the form
can be visualized by a block diagram (Fig. 2.1). The objects of thestructure shown in Fig. 2.1 are called open objects in the steering theory.
Let us consider the quantities H(s), x(s) and y(s) of Eq. (2.4). Each of them can be obtained by using the two others:
1. The transmittance H(s) can be determined only on the basis of experimentally determined y(s) and x(s). The calorimeter is then treated as a “black box” and knowledge of their physical parameters is neglected. It is assumed that the calorimeter can be treated as a linear, stationary and invariant object.
2. The transmittance H(s) of the calorimeter is based on a mathematical model of the calorimeter with distinguished physical parameters and mutual relation between them. The experimental de
39 CALORIMETER AS DYNAMIC OBJECT
mination of the functions y(s) and x(s) is applied for evaluation of the values of the dynamic and static parameters of the transmittance. This procedure is equivalent to the calibration of the calorimeter.
3. The transform x(s) is determined in the knowledge of the form of the transmittance H(s) and the values of their parameters. Input function y(s) is determined experimentally. This procedure is convenient to verify the agreement between experimentally determined and calculated functions x(s).
4. The transform y(s) is evaluated on the basis of previously known H(s) and experimentally determined function x(s). It corresponds to the determination in the domain of the complex variable of the course of the investigated heat effect.
The form of the transmittance depends on the type of the dynamic object.
2.1. Types of dynamic objects
Among the open systems, the following types of dynamic objects can be distinguished [64, 65]:
Proportional type, when the input function y(t) is proportional to the output function x(t):
where k is the proportionality coefficient, and the transmittance H(s) has the form
while the spectrum transmittance is expressed by Eq. (2.7):
Integrating type, when the input function is proportional to the derivative of the output function:
40 CHAPTER 2
while
First-order inertial type, when the input function is a linear combination of the output function and its derivative:
while
Let us compare the equations describing the dynamic properties of the distinguished types of objects with suitable heat transfer equations:
1. We compare Eq. (2.5), which describes the dynamic properies of a proportional object, with the Newton heat transfer equation [Eq. (1.46)];
2. We compare Eq. (2.8), which describes the dynamic properties of an integrating object, with the first term of the left-hand term of Eq.(1.99);
3. We compare Eq. (2.11), which describes the dynamic properties of an inertial object, with the heat balance equation of a simple body [Eq. (1.99)].
It can readily be imagined that a calorimeter in which the course of heat power within time corresponds (with the accuracy of the factor) to the course of the changes in the output function (e.g temperature) has the properties of the proportional object. The properties of integrating
41 CALORIMETER AS DYNAMIC OBJECT
objects are those of adiabatic calorimeters, inside which the accumulation of heat occurs.
Calorimeters that are inertial objects comprise the most numerous group of calorimeters. Let us assume that a calorimeter has only the integrating or proportional properties of the object, as a certain idealization. Of course, this idealization is well-founded in many cases. The relation describing the dynamic properties of the object is equivalent to the mathematical model of the calorimeter. It is expressed as a function of time, frequency or a complex variable domain.
2.2. Laplace transformation
The Laplace transformation [66] is the operation of changing one expression into another by integration. In this transformation, the function f(t) of the real variable is changed into the complex function F(s) of the complex variable s. The Laplace transform is defined by Eq. (2.14):
and abbreviated as
where while for the existence of the transform F(s) the condition must be fulfilled.
The inverse Laplace transformation is defined by Eq. (2.16):
where C is a contour that outlines all extremes of the function in the integral formula. This operation is abbreviated as
The Laplace transformation is very convenient to use. Its advantages include: 1) The Laplace transforms of simple functions can be deter
42 CHAPTER 2
mined by direct integration or integration by parts. In most cases, the simple function f(t) and the transform F(s) representing the function transform pairs are tabulated; 2) the Laplace transformation is a linear transformation for which superposition holds; 3) by application of the Laplace transformation, an ordinary differential equation is reduced to the algebraic equation of the transform, called the subsidiary equation of the differential equation.
Let us apply the Laplace transform to the heat balance equation of a simple body (Eq. 1.99):
On dividing by G and putting
we obtain
Use of the Laplace transformation for Eq. (2.19):
gives the solution for Eq. (2.19) in the complex domain
After simple rearrangement, Eq. (2.21) becomes
Equation (2.22) is called the subsidiary equation of differential Eq. (1.99); T(s) is the response transform of the output function; F(s) and
are driving forces; and is the characteristic function of the object. The first and third terms on the right-hand side of Eq. (2.22), the function of the initial conditions, are the transforms of the transient
43 CALORIMETER AS DYNAMIC OBJECT
solution. The second term, which is independent of the initial conditions, represent the transform of the steady-state solution.
The inverse Laplace transformation defines the function T(t) characterizing the course of the temperature changes of the calorimeter. When the heat effects are not generated, and and thus T(t) depends only on the initial temperature difference T(0) between the calorimeter and its environment. Then:
In a similar way, the Laplace transform can be applied to obtain the solution of Eq. (2.20) for the other input functions.
If it is assumed that two first-order inertial objects in series are distinguished in the calorimeter, while the output function of the first object is at the same time the input function of the second object (Fig. 2.2), then the calorimeter transmittance H(s) has the form
In the time domain, the system is described by the following differential equations:
Increase of the number of inertial objects causes significant changes in the course of the output function. Let us assume that the objects are arranged in series in such a way that the input function of the next iner
44 CHAPTER 2
tial first-order object is the output function of the previous object (Fig. 2.3).
A graphical presentation of the output functions for numbers of objects ranging from one to six, caused by input function forcing corresponding to the unit step function, is shown in Fig. 2.4.
The block diagrams presented in Figs 2.1 - 2.3 are characteristic for the open systems and differ from one another only in the number of inertial objects. The dynamic objects are not always arranged in series. In many cases, as a result of self-arrangement of the objects and their configurations, we must consider the set of differential equations presented by the block diagrams of closed-loop systems. For example, for the calorimeter described by the differential equation
the resulting block diagram is a in Fig. 2.5, while for the calorimeter described by the following set of differential equations:
45 CALORIMETER AS DYNAMIC OBJECT
where
the resulting block diagram is b in Fig. 2.5.
When a larger number of inertial objects are distinguished, the calorimeter transmittance will have a more complicated form. For N objects, the transmittance has the form
and we obtain the form of the calorimeter transmittance H(s):
In this case, in the time domain the calorimeter is described by the following set of differential equations:
where
46 CHAPTER 2
When the physical parameters of the system are neglected, Eq. (2.30) takes the form
On application of the Laplace transformation, Eq. (2.33) under zero initial conditions can be written in the form Eq. (2.4):
where
is the transmittance of the analyzed system; m < N; and N denotes the system rank.
Determination of the transmittance expressed by Eq. (2.34) is
eqivalent to calculation of the polynomials and
The equation
is called the characteristic equation and its roots are the “eigenvalues” or “poles” of transmittance. If it is assumed that in Eq. (2.35) the polynomial has only single zero values, we can write
(2.37)The roots of Eq.
CALORIMETER AS DYNAMIC OBJECT 47
are named the “zeros” of transmittance, and the polynomial in this equation is expressed by
On substitution of Eqs (2.36) and (2.38) into Eq. (2.34), the transmittance H(s) can be written in the form
The poles and zeros of transmittance express the inertial properties of the calorimetric system as a dynamic object. With the introduction of
transmittance H(s) becomes
where
is a constant called the static factor.
2.3. Dynamic time-resolved characteristics
The relation that describes the output function changes in time caused by the action of the input function is given by the dynamic time-resolved characteristics. In calorimetry, the same input functions are used for their description as in control theory [64]. However, the terminology used for this purpose is different. Thus,
48 CHAPTER 2
1. The input function described by a short-duration heat pulse of relatively high amplitude, called in control theory a unit pulse function (impulse function, Dirac function) (Fig. 2.6), is expressed by
The unit pulse whose surface area is equal to one has a Laplace transform y(s) equal to one.
2. The input function described by a constant heat effect in time corresponds to the unit step function (Fig. 2.7):
49 CALORIMETER AS DYNAMIC OBJECT
The unit step function corresponds to the integral of the unit pulse function with respect to time. The Laplace transform of the unit step function is
3. The input function described by a heat effect that is constant in time over a determined interval of time corresponds to the input step function of amplitude b and time interval a, called the rectangular pulse (Fig. 2.8):
where u(t) is determined by
while u(t–a) is expressed by
This is the shape of the input function that is applied when the calibration of the calorimeter consists in generation of a Joule effect that is constant in time for a defined duration. The exceptions to the rule are those instruments in the calibration of which the frequency characteristics are used.
The Laplace transform of the rectangular pulse is expressed by
50 CHAPTER 2
4. The input function described by a heat effect rising linearly in time is presented in Fig. 2.9 and expressed by Eq. (2.49):
The generation of such a forcing function is used in steering theory as well as in adiabatic and scanning calorimetry. The ramp function has the following Laplace transform:
5. Generation of the heat effect of the first-order kinetic reaction is expressed by the exponential function (Fig. 2.10)
The Laplace transform of which is
51 CALORIMETER AS DYNAMIC OBJECT
6) To evaluate the dynamic properties of calorimeters and calibrate the instruments, period input functions have also been used (Fig. 2.11).
where A is the amplitude of oscillation, is the oscillation frequency, and
The Laplace transform of the sinusoidal input function is
These periodic heat forcing functions are the basis for some calorimetric methods, e.g. those used in modulated scanning calorimetry.
Determination of both the transmittance of the investigated object and the Laplace transform of the input function y(t) furnishes the output function x(s) = y(s)· H(s). With the inverse transformation, we obtain y(t). Output functions x(t) of proportional, integrating and inertial objects for various input functions are collected in Table 2.1.
The time-resolved dynamic characteristics presented in Table 2.1 show that the shapes of the output functions depend strongly on the type of the dynamic object. For proportional objects, the output and input functions have the same shape, while their values are equal to each other with the accuracy of the factor.
This means that in a calorimeter with the dynamic properties of a proportional object the output function gives direct information on the course of the output function; in other words, the course of the experimentally determined function T = T(t) corresponds to the course of the changes in heat power P in time t.
52 CHAPTER 2
53 CALORIMETER AS DYNAMIC OBJECT
54 CHAPTER 2
For integrating objects, the course of the output function corresponds to the accumulation process and to the operation of integration. The object responds to a generated unit pulse with an output signal, which is equivalent to the unit step function; the response of the object to the unit step function is a linearly rising function; production of the ramp forcing function stimulates the response of the object according to the relation
For inertial objects, the course of the output function is induced by the inertial properties of the object (calorimeter). This results from the
/(Cs+k) orH(s),
function
transmittance form which is expressed by the operator 1the operator while the relation between the input function y(s), the output x(s) and the transmittance H(s) is presented graphically by a block diagram (Fig. 2.12)
When the trasmittance is represented by the single symbol H(s), it is depicted by the block diagram presented in Fig. 2.1.
The form of the transmittance H(s) indicates that the time constant is a decisive parameter for characterizing the inertial properties of the object (calorimeter). This also means that the value of the time constant determines the course of the output function, the character of which is approached more closely for either proportional or integrating objects. Simply, the values of control the inertial, damping properties of the object. Different values of the function x(t), depending on the values of
are responses to the same heat forcing (Fig. 2.13). The courses of the output functions caused by the generation of the
sinusoidal input function for proportional, integrating and inertial first-order objects are also presented in Table 2. 1. It is seen that, for a proportional object, only the value of the sinusoidal (harmonic) oscillation frequency changes. For an integral object, the sinusoidal input function is transformed by the object to a cosinusoidal function. The amplitude of the output function is then inversely proportional to the frequency of the
55 CALORIMETER AS DYNAMIC OBJECT
sinusoidal input function. The frequency phase lag is 90° relative to the input function. For inertial objects, the sinusoidal input function is transformed by the object to an other sinusoidal function that has different phase and amplitude. In the following relation, expressing the output function x(t) for the steady state
where
the factor expresses in terms of f requency the ratio of the output and input function amplitudes. The values of the factor and the size of the phase shift characterize the dynamic properties of the inertial object. For a frequency close to zero, when sinusoidal changes have low frequency, the course of the output function is similar to that of the input function y(t). The phase shift is then close to zero and the properties of inertial and proportional objects become very similar. The shift in the output function course relative to the input function results from the
x(t) is expressed as the conversed time constant
radians or –90°. When the frequency is related tothen the oscillation frequency is 0.707
and the phase shift is
rise in frequency. For infinitely high frequency, the shift in the course of
radians or 45°. This is the frequency related to the transfer function of an inertial object, given by the operator or
2.4. Pulse response
The pulse response function is the output function h(t) caused by the action of the input impulse function (Dirac function). It is applied for determination of the particular forms of the Laplace transmittance. It can be obtained by applying the Laplace inverse transformation to the transmittance Eq. (2.41):
56 CHAPTER 2
where coefficients have the form
from the Cauchy theorem of residues. The pulse response function is a positive function of real argument t.
It fulfils the condition given by Eq. (2.43):
Taking into account Eq. (2.57) and integrating, we have
If we take advantage of the theorem of the initial value of the original, i.e. the function h(t), the initial value of the pulse response h(t) on the basis of Eq. (2.34) can be given by
The pulse response can be obtained experimentally as the response of the calorimetric system:
a) to a rectangular heat pulse of short duration (“experimental” Dirac pulse) expressed as a sequence of discrete values
where and is the sampling period; or b) to the unit step function lasting a sufficiently long time to achieve
the stationary state of heat transfer. In this case, the pulse response is expressed by the derivative of the calorimetric response
CALORIMETER AS DYNAMIC OBJECT 57
With the measured values of the response at times and respectively
numerical derivation has to be performed in order to obtain discrete values of the pulse response h(t).
In the first case, the accuracy of obtaining the values of the unit pulse response depends on the degree to which the “experimental” pulse approximates to the “ideal” Dirac function and on the accuracy of the measurement of the calorimetric signal. In the second case, the procedure of numerical derivation influences the accuracy of obtaining the pulse response. Since the experimentally obtained response of the system does not fulfil the condition [Eq. (2.49)], it is necessary to calculate the integral from the course obtained for the calorimetric signal and divide all the values of the signal by the value of this integral. Thus, we obtain a new course that fulfils the condition needed.
From Eqs (2.59) and (2.60), the dependences between the amplitudes and time constants can be obtained:a) for the first-order system:
b) for the second-order inertial system:
c) for the second-order inertial system whose transmittance containsone zero
It results from Eqs (2.65) and (2.66) that the values of coefficient and depend not only on the time constants, but also on the zeros of transmittance.
58 CHAPTER 2
In Fig. 2.13, the plots of pulse responses of calorimeters of various orders are shown. As the order of the system becomes higher, the pulse response is “flattened”, and its maximum value drifts more in time.
2.5. Frequential characteristics
To analyze the dynamic properties of calorimeters, frequential characteristics, similarly as time-resolved characteristics, are determined [8, 67]. To obtain the frequency characteristic, Fourier transforms are used. The Fourier transform which is a complex function of the real variable can be written as follows:
or in the form
If it is assumed that
where and are the real (even) and imaginary (odd) parts of the transmittance respectively, we can write
CALORIMETER AS DYNAMIC OBJECT 59
Because
from Eq. (2.69) we have
Magnitude is called the amplitude. Division of Eq. (2.69) leads to
Thus
Magnitude is called the phase and is equal to the argument of transmittance The phase describes the relative amounts of sine and cosine at a given frequency.
The spectrum transmittance of an N-order inertial system has the form
Equation (2.75) is equivalent to Eq. (2.67), assuming that In the spectrum transmittance described by Eq. (2.75), let us
distinguish the component transmittances and
If
this becomes
and for
It results from Eqs (2.78) and (2.79) that the amplitude of the transmittance is equal to the product of the amplitudes of particular
60 CHAPTER 2
transmittances. Thus, the phase of the transmittance is equal to the sum of the particular transmittances of the phases.
According to Eqs (2.75) and (2.79), the phase is described by the equation
If the magnitude approaches infinity, then, according to Eq. (2.80), the value of the limit phase approaches
To analyze the dynamic properties of the object, the amplitude characteristics, phase characteristics and amplitude-phase characteristics are used. The amplitude characteristic is a relation expressing the ratio of the amplitude of the output function to that of the input function. The dependence of a phase shift in frequency is called the phase characteristic of the object. The amplitude-phase characteristic presents the amplitude changes and the phases of the output function. Two types of plots are usually used to draw the amplitudes: one in the coordinates
and the other in the coordinates and two types of plots for the phase: in the coordinates or The plot in the coordinates gives the amplitude-phase characteristics.
Let us analyze the amplitude-phase characteristics for a few types of spectrum transmittance.
According to Eqs (2.72) and (2.75), the amplitude is described by the function
For sufficiently large values of the function can be approximated by the equation
61 CALORIMETER AS DYNAMIC OBJECT
Taking logarithms of both sides of the above equation gives
It results from the above equation that the plot of the amplitude in the coordinate system asymptotically approaches a straight line with direction coefficient equal to –(N – m). In this way, the asymptotic plot permits an estimation of the difference between the number of poles and the number of zeros of the transmittance. The plot of helix shape
nates(N – m)which passess through the – guater of the system in the coordi–
the phase shift [Eq. (2.81)].will be obtained. The number of –(N – m) is related with
2.6. Calculations of spectrum transmittance
The spectrum transmittance can be obtained as the Fourier transform of the pulse response or as the quotient of the Fourier transform of the system response to a known heat effect.
where is a heat pulse of constant heat power and time interval u (input step function)(Fig. 2.14a); is the temperature response to this heat effect (Fig. 2.14b).
In order to determine the spectrum transmittance it is necessary to calculate the integrals on the right-hand side of Eq. (2.85). According to the Euler formula:
where
62 CHAPTER 2
and are the real (even) and imaginary (odd) parts of the Fourier transform of the response function, respectively.
The result of the calorimetric measurement is obtained as the number sequence temperature data [Eq. (2.66)]
at times respectively. Thus, the integrals of the calorimetric signal [Eqs (2.87) and (2.88)] are to be calculated numerically by applying a convenient approximation, e.g.
Then, Eqs (2.87) and (2.88) become
63 CALORIMETER AS DYNAMIC OBJECT
Integration and rearrangement of Eqs (2.90) and (2.91) gives
parts ofIn this way we obtain the real and imaginary the Fourier transform of the response function to a heat pulse. The Fourier transform of the input function should also be determined.
Let us determine the transforms for the following input functions: a step input function, a pulse function, and a periodic (sinusoidal) function). These functions are often used for spectrum transmittance determination.
The Fourier transform of the heat pulse can be written in the form
where
are the real and imaginary parts, respectively, of the Fourier transform of the input pulse.
According to Eqs (2.85), (2.86) and (2.92) – (2.94), we have
64 CHAPTER 2
or
where
When the calorimeter is calibrated by a unit pulse of amplitude and sufficiently long duration, the spectrum transmittance can be expressed as
where is the calorimetric response to a unit pulse heat effect. Application of the approximation of the calorimetric response given by Eq. (2.89) yields
and, after integration, the spectrum transmittance obtained can be written in the form
where
65 CALORIMETER AS DYNAMIC OBJECT
On the basis of the above method, the algorithm of the calculation of the Fourier transforms expressed by Eqs (2.85) and (2.100) is calculated by using the Fast Fourier Transform Method [68].
The Fourier transform of the impulse response h(t) can be obtained in the case of a sinusoidal input function (Fig. 2.11):
The Fourier transform is equal to
Hence
becomes
where
It results from Eqs (2.96)–(2.99) that the accuracy of the determination of the spectrum transmittance depends on the accuracy of the determination of and Errors connected with their determination are due to the approximation of the thermograms or and also connected with the accuracy and precision of the measurements made.
66 CHAPTER 2
2.7. Methods of determinationof dynamic parameters
Selected methods will now be discussed that are used to determine the dynamic properties of calorimeters as inertial objects. Several of these methods are similar to those used in steering theory.
Different methods are presented for determining the time constant of a calorimeter treated as an inertial object of first order. The methods used to determine the dynamic parameters of calorimeters that are inertial objects of order higher than one are also discussed. All these numerical methods, algorithms and listing programs are described in detail in [67].
To apply each of the methods presented below, a knowledge of the physical properties of the investigated object is not necessary. These methods have been qualified as useful in calorimetry to identify the dynamic parameters and to study thermokinetics.
To obtain the most information about the properties of the calorimeter, it is recommended to determine the physical properties of the particular domains of the calorimeter and quantities characterizing the heat transfer between the domains themselves and between the domains and the environment. When we follow this procedure, the dynamic properties of a calorimeter can be determined by using the method of N-domains based on the general heat balance equation [Eq. (1.147)]. This method will be presented in Chapter 3.2.4.
2.7.1. Determination of time constant
The dynamic properties of a calorimeter treated as an inertial object of first order are characterized unambiguously by the time constant
To evaluate the time constant on the basis of the heat balance equation of a simple body, different input functions are used. Consider the determination of by applying the input step function [Eq. (2.45)] under conditions where the initial temperatures of the calorimeter and isothermal shield are the same. Equation (2.19) can then be written in the form
67 CALORIMETER AS DYNAMIC OBJECT
where
is determined by Eqs (2.45) and (2.47).The Laplace transform of the function y(t) corresponds to
while after the Laplace transformation Eq. (2.111) becomes
After simple rearrangement, Eqs (2.113) and (2.114) can be written in the form
Inverse Laplace transformation of Eq. (2.115) gives
The function T(t) expressed by Eq. (2.116) can be presented graphically by using the curves I, II and III shown in Fig. 2.15. The first term on the right-hand side of Eq. (2.116) is related to curve I, and the second term on the right-hand side of this equation to curve II. Curves I and II have identical shapes, but there is a shift in time between them, related to the duration of the heat impulse produced. For this period of time, the courses of the changes in the calorimeter temperature T in time t are represented by the interval 0K of curve I. When t > a, the course of the function T(t) from to the shield temperature is presented in curve III. This is the cooling curve of the calorimeter. The changes in temperature that occur here are only a result of the existing difference in temperatures The interval KM of curve III graphically represents the difference between the values T(t) of the first and second terms on the right-hand side of Eq. (2.116).
68 CHAPTER 2
When the heat generation period is long enough for a new state of thermal equilibrium to be reached, characterized by Eq. (2.19) can be written in the form
The solution of Eq. (2.117) when T(0) = 0 is
which corresponds to the first term on the right-hand side of Eq. (2.116). Equation (2.118) describes the heating process occurring in the calorimeter (curve 0I, Fig. 2.15).
Let us use Eq. (2.118) to present several procedures for determining the time constant
Procedure 1. We find the time derivative of the heating curve
From Eq. (2.119), we have that a tangent to the curve 0K crosses an asymptote of the curve at the point relating to (Fig. 2.15).
69 CALORIMETER AS DYNAMIC OBJECT
Procedure 2. At every point of the heating curve characterized by the interval 0K of the curve I (Fig. 2.15), the length of the subtangent determined by its point of intersection with the straight line is related to the time constant From Eqs. (2.117) and (2.118), we have
If we take into account the graphical presentation of the heating curve in (Fig. 2.15), we have
where
Thus, the length of the subtangent is equal to the time constant value
Procedure 3. After time T(t) is equal to
After time the temperature becomes and after time we have Proceeding in such a way for the known values of and T(t) of the heating process, we can obtain the value of the time constant or its multiplicity.
Procedure 4. The value of the time constant can be determined analytically. The values of T(t) related to time moments and correspond to
Hence, Eqs (2.124) – (2.126) become
70 CHAPTER 2
Thus
and after rearrangement we have
Procedure 5. To obtain the time constant the integration method can be used.
Hence, the time constant is equal to
Integral represents the surface area F1 between the
straight line and the heating curve (Fig. 2.16a). The changes in temperature T(t) in time, caused only by the initial
temperature difference between the calorimeter and shield, are also used to determine the time constant In this case, it is assumed that y(t) = 0,
and the cooling process is expressed by equation
71 CALORIMETER AS DYNAMIC OBJECT
The solution of Eq. (2.134) is
The course of T(t) is graphically presented by the cooling curve (curve IV) in Fig. 2.15.
The procedures used to determine the time constant on the basis of the cooling curves are not much different from the procedures presented above.
Procedure 1. The same as in the case of the heating curve; the length of the subtangent at every point of the cooling curve is equal to the time constant (see heating curve, Fig. 2.16, Procedure 2).
Procedure 2. After time the decrease in T(t) is 36.8% compared to the initial value This results from Eq. (2.135). In a similar way, the value of T(t) can be determined for the time constant multiplicity. Knowing temperaturecan determine the value of the time constant.
and choosing a matching value of T(t), one
Procedure 3. The value of the time constant can be determined analytically if at least two temperature values of the cooling process defined as a function of time are known. When, after time of the cooling proc
72 CHAPTER 2
ess, the value of T(t) becomes and, after time it becomes then according to Eq. (2.135)
Division of both sides of Eq. (2.136) by Eq. (2.137) gives
Hence
Procedure 4. The time constant for the cooling process can be calculated by an integrating procedure as for the heating process (Fig. 2.16b). On calculation of the integral:
Hence
Procedure 5. Taking logarithms of both sides of Eq. (2.135) gives
Hence
Equation (2.143) is used for the graphical determination of the time constant When the experimentally determined T and the t data for the cooling process have been obtained, the plot in the coordinates (t, lnT)
73 CALORIMETER AS DYNAMIC OBJECT
can be drawn, as shown in Fig. 2.17a [8]. When the dynamic properties of the calorimeter are characterized by one time constant the relation lnT = f(t) is expressed by a straight line (Fig 2.17a), which forms an angle with the t axis, for which
This line cuts the axis at the point of the ordinate. Thus
When the dynamic properties of the calorimeter are characterized by more than one constant of time [Eq. (2.57)], at the begining of the cooling process the relation lnT = f(t) is not linear, as shown in Fig. 2.17b. In this case, the discussed method can be applied to evaluate the higher time constants. The following procedure is used. The straight line interval (Fig. 2.17b) is extended to the point of intersection with the lnT axis and the first time constant is determined. Next, a new function of the form
is created and a new plot in the coordinate system can be drawn. The second time constant is determined. The iterative procedure is repeated until a plot similar to the plot given in Fig. 2.17a is obtained.
74 CHAPTER 2
The number of time constants which can be distinguished depends on the properties of the calorimeter and the accuracy of the determination of the experimental data.
2.7.2. Least squares method
The least squares method for determination of the transmittance parameters was proposed by Rodriguez et al. [69]. This method allows the time constants and the zeros of the transmittance nominator to be obtained by approximation of the pulse response of the calorimeter by the least squares nonlinear curve-fitting procedure described by Marquardt [70].
In order to use this method, it is necessary to assume or determine the order of the model number of poles and the number of transmittance zeros. According to these assumptions, the pulse response is a function of time t, poles and zeros
where m < N. Introducing vector the components of which are poles and zeros:
Equation (2.147) can be written in the form
As is a nonlinear function of the components, expansion of this function as a Taylor series in the neighborhood of point is applied:
neglecting the derivatives of higher order. As a criterion of fitting the experimentally determined pulse response and approximated pulse response it is assumed that
75 CALORIMETER AS DYNAMIC OBJECT
Equation (2.150) then becomes
where < 0, T > is the time interval in which the changes in pulse response are measured, and
In possession of the discrete values of the pulse response, instead of Eq. (2.152) the following fitting criterion is accepted:
where isand the sampling period. From the necessary condition of the minimum of the function expressed by Eq. (2.154):
we have the following set of equations:
Solving the set of Eqs. (2.156) with respect to leads to the poles and zeros of transmittance according to the equation
Since the linear approximation is applied to the nonlinear function, we can obtain the values of the parameters only with large error in one iteration. Thus, it is necessary to repeat the iteration, assuming the calculated values as initial values and repeat the iterative procedure until we obtain a suitable approximation of the pulse response.
76 CHAPTER 2
2.7.3. Modulating functions method
The modulating functions method was proposed by Ortin et al. [71]. This method permits determination of the poles and zeros of transmittance. The poles of transmittance are determined on the basis of an accepted model in the form of a differential equation. As the pulse response h(t) is the finite sum of exponential functions [Eq. (2.157)]:
it can be assumed that it satisfies the differential equation with constant coefficients:
where is k times the derivative with respect to time t of the pulse response of the system, and Next, the time interval in which the changes in the pulse response are measured (observed) is assumed as the basis of the modulating functions which fulfils the conditions
for i = 1, 2, ... , N; k = 0, 1,..., N – 1 is also assumed. These functions have continuous derivatives of desired order. The order and the smoothness are connected with the order of differential Eq. (2.159). Multiplying both sides of Eq. (2.159) by and intergrating with respect to time t in the interval yields
Putting
leads with respect to the coefficients to the following set of algebraic equations:
77 CALORIMETER AS DYNAMIC OBJECT
The above set of equations can be solved with respect to From the values of the coefficients from the characteristic
equation
expressions
it is possible to determine the eigenvalues (poles) of the transmittance, taking into account that the time constants
The in Eq. (2.162) contain the derivatives of the pulse response function h(t). To avoid the calculations of these derivatives, which can result in the introduction of large errors, Eq. (2.162) (after integrating by parts) can be presented in the form
taking into account the conditions given by Eq. (2.160). When we have determined the poles of transmittance and know the
value of the pulse response h(t) in Eq. (2.158), only the amplitudes are unknown. These coefficients can be determined by applying the modulating function procedure given above to the pulse response:
On putting
we obtain the following set of equations:
78 CHAPTER 2
The coefficients of the pulse response h(t) can be determined by solving the above set of algebraic equations after previous calculations of the coefficients
From the determined time constants and coefficients the Laplace transform to the pulse response gives
where
is the denominator of the transmittance, and
is the m–degree polynomial m < N with respect to s. By solving the equation
the zeros of the transmittance H(s) are obtained. The general form of the equation expressing the relation between the
generated heat power P(t) and the temperature changes T(t) of the calorimetric system has the form
Multiplying both sides of the above differential equation by the modulating function and integrating with respect to time t in the interval leads to the following set of algebraic equations with respect to coefficients and
where
79 CALORIMETER AS DYNAMIC OBJECT
The obtained set of Eq. (2.175) has a similar form as that of the set of Eq. (2.162). In the particular case when the calorimeter is calibrated by a constant heat effect of heat power and duration u smaller than
the relation for coefficients given by Eq. (2.177) (taking into account the conditions Eq. (2.159) and integrating by parts), can be simplified to the following form:
The flow diagram of the modulating functions method, the program algorithm and the listing program are given in [67].
2.7.4. Rational function methodof transmittance approximation
In this method, the transmittance H(s) is approximated by a rational function [67, 72, 73]:
where D(s) and L(s) are polynomials of degree m and N(m<N) given by
80 CHAPTER 2
The rational function L(s)/D(s) is the approximation expression of function H(s) if the expansion in the power series with respect to s is identical with the expansion in the power series of function H(s) to the degree m +N. As the criterion of fitting, we can assume
or, using Eq. (2.183), we can write
where is the number of points taken into account in the approximation. The values are calculated by numerical integration, having the values of the pulse response h(t) and assuming a set of values of the complex variable s. In order to adequately define the criterion Eq. (2.184), the values of variable s must be real. Function (2.185) is a function of N + m + 1 unknown parameters and (n = 0, 1, ... , N). The necessary condition of the minimum of function (2.185) with respect to parameters and has the form
and gives the following set of algebraic equations:
or, after simplification:
81 CALORIMETER AS DYNAMIC OBJECT
On solving the above set of equations with respect to parameters and D(s) and L(s), the quotient of which gives the expression approximating to the transmittance H(s). The roots of the polynomial L(s) yield the zeros of transmittance, and the roots of the polynomial D(s) yield the poles of the transmittance.
we can calculate their values as well as the polynomials
2.7.5. Determination of parametersof spectrum transmittance
transmittanceTo determine the dynamic parameters of the calorimetric system, the
of the compensating system (numeric or analog) [67, 74] should be matched in such a way that the resultant transmittance corresponds to the non-inertial system and fulfils the following condition:
where is the spectrum transmittance of the calorimeter. As the basis for determination of the transmittance, the experimental pulse response of the calorimeter is taken. Next, through use of the Fast Fourier Transform (FFT) procedure, the values of the amplitude (modulus) and the phase of the Fourier transform of the pulse response are calculated. These values are plotted in a Bode plot. From the Bode plot, the value of the direction coefficient of the last slope asymptote, which permits an evaluation of the difference between the number of zeros and the poles of the transmittance is determined. If this coefficient is equal to –1, the transmittance can have one pole, or one zero and two poles, or
82 CHAPTER 2
two zeros and three poles, etc. If this coefficient is equal to –2, the transmittance can have two poles, or one zero and three poles, or two zeros and four poles, etc.
To illustrate our considerations, let us assume, for example, that the value of the direction coefficient of the last asymptote is equal to –1.
Having determined the difference between the number of zeros and poles of the transmittance, on the basis of the Bode plot (Fig. 2.18) we
at which the first slope asymptote intercepts thecan find the point
axis, and thus estimate the time constant with he largest value, according to the relationship
In the knowledge of the time constant we determine a new transmittance
and its amplitude and phase and draw their plots. If the plot
relations of the amplitude and the plot of the phase are similar to the plots of the
and for a first-order inertial object in the accepted frequency range, we stop our calculation and assume that our system is the first-order inertial system of transmittance:
In the other case, from the relations and it can result that the number of zeros is equal to the number of poles. We assumed earlier, that the value of the direction coefficient is equal to –1, and we
83 CALORIMETER AS DYNAMIC OBJECT
have to deal with one pole and one zero, or two poles and two zeros, etc. Let us assume additionally that the experimental data enable us to determine only one zero and one pole more.
In the first case (Fig. 2.19), as emerges from the previous considerations, the value of the zero of transmittance is larger than the value of the second pole. Thus, we can determine from the slope of the asymptote, and we have
From the value of the horizontal asymptote, we can calculate the second time constant
After calculation of the parameters of the transmittance, we can write
In the second case, the value of the zero of transmittance is smaller than the value of the second pole. In this case, from the slope of the asymptote we can calculate and thus the value of the second time constant is
84 CHAPTER 2
From the value of the horizontal asymptote, we can calculate
from the formula
and write the form of the transmittance as above. If the amplitude plot and the phase plot of the obtained are similar to the relation that results from the dependence
transmittancein an appropriate
frequency range, we can assume that the parameters of the transmittance have been determined correctly.
Chapter 3
Classification of calorimeters Methods of determination of heat effects
3.1. Classification of calorimeters
The papers that consider determination of the heat effects that accompany physical and chemical processes present a wide spectrum of types of calorimeters. These devices have been given various names by the authors, who made their choices on the basis of different criteria. Names such as low-temperature calorimeters, high-temperature calorimeters and high-pressure calorimeters come from the conditions of temperature and pressure under which the measurements are performed. In some cases, the type of process investigated is decisive: calorimeters for heat of mixing, heat of evaporation, specific heat measurements, and others. The names of calorimeters often have to contain information about their construction features, e.g. labyrinth flow calorimeter, calorimetric bomb, drop calorimeter, or stopped-flow calorimeter. The name of the device sometimes stems from the name of its creator. Examples here include the calorimeters of Lavoisier, Laplace, Bunsen, Calvet, Swietoslawski, Junkers, and others. This diversity of the names of calorimeters justifies an attempt to find features that classify the devices unambiguously.
Let us first define a “calorimeter” as an instrument devised to determine heat. In any calorimeter, we may distinguish: 1) the calorimetric vessel (often called the cell, container, or calorimeter proper) at tem-perature that is usually in good contact with its contents, in which the studied transformation occurs. The contents include the reactant samples and subsidiary accessories necessary to achieve the investigated transformation (e.g. to initiate the reaction, or to mix the reagents) or to calibrate the device; and 2) the surroundings at temperature of
86 CHAPTER 3
ten called the shield, environment or thermostat. The surroundings form a part of the calorimeter that is functionally distinct from the measuring system, with a defined temperature time dependence [82]. It may also be considered the first thermostat shield of the calorimetric vessel (in some calorimeters there are several shields).
There are single, differential and twin calorimeters (see 3.2.2.). Various classifications of calorimeters have been presented [75–83].
The classification given here [84] is based on the assumption that the calorimeter is a dynamic object in which heat is generated. Calorimeters are graded by applying the criteria of the temperature conditions under which the measurement was made. As an initial basis for further considerations, the Fourier – Kirchhoff equation (Eq. (1.29)) has been used in the following form:
A set of simplifying assumptions is next introduced to shorten this form of equation. We assume that the process takes place under isobaric conditions. On multiplying both sides of Eq. (3.1) by volume V, we have
where is equal to heat capacity C. Furthermore, assuming boundary conditions of the third kind (Newton’s cooling law), we can write
where is the temperature of the calorimetric vessel and is the shield temperature. Taking into account Eq. (3.3), Eq. (3.2) becomes
With the additional assumptions that mass transport takes place only in the x direction, and that temperature T and heat power P are functions of the one coordinate x and time t, e.g. and Eq. (3.4) becomes
87 CLASSIFICATION OF CALORIMETERS
Equation (3.5) describes the heat transfer in calorimeters with mass exchange. These calorimeters are called open calorimeters. In contrast, calorimeters in which mass exchange does not occur are called closed systems. Then, w = 0 and Eq. (3.5) takes the form:
In the construction of a calorimeter, it is possible to provide conditions which make it possible to carry out an experiment in a desired manner, e.g. to impose the temperature conditions of the calorimetric vessel or of the calorimetric shield const., or the temperature difference between them. In this manner, the following cases of temperature conditions can be distinguished:
On the basis of the criteria listed above, calorimeters can be divided into two groups:
I. Adiabatic calorimeters, in which the temperature gradient between the calorimeter proper and the shield is equal to zero 0); during the calorimetric measurement, heat transfer does not occur between the calorimetric vessel and the shield.
II. Nonadiabatic calorimeters, in which the temperature gradient between the calorimeter proper and the shield is different from zero
during the calorimetric measurement, heat transfer occurs between the calorimetric vessel and the shield.
Two subgroups of adiabatic calorimeters one can be distinguished:
88 CHAPTER 3
Ia. Calorimeters with constant temperature They can be called adiabatic-isothermal.
Ib. Calorimeters where the temperature of the shield T0(t) changes in time. They can be called adiabatic-nonisothermal or simply adiabatic.
Nonisothermal calorimeters involve the following subgroups: IIa. Calorimeters with constant temperature T0(t) (isothermal sur
rounding shield), called isoperibol calorimeters. IIb. Calorimeters in which the shield temperature changes in
time (e.g. scanning calorimeters). In both subgroups IIa and IIb, there are calorimeters with a tempera
ture gradient that is stable in time, or with a calorimetric vessel whose temperature changes in time. The calorimeters in subgroup IIa are non-adiabatic-isothermal, whereas those in subgroup IIb are nonadiabaticnonisothermal.
The schedule of the presented calorimeters division according to the temperature conditions by Czarnota and Utzig [85] is shown in Fig. 3.1.
Let us determine particular forms of Eq. (3.6) for distinguished temperature conditions. These equations will then be treated as general mathematical models of the classified calorimeter groups. Particular forms of Eq. (3.5) will be given only for the types of open or closed calorimeters that are known by the authors.
CLASSIFICATION OF CALORIMETERS 89
1. When and Eq. (3.6) takes the form
Calorimeters that are described by Eq. (3.7) are characterized only by heat accumulation. They are adiabatic-nonisothermal calorimeters, and usually called adiabatic calorimeters. Their functioning rule is based on the assumption that the temperatures of the calorimetric vessel and the shield change in the same manner during the measurement. Their dynamic properties are those of integral objects.
Adiabatic calorimeters were first used by Richards [76, 86] and then Swietoslawski [76]. Nowadays, adiabatic calorimeters are used for studies of various transformations in a wide temperature range, from very high temperatures to very low, close to the absolute zero (0.001 K). Mention may be made of [83]: 1) low-temperature calorimeters, like those of Westrum Jr et al. [87–89], Furukawa et al. [90], Suga and Seki [91], and Gmelin and Rodhammer [92]; 2) room-temperature calorimeters, such as those of Swietoslawski and Dorabialska [93], Zlotowski [94], and Prosen and Kilday [95]; and 3) high-temperature calorimeters, e.g. those of Kubaschewski and Walter [96], West and Ginnings [97], Cash et al. [98], and Sale [99]. High-pressure adiabatic calorimeters were designed by Goodwin [100], Rastogiev et al. [101], Takahara et al. [102] and others.
In measurements performed with the use of adiabatic calorimeters, quite large amounts of substances have been applied (even several dozen grams). A series of new adiabatic calorimeters was recently designed that allow measurements on very small amounts of substance (< 1 g), among them the calorimeters constructed by Ogata et al. [103], Matsuo and Suga [104], Kaji et al. [105], and Zhicheng Tan et al. [106].
One of the first scanning adiabatic calorimeters designed in the past was the DASM 1M microcalorimeter [107], used to determine the apparent molar heat capacity and conformational changes of proteins and nucleic acids. Measurements are performed in the temperature intervalfrom 10 to 100°C, the shield heating rate can vary from 0.1 to
and the sensitivity of the instrument is A
90 CHAPTER 3
new generation of scanning adiabatic calorimeters is represented by the devices designed by S.V. Privalov et al. [108] and Plotnikov et al. [109]. Each of these instruments is constructed as the differential system.
2. When and the terms of the left-hand side of Eq. (3.6) are equal to zero. Then:
Since and are identical during the measurement, the processes in such adiabatic calorimeters take place under isothermal conditions. These conditions can be fulfilled, when two heat processes of opposite sign and occur:
where is the heat power of the process studied and is the compensating heat power.
The best-known [83] such calorimeters are those of Lavoisier and Laplace (determination of the mass of melted ice) [110], Bunsen (pycnometric determination of the volume change of the liquid water-ice system) [111], Dewar (volumetric determination of the air vaporized) [112] and Jessup (room-temperature operation based on the melting of diphenylether) [113]. In all of these devices, determinations are made of the changes in the measured quantity that result from the phase transformation. However, in this case it is very difficult or impossible to obtain conditions that correspond to thermodynamic equilibrium [76].
Progress in the development of adiabatic-isothermal calorimeters was made by Tian [114–116], who utilized the Peltier and Joule effect to compensate the generated heat power. At present, the modern electronic and steering devices applied to generate these effects permit measurements with high accuracy. A good illustration of this is the achievements at Brigham Young University [117], where this type of calorimetry has been developed for almost 40 years. The titration calorimeter [118, 119] and the few high-pressure flow calorimeters [120–122] have been constructed there.
3. When and const., Eq. (3.6) becomes
91 CLASSIFICATION OF CALORIMETERS
Methods for the determination of heat effects in these types of calorimeters are based on the assumption that
where is the heat power generated during the process examined; is the compensating heat power generated additionally to carry out
the calorimetric measurements under isothermal but nonadiabatic conditions.
This class includes the calorimeters of Olhmeyer [123], Kisielev et al. [124, 125], Dzhigit et al. [126], Pankratiev [127, 128], Wittig and Schilling [129], Zielenkiewicz and Chajn [130], Hansen et al. [131] and Christiansen and Izaat [132].
and4. When Eq. (3.6) takes the form of Eq. (3.12) for the open system and Eq. (3.13) for the closed system:
It results from Eqs (3.12) and (3.13) that the calorimeter systems described by these equations are open and closed nonadiabaticnonisothermal (n-n) systems. For the open calorimetric systems described by Eq. (3.12), heat and mass exchange occur simultaneously.
Closed, nonisothermal-nonadiabatic calorimeters have for a long time been the most widely used class of calorimeters. The heat effect that is generated in these calorimeters is in part accumulated the in calorimetric vessel and in part exchanged with its surrounding shield. These are dynamic properties of inertial objects. The parameter that is decisive as concerns their properties is the time constant (or time constants).
In this class of calorimeters, there are instruments that have time constants of and others with time constants of several They have different constructions and find various applications. Among them there are:
92 CHAPTER 3
a) Dewar vessel calorimeters in more or less sophisticated form, such as the well-known Nernst low-temperature calorimeter [133] or Pierre Curie and Laborde‘s twin calorimeter [134] used in radiology. The Dewar-type calorimeters have found application in the determination of the average specific heats of organic liquids and their mixtures [135, 136], the heat of evaporation [137], the heat of polymerization [138–142], the heats of hydration of cements [143–146], etc. Vacuum jackets of special design are used, for instance, in the accurate instrument of Sunner and Wadsö [147], and the microcalorimeters of Wedler [148], et al. [149] and Randzio [150] for measurement of the heats of chemisorption of gases on thin metal films.
b) Calorimeters with the jacket filled with water or air are mainly used to measure heat effects with a duration of a few minutes, calculated by use of the method of corrected temperature rise (§ 3.2.9). The well-known Regnault-Phaundler equation is then applied. This group includes, for example, oxygen [151–153] and fluorine [154–156] calorimetric bombs and calorimeters used to study thermokinetics and the total heat effects of reactions [157– 160].
c) High-temperature calorimeters such as those of Eckman and Rossini [161] or Mathieu et al. [162].
d) Heat-flow or conduction calorimeters, where the heat exchange between the calorimetric vessel and the isothermal shield is excellent. Most of them make use of the thermometric “heat flowmeters” in a differential assembly, like the well-known Calvet microcalorimeter [10] and the others that are characterized by very high sensitivity (they can even detect signals of and are applied for various kinds of investigations [163, 164], e.g. the metabolism in living organisms [165–167], sorption and kinetics of adsorption [168–171], photochemical reactions [93], calorimetric titration [173–175], investigation of the properties of medicaments [176], and the precipitation or crystallization of lysozyme [177].
e) Calorimeters where the heat generated is transferred to the liquid that flows around the outside surface of the calorimetric vessel, as
93 CLASSIFICATION OF CALORIMETERS
in the Junkers [178] and labirynth flow calorimeters [76, 179, 180].
f) AC calorimetry, which is applied intensively for the measurement of heat capacity in the region of phase transitions [181–185].
g) A number of “quasi-adiabatic” calorimeters are used in such a way that, in the calculation of the heat involved, the transfer of heat between the calorimetric vessel and the surroundings is neglected. Such are the flash calorimeters of Rosencwaig [186, 187], Callis et al. [188] and Braslawsky et al. [189], and the photoacoustic calorimeter of Komorowski et al. [190].
There are open nonisothermal-nonadiabatic calorimeters like those of Picker, Jolicoeur and Desnoyers [191–193].
When measurements in an open, flow n-n calorimeter are made after a relatively long time
Equation (3.12) takes the form
Relationship (3.17) describes the processes occurring in the flow and stopped-flow calorimeters of Roughton [194, 195], Kodama and Woledge [196] and Berger [197].
5. When and Eq. (3.6) takes the form for the closed system:
Equation (3.18) describes the nonisothermal-nonadiabatic system in which changes occur in the shield temperature. The temperature rise is usually linear and described by the ramp function (Eq. 2.49) as in the
94 CHAPTER 3
Calvet scanning microcalorimeter. There are several thermal analysis devices for which Eq. (3.18) in its simplified form can be considered as mathematical model. They operate via observation of the temperature of the samples caused by the forcing function generated on the shield. This group includes: devices for heating and cooling curve determination (temperature measurement); differential thermal analysis, DTA (measurement of the temperature difference between the studied sample and the standard substance) [198, 199]; heat flux differential scanning calorimetry, hf-DSC (determination of the difference in heat flux between the studied sample and the standard substance to the shield [200]; and modulated temperature differential calorimetry, mt-DSC (the temperature change of the sample described by the frequency and amplitude of vibration) [116].
Regardless of which measurement method is used, in each of them the heat effects generated in the sample and in the calorimeter shield are superimposed. In consequence of the same type of inertial properties (of inertial objects) of the devices mentioned, the course of the output function caused by the programmed rise of temperature of the shield is always the same (see § 3.2.5). Let us confine ourselves to considering only the changes in temperature that are caused by linear rise of the shield temperature When the initial temperature of the shield
the temperature of the vessel and the ramp function is
Equation (3.18) then takes the form
Division of both sides of Eq. (3.20) by G yields
The solution of Eq. (3.21) is
95 CLASSIFICATION OF CALORIMETERS
When the calorimeter proper and the shield are initially in thermal
equilibrium, i.e. and are equal to each other, and the measurement is performed until conditions of stationary heat exchange between
the calorimeter proper and shield Eq. (3.22) takes the form
The courses of the changes in and according to Eq. (3.22) are presented in Fig. 3.2. This shows that after a certain period of time
following the start of measurement, the course of change in becomes linear. From this point, the difference between and is equal to and the shift between the temperature curves is equal to the time constant Such a temperature course is observed when the sample is a thermally passive object. For an endothermic reaction, the line appears to be twisted as a result of decrease of the heating rate. For an exothermic reaction, the twist of the line is linked to the increase of the heating rate. This is presented in Fig. 3.3(a). Figure 3.3(b) shows the temperature change reading determined by differential measurement. In the case of a Calvet DSC microcalorimeter, thermogram data are usually used for the determination of P(t) and then Q(t).
96 CHAPTER 3
6. When and const., Eq. (3.6) (similarly as previously) takes the form of Eq. (3.10), i.e.
The function P(t) is a superposition of at least three heat forcing functions relating to the heat power generated by the studied process, the compensating heat power and the heat power generated in the shield in order to keep its temperature in compliance with the programmed changes.
When Eq.7. and (3.6) becomes
The authors do not know any examples of calorimeters of this type.
97 CLASSIFICATION OF CALORIMETERS
The classification of calorimeters presented above conforms with that given in 1930 by Lange and Miszczenko [1], who distinguished four groups of calorimeters:
1) isothermal-adiabatic; 2) isothermal-nonadiabatic; 3) nonisothermal-adiabatic; and 4) nonisothermal-nonadiabatic. Obviously, the experimental description of the device should also
contain information such as: 1) the purpose of the instrument (combustion, heat of mixing, heat capacity, sublimation, etc.); 2) the principles and design of the calorimeter proper, including the ranges of temperature and pressure in which measurements can be performed; 3) the measured quantity and measuring device; 4) the static and dynamic properties of the calorimeter; the calibration mode and the methods of measurement and determination of heat effects; 5) the operational characteristics of the calorimetric device, the sensitivity noise level, the method of calibration, the accuracy, etc.; 6) a description of the experimental procedure used in the calibration and the actual measurements.
The mathematical models of calorimeters presented above were applied as the basis of methods used to determine heat effects.
3.2. Methods of determination of heat effects
3.2.1. General description of methodsof determination of heat effects
Many methods are used to determine heat effects. Some of them allow the determination of the total heat effect Q studied, while others permit the determination not only of the total heat effects, but also of the course of thermal power P in time t (function P(t), called the thermokinetics or thermogenesis).
For the characteristics of these methods, the general heat balance equation (Eq. (1.148)) has been used [21]:
98 CHAPTER 3
In an adiabatic method (§ 3.2.3), it is assumed that only heat accumulates in the calorimeter, which is treated as an integral object. A generated heat effect P(t) is then described by the first term on the right-hand side of Eq. (1.148).
Several methods are used for nonadiabatic calorimeters. In the multidomains (N-domains) method (§ 3.2.4), particular forms
of Eq. (1.148) are applied, depending on the number of distinguished domains, and their mutual location. A similar procedure is applied in the method of finite elements (§ 3.2.5).
In the dynamic method (§ 3.2.6), the calorimeter is treated as a simple body of uniform temperature. The detailed form of Eq. (1.148) is then a heat balance equation of a simple body. The dynamic method is a one of the most frequently used in the determination of total heat effects and thermokinetics.
In the modulating method (§ 3.2.8), Eq. (1.148) is usually reduced to the form of a heat balance equation of a simple body [Eq. (1.99)], one of the input forcing functions being a periodic function.
In the flux method (§ 3.2.7), the calorimeter is treated as a proportional object. In this method, it is assumed that the accumulation of heat in the calorimeter proper is negligibly small.
The steady-state method (§ 3.2.9) is based on the assumption that the heat power generated in the calorimetric vessel is compensated by additionally generated heat power of opposite sign. The calorimeter is treated as a proportional object. The inertial properties of the calorimeter are neglected. The left-hand side of Eq. (1.148) is equal to zero.
The heat balance equation (Eq. (1.148)) reduced to the heat balance equation of a simple body [Eq. (1.99)] is also the basis of many methods used to determine total heat effects. One of the best-known is the method of corrected temperature rise (§ 3.2.10), often called the Reg-nault-Phaundler correction.
A group of methods exist which a priori assume that the calorimeter is an inertial object of N order. A model of the calorimeter is expressed
CLASSIFICATION OF CALORIMETERS 99
in the form of a convolution function [42, 43]. The set of linear differential heat balance equations resulting from Eq. (1.142) is then replaced by one equation of N order. Let us derive the equations that are the mathematical models of these methods. Equation (1.148) in its matrix form gives
where is the diagonal matrix whose elements are the heat capacities
of the particular domains; is the matrix whose elements are the heat loss coefficients; T(t) is a vector whose components are the tempera-
the heat powers of the distinguished domains; andP(t)tures of the particular domains; is a vector whose components are
is the derivative of the T(t) vector. Laplace transformation of Eq. (1.146) gives
where s is the Laplace operator, is the initial state vector (the initial temperature condition in the domains), and T(s) and P(s) are the Laplace transforms of state vector T(t) and P(t), respectively. The solution of Eq. (3.27) in the complex domain s is
where
is the transfer matrix; in the frequency domain the solution is
and in the time domain t, the solution is
where H(t) is the matrix of fundamental solutions. If it is assumed that
100 CHAPTER 3
where is the sampling period and is the Dirac function, Eq. (3.31) can be rewritten as
If it is additionally assumed that the heat source is located in one domain only, and that the temperature is measured in one domain only and under the zero initial temperature, Eqs (3.30), (3.31) and (3.33) define the mathematical models for reconstruction of the thermokinetics P(t). Equation (3.32) written in the form
corresponds to the mathematical model of the harmonic analysis method (§ 3.2.11.1). Eq. (3.31) in the form
represents the mathematical model of the dynamic optimization method (§ 3.2.11.2). Equation (3.26) is the basis of the state variable method (§ 3.2.11.4). Equation (3.33) in the form
represents the mathematical model of the thermal curve interpretationmethod (§ 3.2.11.3). Under zero initial conditions, Eq. (3.28) in the form
where
represents the mathematical model of the method of transmittance decomposition (§ 3.2.11.5).
Techniques that use analog and numerical correction of the dynamic properties (§ 3.2.11.6) of the calorimeter compensate the transmittance zeros and poles and can be also applied to reconstruct the thermokinetics. In agreement with Eq. (3.41), the transmittance has the form
CLASSIFICATION OF CALORIMETERS 101
where S is the gain factor.
3.2.2. Comparative method of measurements
Calorimetric determinations are based on the comparative method of measurements. The International Conferences on Chemistry in Lucerne in 1936 and in Rome in 1938 accepted the proposal that all physicochemical measurements should be divided into two groups, absolute and comparative [202–205]. The absolute measurements include the determination of absolute values characterizing a given physicochemical property of chemical compounds or a mixture. It is necessary to introduce all secondary factors which would change the numerical value determined by the absolute method. Absolute measurements should be carried out exclusively by specialists working in bureaus of measures and standards or in laboratories sufficiently adapted for high-precision measurements. A comparative method of measurements can be performed when possible to assume certain substances as standards and the properties of the investigated systems can be compared with the identity of substances. The main principle of this method is the identity of conditions during the measurements and the system calibration. The achievement of this condition is difficult on determining the heat power by the methods when the consideration of the physical parameters of the system is abandoned. In these methods it is assumed a priori that the transmittance of the calorimeter during the calibration and measurement are the same.
The method of comparative measurements is often performed with use of the differential method of measurement, which is defined [206] as “a method of measurements in which the measurand is compared with the quantity of the same kind, of known value only slighty different from the value of the measurant, and in which the difference between the two values is measured”.
102 CHAPTER 3
The differential method of measurement is the basis of the use of differential calorimeters. It is assumed that such devices are constructed of two identical calorimeters (I and II) located in a common shield. One of them contains the sample in which the heat effect is generated; in the second, the thermally passive object (or standard substance) is located. The course of the change in temperature of calorimeter I in which the heat effect is generated is based on the measured temperature difference between calorimeters I and II.
The conditions of the differential method of measurement are fulfilled when: a) the static and dynamic properties of the two calorimeters are identical; and b) the influence on calorimeters I and II of the input forcing functions generated in the surroundings are the same. This manner of temperature difference measurement allows determination of the temperature changes caused by the heat power generated in the sample, and elimination of the influence of other forcing functions. This method is very often used in isoperibol and scanning calorimetry, in DTA de– vices and in some cases in adiabatic calorimetry.
From the dynamic properties of differential calorimeters, it is clear that the disturbances can be eliminated only if the transmittances of calorimeters I and II are the same. It is very difficult to fulfill this condition. Hence, for a given differential calorimeter it is useful to determine an acceptable range of difference of the time constants for which, for a given disturbance and required accuracy of T(t) measurements, the assumption of a differential character of the calorimetric system is satisfied [207]. The application of the dynamic equations discussed in Chapter 4 can be very helpful in this type of investigations.
An other type of calorimeters used is the group of devices called twin calorimeters. In such calorimetric systems, it is necessary to obtain equal temperatures of the inner parts of calorimeters I and II in such a way that in calorimeter II a the heat power has the same magnitude and course as that in calorimeter I. It is obvious that, for twin calorimetric systems, similarly as for differential calorimeters, the dynamic properties of the two calorimeters should be the same.
CLASSIFICATION OF CALORIMETERS 103
3.2.3. Adiabatic method and its application in adiabatic and scanning adiabatic calorimetry
The adiabatic method [76, 87–89] is based on the assumption that no heat exchange occurs between the calorimetric vessel and the shield. The calorimeter has the dynamic properties of an integral object. “Ideally, the adiabatic shield is always maintained at the temperature of the calorimeter so that there is no temperature differential [208].”
To perform the measurement, two methods are used. In the first, called the continuous heating method, the calorimeter proper and the shield are heated at constant power input throughout the whole period of measurement. The course of the temperature change with time is measured, as is the electrical power supplied to the calorimeter heater. We assume that the thermal power generated is used only to heat the studied substance and the other parts of the calorimeter proper. If this assumption is true, then the three quantities temperature, energy rise and temperature rise (caused by the energy rise) are sufficient to define the measured quantity used to determine the specific heat at temperature T. The generation of electric energy inside the calorimeter proper does not always lead to a temperature rise. It can happen that an isothermal rise of the enthalpy occurs during the studied process.
In the second method, the temperature of the calorimeter proper is measured with no power input. First, the calorimeter proper is heated at constant power for a known time interval to attain a certain temperature. After the power is turned off, the temperature is measured. Then, the current supply can again be switched in and next, after switching-off, the temperature will be measured. This cycle can be repeated several times. Such a procedure is called the intermittent-heating method. Both of the measurement procedures described above are used in practice. The first permits control of the temperature of the calorimetric shield in an easier way and it is certainly more convenient to obtain results in a full range of measurement. The second procedure permits study in a precise way of these temperature ranges where interesting phenomena (e.g. unknown phase transitions) are to be observed.
104 CHAPTER 3
3.2.4. Multidomains method
The multibody (domain) method [67, 209, 210] allows the determination of thermokinetics as well as the total heat effects of the process examined. The method is based on the general heat balance equation [Eq. (1.148)]. The mathematical model of the calorimeter is described by the following set of equations:
where N i j;
i
is the number of distinguished domains; is the heat loss coefficient between domains and the is the heat loss coefficient between domain and the shield; and is the heat power.
Equation (3.41) describes the “changeable” part of the calorimeter; it is assumed that is the heat capacity of the calorimetric vessel with the contents. The remaining part of the calorimeter described by Eq. (3.40) corresponds to an “empty” calorimeter. This part is called the “nonchangeable” part of the system.
The above form of the set of equations indicates that, for various heat capacities there is no need to change the mathematical model of the calorimeter; a change in calls only for the introduction of new data in the deconvolution program. This can also be applied when the heat capacities of the calorimetric vessel content changes during the experiment (e.g. in the titration process).
The form of the heat balance equations for a given calorimeter depends on a number of factors, such as the number of defined domains, the interactions between the domains, and the mutual location of the heat source and temperature sensor. This means that the mathematical form of the equations is related to the thermal and geometrical parameters of the calorimeter and to the location of the sensors and heat
105 CLASSIFICATION OF CALORIMETERS
sources. It is accepted that each of the domains has a uniform temperature throughout its volume and that its heat capacity is constant. Temperature gradients occur only in the media that separate these domains, and the heat capacities of the media are taken to be negligibly small. The amount of heat exchanged between the domains through these media is proportional to the difference between their temperatures. The proportionality factors are the corresponding heat loss coefficients, and a heat source and temperature sensor can be located between them. The system of domains is located in a shield of temperature, which is treated as the reference temperature.
To elaborate the dynamic model, it is necessary to calculate the heat capacities of defined domains and the heat loss coefficients, and to determine the structure of the model. For example, qualitative analysis of the heat exchange in the BMR calorimeter [157] (Fig. 3.4) on the basis of the calorimeter construction allowed the distinction of 19 domains.
The distinguished domains are individual parts of the calorimeter. A
presented inblock diagram of a such system, elaborated by Cesari et al. [211], is
Fig. 3.5, where are the interaction coefficients between the domains. The calorimeter was divided into upper U and lower B parts, because there is no symmetry of the device in the horizontal plane.
106 CHAPTER 3
Starting from the vertical symmetrical axis going through the center of the calorimetric vessel, the following domains were chosen for the parts of the calorimeter: 1, 2 – the calorimetric heater R; 3, 4– the shield A of the heaters; 5–8–the block vessel, 9, 1 0–t h e cylindrical parts of the vessel shield; 19 – the bottom part of the shield; 11,2,15,16– thermocouples; 13, 14–thermocouple supports; 17–inner thermostat block; 18– vessel shield support. It was assumed that the calorimeter is ideally differential, and that the other twin battery has been eliminated, because it does not contribute to the transfer function. The heat capacities of each of the domains were calculated on the basis of its geometry and its parameters: the specific heat and density of the domain material; coefficients were calculated from the equation where is the thermal conductivity; F is the surface area of heat exchange; and is the distance between the centers of the neighboring domains. This relation was applied when the surface dividing the domains was a plane. For a cylindrical surface of heat transfer, the equation
107 CLASSIFICATION OF CALORIMETERS
was used, where l is the height of the cylinder; and and are the radii of the cylindrical surfaces that pass through the centers of the neighboring domains.
The elaboration of the model allows determination of the set of heat balance equations. The procedure of calculating the calorimetric response starts from the heat balance equation of the domain in which the heat source is located, with the assumption of zero initial conditions for all the temperatures, for i = 1,2, ... , N. On substituting the derivatives in the set of Eqs (3.40) and (3.41) by differences, we obtain
The temperature changes vs. time are calculated from
When the values of are known, the temperature is calculated, and next the temperatures of the neighboring domains are calculated from Eq. (3.43). The last equation in the loop calculates the temperature of the sensor. The temperature changes in these domains are the model responses to a given heat effect. There are as many equations as domains distinguished and all calculations are carried out in one calculation loop.
The algorithm of the thermokinetics calculation is very similar to that for thermogram calculations. The beginning of the procedure is the temperature of the sensor. Next, the temperature of the neighboring domain is calculated, assuming zero initial temperature for the remaining domains. For a system of domains, Eq. (3.42) for can be written in the form
108 CHAPTER 3
Equation (3.44), which is the calculation loop, is used N–1 times to calculate the temperatures of neighboring domains. The final calculation of the heat power gives
where z is the index of the heat source domain, and z – 1 is the index of the domain next to z.
For a model of more complicated configurations, when one domain can have more than two neighbors, one calculation loop has as many equations as neighbors. For example, domain j has r neighbors. The heat exchange between these domains is characterized by heat loss coefficients Coefficients and are the heat loss coefficients between domain j and its neighbors and between domain j and the shield, respectively; The calculation loop will then be a set of r equations of the form
where r is the index of the neighboring domain to the j domain. The following loops are related to the number of domains and the configuration between them, up to the last loop for calculating the course of heat power in time.
The transmittance (Eq. 2.41) of the calorimetric system has the form
where is the root of the transmittance (the root of the numerator of the transmittance) and is the pole of the transmittance (the root of the dominator of the transmittance); S is the static amplification factor. The finding of the real form of the transmittance is the same as determination of the dynamic properties of the examined calorimetric system. In this method, it is assumed that synchronous knowledge of the
CLASSIFICATION OF CALORIMETERS 109
real transmittance form and S and will be suitable for determination of the thermokinetics, but only when the optimization and stability conditions of the numerical solution are fulfilled. These conditions demand the admission of the value of a sampling period obtained from the amplitude characteristics of the calorimeter, taking into account the noise-signal ratio [see § 3.2.11.7]. The optimal sampling period limits the smallest value of the time constants. If any number of time constants of the calorimeter does not satisfy the stability condition, the a new model of the system must be worked out, decreasing the number of domains and calculating new parameters. The maximum order of the new model is limited by the number of time constants which satisfy the stability condition. Next, the model response to a given heat effect is compared with the experimental response. If the result is positive, this means that a model useful for the determination of thermokinetics has been elaborated.
3.2.5. Finite elements method
The finite elements method was proposed and described by Davis and Berger [212]. This method is based on the following assumptions. A certain number of elements are distinguished, between which the heat exchange is characterized by the heat loss coefficients For each element, the heat capacity is calculated. It is assumed that temperature for each of the distinguished element is known at moment t and next calculated for For each i-th element, the amount of heat exchanged between the element i and element i+1 is determined by the equation
For each element, we can write
Thus:
110 CHAPTER 3
Next, the temperature of each element is calculated after time
For example, if for the first element oftemperature the heat power P is generated during time then after time the change in temperature of this element is
The result of these calculations is the thermogram, which represents the course of the changes in time of the temperature of the element in which the sensor was placed.
Thermokinetics is determined on the basis of deconvolution of the pulse response of the examined system and the measured thermogram. For calculations, the first nonzero value of the pulse responseis taken. The increase in temperature of the element (in which the heat effect is generated) is determined on the basis of the equation
where is the increase in temperature of the element in which the sensor is placed. The magnitude R plays the role of the multiplier, which allows transformation of the sensor signal to the signal in the reaction vessel. In order to determine the thermokinetics at moment it is necessary to know the temperature distribution of all elements and the heat power P at moment t. In each sampling period the increase in temperature is caused by two effects: 1) the heat generated by the reaction (or pulse), which causes the temperature increase; and 2) the heat transferred, which causes the temperature increase Thus, the increase in temperature of the sensor, according to the superposition principle, is given by the formula
The increase in temperature is calculated on the basis of Eqs (3.48)–(3.51). The value of the temperature increase is determined on the basis of the thermogram obtained, and the increase in temperature
is calculated as the difference
CLASSIFICATION OF CALORIMETERS 111
The value of the increase in temperature is calculated on the basis of Eq. (3.53). Thus, the temperature of the reaction vessel for is
PThe heat power for is given as
The presented method permits the use of an iterative procedure to determine the values of heat power in sequenced time moments. This method is very sensitive to the errors in the determination of the value of the pulse response and coefficient R.
3.2.6. Dynamic method
tion of: a) the course of the thermal power change in time, The dynamic method [10] of measurement is used for the determina-
b) the course of the temperature change vs. time, which characterizes the course of the thermal power change in time; and c) the total heat effect. As the mathematical model of the calorimeter, we use here the heat balance equation of a simple body [Eq. (1.99)].
As concerns the explanation of the method principles, let us assume that the calorimeter proper at temperature is surrounded by a shield at constant temperature while the results of the temperature difference are expressed by function T(t). This assumption enables us to discuss this method by using the procedure proposed by Calvet [10].
To describe the relation between the generated heat effect Q(t) and the difference T(t) in the calorimeter proper and the shield temperatures, Eq. (3.13) is used in the form
or in the form
112 CHAPTER 3
while to describe the course of the thermal power change in time expressed as a function of temperature, the dynamic equation is used:
The first term on the left-hand side of Eqs (3.58) and (3.59) is equivalent to the amount of heat accumulated in the calorimeter proper, while the second term on the left-hand side of these equations is equivalent to the amount of heat exchanged between the calorimeter proper and the shield.
Measurements of the temperature are usually made by using sensors such as a resistance thermometer and thermistor, where the resistance is a function of temperature, or a thermocouple and thermopile, where the electromotive force is a function of temperature. Accordingly to express T it is convenient to use the quotient with where is the measured magnitude, and g is the factor of proportionality. Equation (3.58) then becomes
Integration of Eq. (3.73) leads to
where notes the values of and at times and while
is equal to the surface area F located between the course of changes in time and the time axis t. The values of and F are the results of calorimetric measurement. The values of C/g, G/g, and are determined via the calibration procedure. Equation (3.61) is often called the Tian– Calvet equation.
The calibration consists in generating a rectangular pulse [Eqs (2.45) and (2.46)] of known heat power inside the calorimetric vessel in a time long enough for a new state of stationary heat exchange to be achieved. In practice, it is characterized by a constant temperature difference, de
113 CLASSIFICATION OF CALORIMETERS
scribed as and simultaneously by constant value Allowing a small error, we can assume that it occurs in the time period equal to The solution of Eq. (3.60) is then
and for Eq. (3.61)
In this way, the value of G/g is defined. Quite often, it is useful to determine a set of values G/g by generating rectangular pulses with different amplitudes. It can then be verified if a value of coefficient G/g is constant in the interesting range of changes in the temperature of the calorimeter. This constant value means that the calorimeter has the linear properties of a dynamic object.
If the generation of the rectangular heat pulse is stopped, then the calorimeter becomes a thermally inertial object. Cooling of the calorimeter then occurs up to the moment when the temperatures of the calorimeter and the shield are the same. This process has been described by Newton‘s cooling law [Eq. (1.104)] and is used to determine the value of the time constant (see § 2.7.1).
In the knowledge of and G/g, by means of Eq. (1.103) we can determine the value of C/g:
Besides the determination of the time constant value, very important information is provided by observation of the course of the changes for the calorimeter as a thermally inertial object. When the changes = f(t) are nonlinear during the initial period of the cooling or heating process, it is necessary to analyze whether application of the simple body heat balance equation to the calculations is correct. A nonlinear course of means that the function is multiexponential. More precise equations expressing the relation between P(t) and T(t) should then be used. The calibration procedure presented here is not the only one used in the dynamic method. The literature on this subject
114 CHAPTER 3
contains several modifications of such way of calibration, e.g. [7, 159, 160].
3.2.7. Flux method
The dynamic method presented above is based on the assumption that the heat effect generated in the calorimeter proper in part accumulates in the calorimetric vessel, and in part is transferred to the calorimetric shield. When excellent heat transfer occurs between the calorimeter proper and the shield (as in conduction microcalorimeters), it can be assumed that the quantity of heat accumulated is extremely small. This assumption is the basis of the flux method. The amount of heat transferred between the calorimeter proper and the shield is then directly proportional to the temperature difference. Thus, the course of obtained from the measurement resembles that of P(t), and its value is determined on the basis of the second term on the left-hand side of Eq. (3.61):
while the total heat effect is
which results from Eq. (3.62).
3.2.8. Modulating method
The modulating method is based on the measurement of the temperature oscillations of a sample heated by oscillating heat power. Under isoperibol conditions, this method is called AC calorimetry [213–215]. The first AC calorimetry experiments were performed in 1962 by
CLASSIFICATION OF CALORIMETERS 115
Kraftmacher [213], who measured the heat capacities of metals in the high-temperature region.
Reading et al. [216, 217] proposed a method in which a DSC is used. In this case, the response of the calorimeter as a linear system would be a superposition of two input functions: 1) the ramp function [Eq. (2.49)] generated in the calorimetric shield and 2) the periodic function generated in the sample. When the periodic function is sinusoidal [Eq. (2.53],
where is the initial temperature, is the temperature amplitude and v is the angular frequency. The solution of Eq. (3.68) in the case of steady-state temperature modulation of the sample, according to Eqs. (2.55) and (3.26), is
where is the time constant, which corresponds to and is the phase angle given by
The resultant signal is then analyzed by using the combination of a Fourier transform to deconvolute the response of the sample to the underlying ramp from its response to the modulation that can give rise to an underlying and a cyclic heat capacity. For data evaluation, two procedures are used, for “reversing” and kinetic “nonreversing” components [217], the determination of “storage” and “loss” heat capacities [218, 219]. The “reversing” parameter is most readily identified with the heat capacity of the sample, whereas the nonreversing component includes contributions from irreversible processes such as crystallization, glass transition, and the melting of polymers.
Temperature-modulated differential scanning calorimetry is a new analytical technique used to obtain information on the heat capacity in
many instruments, e.g. as the Modulated DSCthe range close to the phase transformation. It is a method applied in
of TA Instru
116 CHAPTER 3
ments [220, 221], the Alternating DSC of Mettler-Toledo [222] or the ODSC (Seiko Instruments) [223].
3.2.9. Steady-state method
In order to obtain a constant gradient of temperature between the calorimeter proper and its environment, the steady-state method is used. The method is based on the assumption that the following condition is fulfilled:
where is the heat power generated during the process examined; is the compensating heat power; P(t) = 0 (adiabatic-isothermal
calorimeters) or P(t)= const. (adiabatic-nonisothermal; compensating DSC).
Let us apply Eq. (3.6) to formulate the basis of the method. Integration of both sides of Eq. (3.6) with respect to time in the in
terval gives
or
Let us assume that the temperature can be expressed by two terms:
where is the average temperature of the calorimeter proper (the calorimetric vessel), and are the temperature oscillations around the average temperature. Thus, the temperature increment in the considered time period is
CLASSIFICATION OF CALORIMETERS 117
The integral of Eq. (3.73) can then be written in the form
or
When the temperature of the shield can be assumed to be constant:
the third term on the left-hand side of Eq. (3.77) is
and Eq. (3.77) becomes
If it is additionally assumed that the amplitude of temperature oscillations around the average temperature is negligibly small, we can put
and Eq. (3.80) simplifies to the form
For adiabatic-isothermal calorimeters, it is assumed, that 0 and the first term on the left-hand side of Eq. (3.82) is neglected. The thermal power is used to compensate
For adiabatic-nonisothermal calorimeters when to determine the amount of heat it is necessary to know the time interval of the process, the average temperature the heat loss coefficient G and the amount of heat delivered to the calorimeter proper in order to hold the desired value with minimum oscillations.
118 CHAPTER 3
The thermal power is produced by several pulses of Peltier or Joule effects by:
a) Application of pulse compensation consisting in the generation of quantized thermal power pulses as shown in Fig. 3.6, where A is a pulse amplitude, is the pulse duration, and F is frequency.
b) Use of proportional compensation; it is assumed that the temperature change is proportional to the generated compensation thermal power
or
c) Use of proportional-integral compensation; the proportionality of to and to the integral value of is assumed:
where is the integration constant.
CLASSIFICATION OF CALORIMETERS 119
3.2.10. Method of corrected temperature rise
The method of corrected temperature rise [224, 225, 8] is used to determine the total heat effects in n-n isoperibol calorimeters. The method is based on the heat balance equation of a simple body in the form
If we put
Eq. (3.87) can be written in the form
where
increment
.
is called the corrected temperature rise. The amount of heat generated in the calorimetric vessel corresponding to the temperature
can then be expressed as
The determination of is the aim of the calorimetric measurementThe heat capacity C of the calorimeter is determined during the calibration in which a heat effect of known value is generated.
In the calorimetric measurement, three periods can be distinguished (Fig. 3.7): the initial period (segment AB); the main period (segment BC); and the final period (segment CD).
During the initial period the temperature changes before the examined heat process are measured. The beginning of the main period
is the initial moment of the generation of heat by the process studied. As the end of the main period, the time moment is assumed as the end of the studied process. During the final period, the temperature
120 CHAPTER 3
changes of the calorimeter after the examined heat process are measured.
In the method, it is assumed that, independently of the heat process studied, during the whole period of measurement a constant heat effect can be produced in the calorimeter by secondary processes (for example, the process of evaporation of the calorimetric liquid, the friction of the stirrer on the calorimetric liquid, etc.). The course of the temperature changes is then described by
expressing Newton’s law of cooling by magnitudes u corresponding to the constant heat effect. If we assume that
where is the increment of temperature of the calorimetric vessel, which corresponds to the constant heat effect, involve by secondary process Eq. (3.91) can be written in the form
It is assumed that this equation is valid in the initial and the final periods of measurement. In the initial period, we have
121 CLASSIFICATION OF CALORIMETERS
and in the final period, we have
Because of the small changes in temperature in these periods of measurement, we can approximate them as linear changes in time. Thus,
and can be treated as constant, and can be ascribed to the average
temperatures and of the initial and final periods, respectively:
By subtraction from Eqs (3.96) and (3.97), we can calculate the value of the cooling constant as
Let us assume that the constant heat effect caused by the secondary
temperatureprocess exists in the main measurement period too. In Eq. (3.87), the
T(t) must be substituted by the term thus, we have
The value of the integral
can be approximated by the expression
122 CHAPTER 3
where are the values determined during the subsequent readings of temperature T(t) in the main period; and This method involves the assumption that, in small time intervals of the main period, temperature T(t) changes linearly, and the average temperature of the main period is the arithmetic average of the average temperatures obtained in these small time intervals. On determining from Eq. (3.94), we have
Similarly, from Eq. (3.95), we obtain
Use of Eqs (3.99), (3.101) and (3.102) leads to
Substitution of according to Eq. (3.98) gives
On substituting Eqs (3.101) and (3.103) into Eq. (3.99), we can write
or on substituting by expression (3.98), we obtain
123 CLASSIFICATION OF CALORIMETERS
Equations (3.105) and (3.107) for the temperature correction are called the Regnault-Phaundler correction. They assumed the sampling period to be equal to unity, and thus This correction is
ture rise mostly used in isoperibol calorimetry to calculate the corrected tempera-
Depending on the need for precision of the temperature measurement, various approximations of the course of temperature T(t) are used. The graphicel-numerical methods of calculating the corrected temperature rise include the Dickinson method [226]. White [227, 228] proposed the Simpson rule for calculation of the integral of Eq. (3.100). Roth [229] used the least squares method for approximation of the initial and final periods by straight lines. Planimetry at first was used to obtain this integral.
3.2.11. Numerical and analog methodsof determination of thermokinetics
3.2.11.1. Harmonic analysis method
In this method, first used by Navarro et al. [230, 231] and by van Bokhoven [232, 233], the convolution recorded in the frequency domain is accepted as the transformation equation [Eq. (2.8)] of the calorimeter. For the determination of an unknown heat effect, it is assumed that the spectrum transmittance (§ 2.6) has been determined previously. Next, an unknown heat effect is generated and the calorimetric signal is measured. After determination of the spectrum transmittance and the calorimeter response the thermokinetics is obtained as the inverse Fourier transform
where is the Fourier transform of the response As a criterionof the possibility of reproduction, Shannon’s theorem is applied. In practice, a frequency is used which is obtained on the basis of the transfer
124 CHAPTER 3
function calculated. The practical frequency is determined on the basis of the dependence
where is the value of the spectrum transmittance amplitude for v
= 0, is the value of the amplitude for the practical frequency,
and noise is the noise amplitude.
3.2.11.2. Method of dynamic optimization
In the dynamic optimization method [234–236], Eq. (2.9) is taken as a mathematical model of the calorimeter, and thus appropriate zero initial conditions are assumed. This method assumes the existence of one input function T(t) and one output function P(t). The impulse response H(t) is determined as a derivative with respect to time of the response of the calorimetric system to a unit step. As a criterion of accordance between the measured temperature change T(t) and the estimated course of temperature x(t), the integral of the square of the difference between these two courses is taken:
or, on substituting the convolution of functions, we obtain
The task of dynamic optimization consists in selection of the unknown thermal power P(t) so that Eq. (3.111) attains a minimum. Such a task can be solved provided that the temperature response T(t) and the impulse response H(t) of the calorimeter are known in the analytical form. However, in calorimetric measurements, numerical values
CLASSIFICATION OF CALORIMETERS 125
are usually available on the course of the temperature changes T(t) of the calorimeter. Because of this, the integrals in function (3.111) are approximated by sums, and the function therefore becomes a function of multivariables:
In the search for the minimum of function (3.112), a conjugate gradient method is used.
3.2.11.3. Thermal curve interpretation method
It is known that the response to a Dirac heat pulse of unit amplitude is the pulse response For stationary linear systems, the response to a heat pulse generated at time moment is
In the method [237, 248], it is assumed that the heat effect P(t) generated can be approximated by the function
The thermogram T(t) can then be approximated by the expression
or
where is the sampling period, are the values of the heat pulse generated at moment j, and is the i-th value of the pulse response, which corresponds to the unit pulse generated in the calorimeter at moment j.
126 CHAPTER 3
The aim of the spectrum method is to find the values of coefficients The scheme of searching for the values of these coefficients can be
shown as follows. Let us transform the set of functions into the set
of orthonormal functions –
The condition of orthonormal functions has the form
where
Orthonormalization of the function [Eq. (3.117)] is difficult, because we orthonormalize very similar functions.
Using the basis of orthonormal functions and curve T, the coefficients are calculated as
Applying the inverse transformation to transformation (3.117), weobtain the values of coefficients as
The computer realization of this scheme is very simple under the condition that the orthonormalization does not give problems. The thermal curve interpretation method was proposed by Adamowicz [237– 239].
CLASSIFICATION OF CALORIMETERS 127
3.2.11.4. Method of state variables
In the method of state variables [240–242], a certain set of parameters is distinguished:
which characterize the calorimetric system. These values are referred to as state variables. Three types of state variables are distinguished: physical variables, canonical variables and phase variables. The vector
the components of which are state variables, is referred to as the state vector. Thus, the calorimeter transformation equation combines the state variables with the parameters of the calorimetric system and the thermal power produced:
The state equation (Eq. (3.124)) written in this way is a system of first-order equations. Because of the available calorimetric information, the state variables should be transformed in such a way as to obtain a relationship between one input function P(t) and one output function. The relationship between the state variables and the output function has the following form:
The method of state variables for the determination of thermokinetics was proposed by Brie et al. [239]. The method was applied in the following works [239, 243, 244].
128 CHAPTER 3
3.2.11.5. Method of transmittance decomposition
In this method [245], the dependence between the measured calorimetric signal and the generated heat effect, in the complex plane, is described by Eq. (2.11). Use of Eq. (2.41) leads to
or, after dividing (m < N), we obtain
where
R(s) is a polynomial of degree smaller than m (remainder of division). Using Eq. (3.127), we have
The expression after the use of Eq. (3.128), in the time domain corresponds to the differential equation
The expression after the use of (3.129), in the time domain corresponds to the convolution function
CLASSIFICATION OF CALORIMETERS 129
where is the inverse Laplace transform of Eq. (3.129). After using Eqs (3.130–3.132), we obtain the final form of the equation for the desired heat power:
In order to use the above equation to determine the unknown heat effect, it is necessary to determine first the nominator and denominator of the transmittance and next the expressions and On the
basis of we calculate the coefficients and differential equa
tion (3.131), and on the basis of This enables us to decrease the number of derivations of m and is very useful when the difference between the degree of the denominator and the degree of the nominator of the transmittance is small.
3.2.11.6. Inverse filter method
This method [244, 246] is based on the assumption that the time constants of the calorimeter as an inertial object have been determined previously. For example, when the calorimeter is treated as a object of second order, the relation between P(t) and T(t) can be expressed according to Eq. (2.13) in the form of the following differential equation:
Using Laplace transformation and replacing the coefficients and by the time constants and of the calorimeter: Eq. (3.134) becomes
The purpose of the inverse filter method is the application of a procedure which allows elimination of the influence of inertia units in the
130 CHAPTER 3
determination of the relation between T(s) and P(s), and thus that between T(t) and P(t). It consists in the introduction (by the numerical or analog method) of terms providing an inverse function to the terms For an individual corrector, we have
For two correctors, we have
For an ideal correction, this would lead to the case when the input function corresponds to the output function, as represented by the relationship
The practical performance of the inverse filter method is different in different systems [246–257], but advantage is always taken of electronic elements active under the form of an operational amplifier and impedance divider of the feedback, by which the required functionachieved.
is
Another way to achieve the differential correction is numeric correction [255–257]. Taking into account Eq. (3.136), it is intended to calculate numerically the functions corresponding to the terms each of these terms there corresponds a linear differential equation of first order of the form
To
Thus, for an inertial object of second order, the following equations can be noted:
131 CLASSIFICATION OF CALORIMETERS
When the time constants and and T(t) are known, it is possible to determine the and values consecutively, and thus P(t). The numerical differential correction method has also been applied to reproduce the thermokinetics in these calorimetric systems, in which time constant vary in time [258–264], such as the TAM 2977 titration microcalorimeter produced by Thermometric. These works extended the applications of the inverse filter method to linear systems with variable coefficients. In many cases [258–262], as in the multidomains method, as a basis of consideration the mathematical models used were particular forms of the general heat balance equation.
3.2.11.7. Evaluation of methods of determinationof total heat effects and thermokinetics
The methods discussed above discussion are based on particular forms of the general heat balance equation. Methods based on the simple body balance equation or its simplified form have been used in calorimetry for a very long time: the method of corrected temperature rise for more than 100 years, and the adiabatic method for about 100 years. There are also new methods (e.g. the modulating method) or those which have become very important (e.g. the conduction method) in the past 20–30 years.
Improved conditions in calorimetric experiments lead to the creation of more precise mathematical calorimeter models and methods used for the determination of heat effects.
From the methods in which the set of heat balance equations was used, the multidomains method (§ 3.2.3) and the finite elements method (§ 3.2.4) were elaborated. Numerical methods for the determination of thermokinetics in n-n calorimeters (§ 3.2.11.1 - § 3.2.11.6) were also developed.
In the multidomains method and in the numerical methods, in accordance with the detailed solution of Fourier’s heat conduction equation, it was assumed that the impulse response of the calorimeter is described by an infinite sum of exponential functions [Eq. (2.57)]:
132 CHAPTER 3
Thus, in these methods an ideal model for reconstruction of the thermokinetics should be a model of infinite order. In fact, it is necessary to limit the number of exponential terms (domains). Generally, this is due to the compromise between the available information and the possibility of applying it. It has been proved by the results of a multinational program [265] on the evaluation of the new methods of determination of thermokinetics, in 1978. The purpose was to compare different methods independently proposed to reconstruct thermokinetics from the experimental calorimetric data. The dynamic optimization, harmonic analysis, state variable and numerical correction methods were tested. To eliminate the uncertainties caused by the individual features of the various calorimeters in different laboratories, it was generally approved that the responses of all calorimeters should be distributed to all participants of the program. These responses concerned normalized series of heat pulses, generated by the Joule effect in a heater. The values of amplitudes, the time durations of the generated heat effects and the sampling period were fixed as follows. The sampling period was taken as 0.002–0.003 of the largest constant of the calorimeter, which corresponds to 1/300 of the half-period of cooling. The values of amplitudes were given in relative units, equal to 10, 100 and 1000. The amplitude equal to 10 was defined as corresponding to the heat power of the pulse of duration equal to 8 sampling periods, for which the maximal temperature increase was 10 times larger than the amplitude of the measurement noise (the change in baseline when the thermally inert object is placed in the calorimeter). Three types of measurements were made: 1, 3 or 7 pulses of various durations were generated one after another. For example, plots of the series of 7 pulses are given in Fig. 3.7, and the results of the data reconstruction by dynamic optimization and harmonic analysis in Fig. 3.8.
133 CLASSIFICATION OF CALORIMETERS
134 CHAPTER 3
The results of the investigations indicated that the examined methods reveal considerable progress in the reconstruction of thermokinetics. It was stated [265] that “it is clear that the objective is not complete reconstruction of thermokinetics (thermogenesis), but rather decrease of the influence of thermal lags in calorimetric data; thus, after reconstruction, the residual time constant which appears in the data is ~ 200 times smaller than the actual order time constant of the instrument used” and that “the range of application of the presented methods is varied. The optimisation method shows its advantage especially in the cases when the number of experimental data need not be bigger than 100-150. The harmonic analysis, state variable and inverse filtering are not influenced by such a limitation and may be freely applied for the reconstruction of effects requiring a great number of data points”.
It appeared that all methods are equally sensitive to noise in the data and that the amplitude of the heat effect under study, compared to that of noise in the data, is of particular importance for the quality of reconstruction.
Let us consider the same problem on using amplitude characteristics [266]. As given in Eq. (3.143), amplitude is described by the function
and for large values of can be approximated by Eq. (3.144):
As a criterion for choosing the optimal sampling period, it is assumed that
where denotes the noise-to-signal ratio, and q corresponds to the number of certain digits in the measurement of the calorimetric signal. In order to estimate the values of the sampling period h instead of the approximate values
CLASSIFICATION OF CALORIMETERS 135
are assumed in Eq. (3.144):
Raising both sides of Eq. (3.147) to the power 1/m results in
Thus, the values of the constants must be larger than the sampling period with respect to the stability of the numerical solution. In the particular case when the number of certain digits in the calorimetric mesurements is equal to the difference between the number of poles and the number of zeros of the transmitance (q = N – m), the formula for the optimal sampling period takes the form
A scheme for choosing the optimal signal-to-noise ratio has been the subject of many papers, e.g. [267–270]. In the multidomains method, this selecting scheme was included in the procedure of determining the particular form of the calorimeter model. Another manner of selecting is used when harmonic analysis method is applied. In this method, the
This procedure uses transmittance is obtained numerically, using the Fast Fourier Transform.
points, where n = 10, 11, 12 and N = 1024, 2048, 4096, respectively. The number of data used for calculations must cover the whole interval of time from “initial zero” to “final zero” of the temperature calorimetric response. The discrete measurement of temperature limits the upper bounds of frequency which can be applied for reconstruction of the thermokinetics. The value of this frequency, resulting from Shannon’s theorem is a function of the sampling period and can be expressed by the relation It is therefore impossible to use the complete spectrum of the frequency. There also exists a boundary frequency
136 CHAPTER 3
which is related to the measurement noise. The boundary frequency is the second limitation of the frequency spectrum, which can be applied in the reconstruction of the thermokinetics for a given calorimetric system, and
The high precision of calorimetric measurements today permits a less strict description of the calorimetric system itself. The comparison of reconstructions of the thermokinetics obtained with the multibody method and with other methods demonstrates the convergence of the results [67] when the calorimetric system is described by a linear differential equation with constant coefficients of the third to sixth order.
A review of the published papers leads to the conclusion that mathematical models which are particular forms of the general heat balance equation of second or higher order are frequently used in isoperibol and DSC calorimetry. When the mathematical model is known, the inverse filter method is used to determine the thermokinetics.
The course of the thermal power change can be determined by using different calorimeters. The choice of the heat effect determination method does not depend on the calorimeter type. In a calorimeter with a vacuum jacket, the thermokinetics can be determined successfully by means of the dynamic method. In calorimeters whose inertia is very small (conduction calorimeters), use of the flux method is not always suitable. Better results in the reconstruction of thermokinetics are obtained from the use of methods where it is assumed that the calorimeter is an inertial object of first or higher order.
3.3. Linearity and principle of superposition
In the review of methods of heat effect determination and thermokinetics, the linearity of the system has implicitly been assumed. Linearity [8, 271] can be expressed by the equations
CLASSIFICATION OF CALORIMETERS 137
where x and y express quantities to be measured and the function expresses the output signal. Equation (3.141) is the basis of the superposition principle, and Eq. (3.142) indicates proportionality for quantitative measurement.
Regardless of what method of heat effect determination is applied, it has to be known whether measurements were performed in a linear system.
It is essential to draw a distinction between linear and nonlinear responses of the system. To correct the response of the system the linearity has to be confirmed by the experimental facts. When we look for the correct answer, the best method is to analyze the response of each forcing input function in the system. To achieve this, it would be helpful to use the dynamic time-resolved characteristics for the typical input function, given earlier (§ 2.3).
The response of the calorimetric system is always a result of superposition of some forcing functions acting at the same time. The forcing function in the calorimeter proper is always the heat effect generated as a result of the studied process. However, the review of the methods has revealed that there can be forcing functions striving to compensate the generated heat effect of the process; a rectangular pulse or a series of rectangular pulses; periodic heating rate of the sample etc. Additionally, the forcing functions acting in the shield influence the calorimeter. For an isoperibol calorimeter, this is a forcing function, tending to achieve the stability of the temperature of the shield; for scanning calorimeters, it is a ramp function. Analysis of the output functions courses generated in the shield is quite simple to deal with and usually consists in considering the course of the system response, if there is a thermally inertial object inside the calorimeter proper.
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Chapter 4
Dynamic properties of calorimeters
4.1. Equations of dynamics
In our considerations relating to the analysis of the course of heat effects that occur in calorimeters, we have used particular solutions of the general heat balance equation (1.148):
It is frequently more convenient to apply this equation in the temperature dimension [8, 20]:
The set of differential equations (4.1) is called the general equation of dynamics, the assumptions for which are sufficient to allow the calorimeter to have different configurations.
The following notions have been introduced in Eq. (4.1): the overall coefficient of heat loss, the time constant of the domain, the interaction coefficient and the forcing function.
The overall coefficient of heat loss for each of the domains is defined as
140 CHAPTER 4
This coefficient characterizes the heat exchange between domain j and the surroundings, but also that between domain j and other domains.
The time constant of domain j is defined as the ratio of heat ca
pacity and the overall coefficient of heat loss of the domain:
The time constant of domain j is a measure of the thermal inertia
of this domain in the system of domains.The interaction coefficient is defined as the ratio of the heat loss
coefficient to the overall coefficient of heat loss
This is a measure of the heat interaction of domain i with the domain j relative to the interactions of the remaining domains and surroundings with domain j. The interaction coefficients essentially affect the thermal inertia of the calorimeter and allow us to establish the structure of the
coefficient i and
dynamic model of a given calorimeter. If the value of the interaction
thermal interaction between domainsis negligibly small, it may be assumed that there is no
j or, more exactly, that the thermal interaction between domains i and j is small enough to be ignored in comparison with the interactions between domains i and j and other domains and the surroundings.
Furthermore, the notion of the forcing function (taken from control theory) was introduced into these considerations. This function is defined as
or, making use of Eq. (1.149), we have
The function has the dimension of temperature and is proportional to the heat power evolved.
The coefficients are defined as
141 DYNAMIC PROPERTIES OF CALORIMETERS
where is a determinant whose value depends on the interaction coef
ficient is the determinant of the matrix obtained by crossing out
the j-th row and the j-th column of matrix D. The coefficients are dimensionless, chosen in such a way that an increment of the temperature in a stationary state is equal to an increment of the forcing
function Defined in this manner, the coefficients are especially useful in applying the principle of superposition to the system of domains.
The set of differential equations Eq. (4.1) can be written in matrix form as follows:
where is the diagonal matrix whose elements are the time constants
is the diagonal matrix whose elements are the coefficients A is
the matrix whose elements are and for is the state vector, and f is the forcing vector
Application of the Laplace transformation to Eq. (4.8) under zero initial conditions gives
where T(s) is the Laplace transform of the state vector T(t) and f(s) is the Laplace transform of the forcing vector f(t). The solution of Eq. (4.9) is
or
where
is the transfer matrix and its elements are the transmittances which have the form
142 CHAPTER 4
where is the determinant of the matrix is the
corresponding minor of the matrix and is the determinant of
the matrix These determinants, after development into a power series with respect to s, give polynomials of N-th and M-th degree (M < N), respectively:
Thus, the transmittance [Eq. (4.13)] can be written in the form
or, on developing the nominator and the denominator of the transmittance (4.16) into first-degree factors:
where is the static gain, is the root of the nomina
tor of the transmittance (the zero of the transmittance) and is the
root of the denominator of the transmittance (the pole of the transmittance).
The advantage of the use of the presented transmittance is the expression of both the input and output functions in temperature dimensions. It can be applied to analyze the courses of the heat effects in calorimeters of different constructions, with different locations of the heat sources in relation to the temperature sensors. When the N-domain method is used to describe the heat effects, determination of the trans
143 DYNAMIC PROPERTIES OF CALORIMETERS
mittance form makes it possible to verify the correctness of the mathematical model of the calorimeter used in the calculations. In such a case, it is sufficient to compare the values of the calculated and experimentally measured function T (t) as the response to the known heat effect generated in the calorimeter.
In many cases, the general equation of dynamics can be simplified to a few-domain system, as will be pointed out below, in order to analyze the courses of different heat effects in calorimeters.
4.2. Dynamic properties of two and three-domain calorimeters with cascading structure
4.2.1. Equations of dynamics.System of two domains in series
Let us distinguish a system of two domains in series, characterized by heat capacities and respectively. The heat transfer between these domains is described by the coefficient while that between the domains and the environment (surroundings) is described by the coefficient The set of heat balance equations of the system is as follows:
If we put
144 CHAPTER 4
Eqs (4.18) and (4.19) can be written in the form
Let us consider that the heat power is generated only in domain 1, and the temperature change of domain 2 is measured. The
domain 1 output function here is at the same time the input function for domain 2. Equations (4.22) and (4.23) then become
If we additionally assume that Eqs (4.24) and (4.25) can be written in the form
As results from Eqs. (4.26) and (4.27), the domain 1 output function, here is at the same time the input function for domain 2. Function
is the output function of the system. In the general case, the initial conditions for Eqs (4.26) and (4.27)
are
Application of the Laplace transformation to Eqs (4.26) and (4.27) gives the solution in the complex domain:
145 DYNAMIC PROPERTIES OF CALORIMETERS
Equations (4.29) and (4.30) can be rewritten as
Simple rearrangement of Eqs (4.31) and (4.32) with the aim, amongothers, of eliminating results in
If we put
Eq. (4.33) reduces to
The function P(s) expresses the effect of the input function F(s) on This may be represented by a block diagram (Fig. 4.1) in which
the first and second rectangles represent the dynamic properties of domains 1 and 2, respectively.
P(s)The function provides a basis for defining the function for various functions f(t).
The functions G(s) [(Eq. 4.35)] will define the course of T(t) at f(t) = 0, the initial conditions being as follows:
After simple rearrangement, Eq. (4.35) becomes:
146 CHAPTER 4
and after an inverse Laplace transformation this gives
If, at the initial moment of heat generation, there is a temperature difference between the domains (or domain) and the surroundings, both functions P(s) and G(s) must be determined if the function is to be defined.
Let us now define the courses of function in the cases when 1) a unit pulse function; 2) an input step function of amplitude b and time interval a; and 3) a periodic input function is generated in domain 1. This function f(t) is defined by rectangular pulses, each of them over the time period a, the time interval between two successive pulses being Z.
Let us suppose that a heat effect that is constant in time (an input pulse function) is producted in domain 1. In this case:
than the temperature in the sys-
This forcing function results in a rise in temperature until a new stationary heat transfer state is established in the system. This state is characterized by a temperature higher by tem at the moment t = 0, if the initial conditions are zero.
If we assume and with Eq. (4.40), after inverse Laplace transformation Eq. (4.34) becomes
If the constant heat effect occurs in domain 1 for a period of time af(t)and amplitude (unit step function of amplitude the function
assumes the form
147 DYNAMIC PROPERTIES OF CALORIMETERS
The changes in temperature in time, are then expressed by
When n rectangular pulses occur in domain 1, each pulse lasting for a period of time a, the interval between two successive pulses being Z, the input function f(t) may be written in the form
where
For f(t) expressed by Eq. (4.44), the function F(s) is
and Eq. (4.34) takes the form
The function corresponding to P(s) in Eq. (4.47) was determined by an inverse Laplace transformation. This function is
148 CHAPTER 4
4.2.2. Equations of dynamics.Three domains in series
In numerous cases, the determination of the output function with a given accuracy requires that the two-domain cascading system should be enlarged with an “additional” first-order inertial object (domain).
A cascading system composed of three domains in series can be described by the following set of equations of dynamics:
As before, Eqs (4.49)-(4.51) are assumed to be general differential equations of dynamics describing the courses of the temperature changes in time in the domains considered. In Eq. (4.49),f(t) is the input function. It may be assigned an arbitrary course. Function is the domain 1 output function, which at the same time constitutes the input function for domain 2. The output function of domain 2 constitutes the input function of domain 3, whose output function is
For the solution of the above system of differential equations, the Laplace transform method was used, yielding
149 DYNAMIC PROPERTIES OF CALORIMETERS
where
The relation between the functions F(s) and P(s) may be represented as in the diagram in Fig. 4.2.
When f(t) = 0, and
a solution of Eqs (4.49)–(4.51) in relation to is given by the equation
where
150 CHAPTER 4
For a forcing function f(t) described by Eq. (4.40) and initial conditions described by Eq. (4.55), we obtain the changes in temperature
For a forcing function f(t) described by Eq. (4.43) and initial conditions described by Eq. (4.55), we obtain
For a forcing function described by Eq. (4.45) and initial conditions described by Eq. (4.55), the temperature changes are expressed by the equation
151 DYNAMIC PROPERTIES OF CALORIMETERS
Forms of the particular equation of dynamics developed for the systems of two domains and three domains in series are presented only with selected input functions. This selection was made by taking as criterion their application in the analysis of the courses of the heat effects. The particular forms of the equations of dynamics for the other input functions can be obtained in a similar way.
4.2.3. Applications of equations of dynamicsof cascading system
The equations of dynamics of cascading systems have been utilized in calorimetry for many years [25–35]. For example, these equations can be applied as follows:
1) A system of two domains in series. The input function f(t) of domain 1 is at the same time the output function of domain 2. The output function of domain 2 is measured (Fig. 4.1). a) The forcing input function f(t) is the input step function gener
ated in the calorimetric vessel (in domain 1). Domain 2 consists of the temperature sensor in isolation. The amplitude and generation time of the rectangular pulse and the time constants of domains 1 and 2 are known. For the calculations, one can apply Eq. (4.43). These calculations allow determination of the output function of the system, which is of special importance in measurements of heat effects of short duration.
b) The input function is a ramp function. Domain 1 is a thermostat, while domain 2 consists of the calorimetric vessel with sample. Let us assume that the calorimetric vessel contains samples with the same volume, but with differing heat capaci-
ties The time constants of domain 2 there
fore change. This causes differences in the values of the output function. They can be calculated after determination of the particular form of Eq. (4.43), values characterizing the ramp
function and the values of
152 CHAPTER 4
2) The system consists of three domains in series (Fig. 4.2). The input function f(t) of domain 1 is at the same time output function of domain 2, which in turn is the input function of domain 3. The output function of domain 3 is measured. The input function f(t) is the input step function. Domain 1 consists of the calorimetric vessel filled with the substance studied, domain 2 is the inner shield of the calorimeter, and domain 3 is in isolation the temperature sensor located on the outer surface of the inner calorimetric shield. The amplitude and generation time of the rectangular pulse and the time constants of domains 1–3 are known. To calculate the output function, we can apply Eq. (4.61). The calculations allow us to determine the influence of the inertia of the inner shield and the temperature sensor on the recording of the heat effect generated in the calorimetric vessel.
In the discussed examples, the responses of the system to only one forcing function were considered. In many cases, the course of the output function of the system has to be defined as the result of the operation of several forcing functions. This can be demonstrated via the following examples.
3 a) A system composed of a thermostat (domain 1) and a calorimeter (domain 2). In the thermostat, the ramp function f(t) is produced, whereas the calorimeter gives the periodic input function
3 b) A system comprising the calorimetric vessel with the sample (domain 1), the internal shield (domain 2) and the temperature sensor (domain 3). In the calorimetric vessel, heat effect is generated, while the compensating heat effect expressed by is produced in the internal shield of the calorimeter.
153 DYNAMIC PROPERTIES OF CALORIMETERS
This leads to the conclusion that, for the two-domain system when input functions f(t) and (Fig. 4.3) are produced at the same time, the output function P(s) will be expressed by Eq. (4.36) supplemented by the term.
For the three-domain system, when forcing functions and are produced at the same time, the output function is expressed by Eq. (4.54) supplemented by the term
This means that in the two cases considered the solution of the equations of dynamics will be the sum
This procedure results from the application of the superposition rule to linear systems.
Equations of dynamics are also useful in analysis of the courses of the heat effects in differential and twin calorimeters.
Let us consider a system composed of two calorimeters (I and II), characterized by the dynamic properties of inertial objects of the first order, placed in a common shield. The sample is situated in one of them, and the reference substance in the other. The forcing input function is the ramp function generated in the thermostat. Let us assume that this function is at the same time the input function of both calorimeters. The influence of the forcing function on a differential calorimeter is shown
154 CHAPTER 4
schematically in Fig. 4.5, where and are the output functions of calorimeters I and II, respectively and T(t) is the output function of the differential calorimeter.
For this system, we can determine the changes in the course of the function T(t) due to the changes in the time constants of both calorimeters and therefore the changes caused by the different heat capacities and heat loss coefficients. For the observation of such changes, in many cases it is necessary to consider systems having more domains, both in series and with a concentric configuration. As often as not, with a high number of domains present in the system, even the identification of these domains may pose considerable difficulties and the direct determination of the time constants may be impracticable. The transmittance of the system can then be determined or the system can be approached in terms of a single system with vicarious characteristics. The application of these characteristics does not mean, however, that the accuracy of establishing the output function is somewhat sacrificed.
4.3. Dynamic properties of calorimeterswith concentric configuration
Let us discuss the two-domain model with a concentric configuration, indicating the dependences of the dynamic properties on the mutual locations of the heat sources and temperature sensors (§ 4.3.1 and § 4.3.2); explaining why the calibration of the calorimeter by means of
155 DYNAMIC PROPERTIES OF CALORIMETERS
the dynamic method in some cases is accompanied by apparent changes in heat capacity (§ 4.3.3); and proving the need for use of the equivalent coefficient (§ 4.3.4) instead of the heat capacity value when the method of corrected temperature rise is applied in calculations of heat effects.
4.3.1. Dependence of dynamic properties oftwo-domain calorimeter with concentricconfiguration on location of heat sourcesand temperature sensors
Let us normalize in the dimension of temperature the isoperibol n-n calorimeter characterized by a system of two concentric domains shown in Fig. 4.5 [21, 45].
This is characterized by Eq. (4.18):
and the equation
156 CHAPTER 4
In this case, the overall heat loss coefficients and for the domains 1 and 2 are, respectively
The time constants and of the distinguished domains 1 and 2
are
It may be noted that the thermal inertia of domain 1 is influenced by the heat transfer between domains 1 and 2 and with the shield, whereas the thermal inertia of body 2 is influenced by the heat transfer between domains 1 and 2. The interaction coefficients are, respectively
On putting we can write
In order to determine coefficients and the determinants are calculated, which are, respectively
From Eqs (4.7) and (4.72), we have
With regard to Eqs (4.68)–(4.73), Eqs (4.18) and (4.66) can be written in the form
The differential equations (4.74) and (4.75) are called the equations of dynamics of a calorimeter treated as a system of two domains with a
157 DYNAMIC PROPERTIES OF CALORIMETERS
concentric configuration [44, 45]. It may be noted that the left-hand sides of these equations are similar to the equation of dynamics for a
one-domain model; the time constants and of the particular do
mains thus characterize the first-order inertial properties of each, considered independently of one another.
However, because of the different forms of the right-hand sides of Eqs (4.74) and (4.75) referring to the heat balance equation of a simple body, a new quality is obtained: the mutual interaction expressed by
and This expression follows from the block diagram (Fig. 4.7), which may be assigned to the equations of dynamics.
To obtain the block diagram shown in Fig. 4.6, the Laplace transformation should be applied. Equations (4.74) and (4.75) then become
where and are the differences between the initial temperatures of domains 1 and 2, respectively, and that of the temperature of the shield at time = 0; and are the Laplace transforms of temperatures and respectively; and are the Laplace transforms of the forcing functions and
When
Eqs (4.76) and (4.77) become
158
For the transform Eq. (4.79), we have
CHAPTER 4
from Eq. (4.80) and the transform from
where
are the transmittances of domains 1 and 2, respectively. These functions characterize the dynamic properties of the domains that are distinguished in the examined calorimeter. It is seen from the block diagram (Fig. 4.7) that the dynamic properties of the system depend on the dynamic properties of the domains and on the interaction between them. In this connection, let us consider the dependence of the dynamic properties of the calorimeter described by Eqs (4.74) and (4.75) on the locations of the heat sources and temperature sensors in domains 1 and 2. The following cases can be distinguished:
1. A heat power characterized by forcing function is generated, and the changes in temperature in time are measured.
2. A heat power is measured and the changes is temperature in time are measured.
3. A heat power characterized by function is generated, and the changes in temperature in time are measured.
4. A heat power characterized by function is generated, and the changes in temperature in time are measured.
For these cases, the calorimeter transmittances as functions of transmittances and [Eq. (4.83)] of the distinguished domains and interaction coefficient k are given in Table 4.1; the relationships between the input function F(s) and output function T(s) are given in Table 4.2. Taking into account the form of transmittances given by Eq. (4.83) for the distinguished domains 1 and 2, the transmittances of the calorimetric system given in Table 4.1 can be written in the form presented in Table 4.3.
159 DYNAMIC PROPERTIES OF CALORIMETERS
If we introduce the time constants and of the calorimeter, defined as
which satisfy the equation
the transmittances given in Table 4.3 can be written in the form given in Table 4.4. The time constants and determine the inertia of the calorimeter and depend on the time constants of the distinguished domains
and the values of coefficients k. These are the roots of Eq. (4.85).
160 CHAPTER 4
It can be shown from the transmittances collected in Table 4.4 that transmittance depends only on the time constants and of the calorimeter; transmittance depends on the constants and but also on the interaction coefficient k, which takes into account the temperature differences between domain 2 and domain 1 in steady-state heat transfer; transmittances and depend on the time constants of the distinguished domains as well as on the time constants of the calorimeter.
As a consequence of the different forms of transmittance, there are different courses of the output function for the same forcing function.
161 DYNAMIC PROPERTIES OF CALORIMETERS
We can demonstrate this on examples of 1) the pulse response of the calorimeter; and 2) the temperature changes of the calorimeter as a thermally inert object.
When the inverse Laplace transformation is applied to the transmittances given in Table 4.4, the pulse responses of the calorimetric system given in Table 4.5 are obtained; their plots are shown in Fig. 4.8. Figures 4.8a and 4.8d reveal that, when the heat source and the temperature sensor are situated in the same domain, the shape of the pulse response of the calorimetric system is reminiscent of the response of the calorimetric system of first order. From the shapes of the curves given in Figs 4.8d and 4.8c, it is clear that, when the heat source and temperature sensor are situated in different domains, the pulse response of the calorimetric system at the initial time moment is equal to zero, next increases to a certain maximum value and respectively), and then decreases to zero.
Thus, the pulse responses depend on the mutual locations of the heat source and temperature sensor, and on the parameters of the calorimetric system, and are non-negative functions.
Let us also consider the changes in temperature in time of the calorimeter when there are no heat sources; the distinguished domains are thermally inert objects, which is equivalent to the conditions
162 CHAPTER 4
The temperature changes of the calorimeter are caused only by the initial differences in temperature of the bodies with respect to the environment temperature, which can be written as
When the conditions given by Eq. (4.74) are taken into account, Eqs (4.79) and (4.80) can be written in the form
The determination of and from these equations leads to
Equations (4.90) and (4.91) represent the Laplace transforms of temperatures and when at least one of the temperatures of the distinguished domains at the initial moment t = 0 is not equal to the environment temperature. Application of the inverse Laplace transformation to Eqs. (4.90) and (4.91) gives
163 DYNAMIC PROPERTIES OF CALORIMETERS
and calorimeterwhere the time constants of the are given by Eq. (4.84). When
the plots of the functions (4.92) and (4.93) are shown in Figs. 4.9a and 4.9b.
From the plot in Fig. 4.9a, it is seen that domain 1, at a temperature higher by than the temperature of the environment, undergoes cooling, the course of the temperature changes in time being reminiscent in shape of a one-exponential course. Domain 2, whose temperature at the initial moment is equal to the environment temperature, first undergoes heating to temperature by a certain time and then cools to the environment temperature. At time moment temperatures and are equal. When the initial temperature of domain 1 is smaller by than the environment temperature (Fig. 4.9b), the domain is heated to the environment temperature; the temperature of domain 2 cools to
by time next returning to the environment temperature. The extremum of temperature of domain 2 is accepted as the time moment at which equalization of the temperatures of the two domains takes place.
When
the plots of functions (4.92) and (4.93) are shown in Figs 4.9c and 4.9d. When the initial temperature of domain 2 is higher by than the environment temperature (Fig. 4.9c), domain 2 cools to the environment temperature, and the course of the temperature changes in time are reminiscent in shape of a one-exponential curve.
164 CHAPTER 4
Domain 1 with an initial temperature equal to the environment temperature heats up to temperature not reaching the temperature of domain 2, and then cools to the environment temperature. The temperature of domain 1 is always lower than the temperature of domain 2. If the initial temperature of domain 2 is lower than the environment temperature (Fig. 4.9d), domain 2 heats up to the environment temperature. The temperature of domain 1, which at first is equal to the environment temperature, decreases to a certain temperature and next
165 DYNAMIC PROPERTIES OF CALORIMETERS
increases to the environment temperature. The extremal value of the temperature of domain 1 depends on the value of interaction coefficient k. As the value of interaction coefficient comes nearer to unity, the neight of the peak is smaller.
When the initial temperatures of the two domains are equal and different from the environment temperature:
plots of the functions (4.92) and (4.93) are shown in Figs 4.9e and 4.9f. From Fig. 4.9e, it can be seen that the temperatures of domain 1 and domain 2 decrease in time, but the temperature of domain 1 decreases faster than that of domain 2. When the initial temperatures are smaller by than the environment temperature (Fig. 4.9f), both domains heat up to the environment temperature, but domain 1 does so faster than domain 2. The course of the temperature changes in domain 1 is reminiscent in shape of a one-exponential course.
The examples given above clearly show that the output function is related to the mutual locations of the heat sources and temperature sensor.
The presented equations were defined on the assumption that the form of the input function and the initial conditions are known. To reconstruct the input function on the basis of the form of the output function, it is necessary to know the particular forms of the dynamics equation of the two-domain calorimeter with a concentric configuration.
4.3.2. Dependence between temperature and heat effect as a function of location of heat source and temperature sensor
Let us define particular forms of the equation of dynamics [Eqs (4.74) and (4.75)] expressing the dependence between temperature and heat effect as a function of the locations of the heat source and the temperature sensor [8, 30, 40], As a basis of consideration, we will take the equation of dynamics [Eqs (4.74) and (4.75)]. When heat power is generated only in domain 1, Eqs (4.74) and (4.76) take the form
166 CHAPTER 4
When heat power is generated only in domain 2, Eqs (4.74) and (4.75) take the form
Taking into account Eqs (4.97)–(4.100), let us consider the following cases:
1. The temperature is dependent on the function In this case, the elimination of temperature from Eqs (4.97) and (4.98) furnishes
Division of both sides of this equation by k and taking into account Eq. (4.84) gives
With the assumption that
Eq. (4.102) can be written in the form
167 DYNAMIC PROPERTIES OF CALORIMETERS
Equation (4.105) connects the changes in temperature of domain 1 with the heat effect generated in the same domain. It results from this equation that the changes in temperature of this domain are determined by the relation of the heat power and its derivative. This equation cannot be directly applied to determine an unknown heat power, because it is necessary to know the derivative of the value we are looking for.
2. The temperature depends on the function In this case, by eliminating the temperature from Eqs. (4.97) and (4.98) and following the above routine, we can establish the relationship between the temperature changes of domain 2 and the heat effect generated in domain 1, which has the form
Analogously, by taking into account Eqs (4.99) and (4.100), the dependences between the heat effect generated in domain 2 and the temperature changes can be established for the following cases.
3. The temperature depends on the function In this case, the equation of dynamics has the form
4. The temperature depends on the function In this case, the equation of dynamics has the form
168 CHAPTER 4
Equation (4.107) has a form similar to that of Eq. (4.104). Particular forms of the equation of dynamics show that, for the two-domain calorimeter, the temperature sensor should be situated in another domain than the heat source. In another case, it is possible to carry out a measurement in such a way that the temperature sensor is situated in each domain. Zielenkiewicz and Tabaka [278–281] showed that correct results can be obtained by applying multipoint temperature measurement, corresponding to the number of distinguished domains.
Considerations as to the mutual locations of the heat sources and temperature sensors can form the basis of the explanation of several observed facts, such as the apparent change in heat capacity of the calorimeter with time.
4.3.3. Apparent heat capacity
During the calibration of the Calvet microcalorimeter [10] and the KRM calorimeter [282], it was found that the calculated value treated as heat capacity changes in time.
Changes in the heat capacity of the calorimeter were noted, when was calculated by using the heat balance equation of a simple body, in which it is assumed that the heat capacity C depends neither on time t nor on the geometrical distribution of the heat power source and the location of the temperature sensor; it is equal to the sum of the heat capacities of all the parts i of the calorimeter:
On the assumption that the heat capacity C of the system corresponds to Eq. (3.59) after integration can be written in the form
If we assume that the two-domain model with a concentric configuration is the proper mathematical model for the examined calorimeters
169 DYNAMIC PROPERTIES OF CALORIMETERS
[293], then, in a comparison of Eq. (4.109) with integrating Eqs (4.104)– (4.107), the following cases can be considered:
1. Integration of both sides of Eq. (4.104) in the time interval leads to
Simple rearrangement of Eq. (4.110) gives
A comparison of Eqs (4.109) and (4.111) results in
2. Integration of both sides of Eq. (4.106) in the time interval yields
or
Comparison of Eqs (4.109) and (4.114) gives
3. On integration of both sides of Eq. (4.105) in the time interval we have
170 CHAPTER 4
and
By comparison of Eqs (4.109) and (4.117), we find
4. Integration of both sides of Eq. (4.108) in the time interval leads to
or
On comparing Eqs (4.109) and (4.120), we have
It follows from the above equations that the effective heat capacity depends on various parameters: the heat capacities of the distin
guished domains, the heat transfer coefficients between these domains and the environment, the character of the changes in the heat effects in time and their derivatives with respect to time, the changes in particular temperatures in time and their time derivatives, and also the time interval in which the heat effects are evaluated. The effective heat capacity is time-invariant in only a few cases, e.g. when and i = 1,2 for a system of two interacting domains.
171 DYNAMIC PROPERTIES OF CALORIMETERS
4.3.4. Energy equivalent of calorimetric system
When the corrected temperature rise method was applied for the calibration of the calorimetric bomb, it was established [22–24, 284] that the calculated heat capacity of the device was not equal to the sum of the heat capacities of the calorimeter parts.
King and Grover [22] described the calorimetric bomb in terms of a two-domain model with a concentric configuration. As a result, in the method of corrected rise the heat capacity C was replaced by a corrected term, called the energy equivalent of the calorimeter:
where and are the heat capacities of domains 1 and 2, is the heat loss coefficient between domains 1 and 2, and is equal to the smaller of the cooling constants of the calorimeter.
Let us analyze [283, 285] the influence of the mutual locations of the heat sources and temperature sensors on the value of the energy equivalent for a calorimeter treated as a system of two domains. As stated previously, in the corrected temperature rise method three periods are distinguished during the experiment: and
In the initial and final periods, the calorimeter is a thermally inert object; in the main period, the heat effect is generated in the calorimeter.
As shown in §4.3.2, in the main period, the calorimeter can be described by one of Eqs (4.104)–(4.107), depending on the mutual locations of the heat sources and temperature sensors, while integration of these equations in the time interval similarly as for Eqs (4.110), (4.113), (4.116) and (4.119), leads to
172 CHAPTER 4
where
and and are the values of the derivatives
of the temperatures and with respect to time t at moments and
respectively. Since the moments and belong in the periods when heat power is not generated:
From Eqs (4.4) and (4.5), we have
On taking into account Eqs (4.130)–(4.132), after simple transformation and integration, we find
173 DYNAMIC PROPERTIES OF CALORIMETERS
If the temperature changes in the initial and final periods result from the cooling or heating of the calorimeter as a thermally passive object, the right-hand sides of Eqs (4.104)–(4.107) are equal to zero. The solutions of these equations are
where and are constants. When the second term of Eqs (4.136) and (4.137) decreases quickly and we can write
Equations (4.138) yield the following equations:
For and we have
When Eqs (4.123)–(4.134) and (4.140) are taken into account, Eqs (4.123)–(4.126) can be written in the form
174 CHAPTER 4
Putting
Eqs (4.141)–(4.144) can finally be written in the form
Let us define the energy equivalent R of the calorimetric system as the ratio of the generated heat amount Q to the corrected temperature
as a function of the mutual location of the heat source rise
and the temperature sensor. Then, taking into account Eq. (4.146), we find that
when the temperature of domain 1 is measured and the heat effect is generated in domain 1, the energy equivalent is equal to
when the temperature of domain 1 is measured and the heat effect is generated in domain 2, the energy equivalent is equal to
175 DYNAMIC PROPERTIES OF CALORIMETERS
when the temperature of domain 2 is measured and the heat effect is generated in domain 1, the energy equivalent is equal to
when the temperature of domain 2 is measured and the heat effect is generated in domain 2, the energy equivalent is equal to
It can be seen from Eqs (4.151)–(4.153) that the energy equivalent is the same, equal to the product of the largest time constant of the calorimetric system and the heat loss coefficient In Eq. (4.154), the energy equivalent is smaller than in the first three cases.
In calorimetric measurements, the location of the temperature sensor is generally fixed, while those of the calibrating heat source and the heat source of the examined process can differ. If the temperature of the other domains is measured, it is without difference in that one in which only the calibrating effect and the heat effect process are situated because there is equivalence of the heat sources and On the other hand, when the temperature is measured in the inner domain, the calibrations and examined heat effects must occur in the same domain because
The larger root of Eq. (4.84), which corresponds to the time constant of the calorimetric system, is equal to
Taking into account the relationships (4.68)–(4.71), we obtain
From Eq. (3.96), we have
It results from Eq. (4.157) and Eqs (4.151)–(4.154) that the energy equivalent has the dimension of heat capacity, but is not the sum of the heat capacities and of the distinguished domains. When the calo
176 CHAPTER 4
rimeter is thermally insulated which corresponds to adiabatic conditions, the value of the equivalent is equal to the sum of the heat
curs capacities of the distinguished domains. When ideal heat exchange oc-
with the distinguished domain both domains can be treated as simple domains and the energy equivalent is equal to the sum of the heat capacities.
Final Remarks
The present theory of calorimetry is a result of the authors’ own work. Its essential feature is the simultaneous application of the relationship and notions specific to heat transfer theory and control theory. The present theory has been used to develop a classification of calorimeters, to discuss selected methods of determining thermal effects and thermokinetics, and to describe the processes proceeding in calorimeters of various types. Calorimeters have been assumed to constitute linear systems. This assumption allowed the principle of superposition to be used to analyze several constraints acting simultaneously in and on the calorimeter.
The present theory of calorimetry is concerned mostly with the instruments whose principle of operation is assumed to involve the transfer of heat in the system. This is true for most of the existing calorimeters, whether those with a constant or those with a variable temperature of the shield. It includes calorimeters in which the flow of heat between the calorimeter proper and its surroundings is quite intense, and also those in which this flow of heat is very low. On the other hand, the present theory is concerned to only a minor degree with calorimeters whose principle of operation is based on the assumption that there is no heat transfer (adiabatic calorimeters) or that, by definition, the heat transfer process is stationary (the generated heat effect is compensated).
The considerations presented are based on the general heat balance equation of N-domains. A majority of the methods used to determine heat effects have been shown to rely on the simplest, particular form of this equation. This makes the calculations very convenient, but implies a number of simplifying assumptions. These give rise to several limitations, which have been duly pointed out. Of the methods described and
178 FINAL REMARKS
used to determine heat effects and thermokinetics, the method of N-domains has been given special attention. This method may be particularly useful when the calorimeter constructed is used to study transformations of short or long duration, and with constant or varying volumes and heat capacities of the samples examined. This method is advantageous in that it allows the identification of calorimeter parameters by specifying the “exchangeable” part of the calorimeter as contrasted with the “nonexchangeable” part; this makes the changes that have to be introduced into the algorithm of calculations when the measuring conditions are modified rather minor ones. The method is of particular value when the construction of the calorimeter permits the instrument to be used for various applications. This is true of the numerous calorimeters produced by the major manufacturers.
The references reviewed illustrate that most investigators have been looking for ways to enhance the accuracy of measurements by making use of the conclusions deduced from the analysis of the course of heat effects proceeding in the calorimeter. This is of particular concern as regards calorimetric determinations carried out with the recent DSC techniques. In such investigations, the application of the procedures described in the book and based on the general equation of dynamics and on the method of analogy of the thermal and dynamic properties of the objects, can be of essential assistance.
The numerous illustrative applications of the theory to various problems in the analysis of heat transfer processes occurring in calorimeters should encourage investigators to undertake work to improve the theory of calorimetry still further and to develop more practical applications.
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