MRV Methodology Title: “Replacement of boiler by heat pump in …gec.jp/gec/jp/Activities/fs_newmex/2012/preliminary... · 2013-02-20 · the same climate zone. In accordance with

[Attachment to GEC’s Demonstration/Feasibility Study Report JFY2012]

I-7

MRV Methodology Title: “Replacement of boiler by heat pump in country Mongolia” (Draft Ver. 3.0)

1. Title of the Methodology

“Replacement of boiler by heat pump in country Mongolia”

2. Summary of the Methodology

This methodology can be applied to projects that intend to reduce GHG emission from

reference scenario by replacing existing heating boilers with heat pump system in Mongolia.

3. Eligibility Criteria

This methodology is applicable to projects that fully satisfy the following cases.

Check

Case 1 The existing heating boilers that supply hot water for heating shall be

replaced by heat pumps that supply hot water for heating.

Case 2 All the fuel of the existing boiler(s) before the project is fossil fuel.

Case 3 The existing secondary heating system shall continue to be used after the

project without any modification.

Case 4 The project shall pass the below “check list”.

Case 5 The project shall satisfy the following formula.

Average annual COP of heat pump > efficiency of boiler / emission factor of

fuel of boiler / 3.6 * emission factor of grid

In order to satisfy the above formula, efficiency of boiler, emission factor of

fuel of boiler, and emission factor of grid shall be known.

Case 6 Rooms are heated.

Case 7 In case that the project applies geothermal heat pumps, a know-how support

on designing and construction shall be provided by developed countries.

Note: This methodology is drafted as the result of the GEC’s JCM Demonstration/Feasibility Study in JFY2012. Therefore, this draft methodology is not officially approved by any governments involved in JCM, and is subject to change in the future.


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Check list for determining the reference scenario

No. Check list Conclusion that can be made from checking

1

Is it possible to improve the efficiency of the existing boilers?(1) Yes. (2) No, because there is no regulation that forces to improve the

efficiency of the existing boilers and its project IRR for 15years will be lower than loan interest.

(3) Others.

If (2) is satisfied, improving the efficiency of the existing boilers is not the reference scenario. Go to check No.2.

2

Is it possible to switch from the existing boilers to other heating service?(1) Yes. (2) No, because there is no regulation that forces to switch from the

existing boilers to other heating service and there is no heating service available.

(3) No, because there is no regulation that forces switch from the existing boilers to other heating service and its project IRR for 15years will be lower than loan interest.

(4) Others.

If (2) or (3) are satisfied, switching from the existing boilers to other heating service is not the reference scenario. Go to check No.3.

3

Is it possible to replace the existing boilers with electric heaters?(1) Yes. (2) No, because there is no regulation that forces to replace the existing

boilers with electric heaters and replacing will result in increase of energy cost.

(3) No, because there is no regulation that forces replace the existing boilers with electric heaters and its project IRR for 15years will be lower than loan interest.

(4) No, because power source for the electric heater can’t be secured. (5) Others.

If (2) or (3) or (4) are satisfied, replacing the existing boilers with electric heaters is not the reference scenario. Go to check No.4.

4

Is it possible to switch from the existing boilers to other boilers which fuel has lower emission factor? (1) Yes. (2) No, because there is no regulation that forces to switch from the

existing boilers to other boilers which fuel has lower emission factor and switching will result in increase of energy cost.

(3) No, because there is no regulation that forces to switch from the existing boilers to other boilers which fuel has lower emission factor and its project IRR for 15years will be lower than loan interest.

(4) No, because there is no regulation that forces to switch from the existing boilers to other boilers which fuel has lower emission factor and there is no other fuel available.

(5) Others.

If (2) or (3) or (4) are satisfied, switching from the existing boilers to other boilers which fuel has lower emission factor is not the reference scenario. Go to check No.5.

5

Is it possible to replace the existing boilers with biomass boilers or solar powered heaters? (1) Yes. (2) No, because there is no regulation that forces to replace the existing

boilers with biomass boilers or solar powered heaters and replacing will result in increase of energy cost.

(3) No, because there is no regulation that forces to replace the existing boilers with biomass boilers or solar powered heaters and its project IRR for 15years will be lower than loan interest.

(4) No, because there is no regulation that forces to replace the existing boilers with biomass boilers or solar powered heaters and there is no biomass available.

(5) No, because there is not enough solar energy. (6) Others.

If (2) or (3) or (4) or (5) are satisfied, replacing the existing boilers with biomass boilers or solar powered heaters is not the reference scenario. Go to check No.6.


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No. Check list Conclusion that can be made from checking

6

Is it possible to replace the existing boilers with heat pumps?(1) Yes. (2) No, because there is no regulation that forces to replace the existing

boilers with heat pumps and replacing will result in increase of energy cost.

(3) No, because there is no regulation that forces to replace the existing boilers with heat pumps and its project IRR for 15years will be lower than loan interest.

(4) Others.

If (2) or (3) are satisfied, replacing the existing boilers with heat pumps is not the reference scenario, this methodology is applicable, and it is specified that the reference scenario is continuation of the existing boilers.

Remark: If existing regulation does not work and/or is not conformed to at all, and if project participants can

demonstrate such situation, project participants can construe that there is no such regulation.

4. Selection of Calculation Method

To calculate the reference emission, the project developer must refer to the calculation method

best-suited for his/her project using the flow chart below.

Does the project has at least one of the below characteristics?

It includes installation of air source heat pumps.

It includes installation of water source heat pumps.

Heat pump system includes electric heaters.

Heat pump system includes solar powered heaters.

Yes

No

Yes

No

Calculation

method 2

(simple method)

Calculation

method 1

(precise method)

Are there any “reference projects”

that belong to the same climate zone

as the project?


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5. Necessary Data for Calculation

The data that requires presetting in the planning stage of the project or monitoring after the

start of the project is determined below based on the calculation method selected in section 4.

If the data shown below is imported, a calculation tool is provided in this methodology that

will allow you to measure emission reductions.

5.1 Calculation method 1: …

Data necessary at ex-ante calculation at the stage of registration Item Description of data Symbol Value Unit

Data indispensable to this project

Efficiency of boilers in the reference scenario EF － Emission factor of fuel for boilers in the reference scenario

FEF tCO2/GJ

Data necessary when this project becomes a reference project to other projects

Standard climate data (outdoor temperature) SOTi degree C Heating load of the building under the standard climate data

SQ GJ

Average COP of heat pumps under the standard climate data

SCOP －

Data necessary to be monitored after implementation of the project Item Description of data Symbol Value Unit


Calorie of hot water supplied by heat pumps Q GJ Watt hour consumed by heat pumps (including watt hour consumed by pump for anti-freezing liquid)

W MWh

Emission factor of grid GEF tCO2/MWhData necessary when this project becomes a reference project to other projects

Climate data (outdoor temperature) OTi degree C Conservativeness factor C －

5.2 Calculation method 2:…


Data that should be received from this project

Efficiency of boilers in the reference scenario

EF －

Emission factor of fuel for boilers in the reference scenario

FEF tCO2/GJ

Standard climate data (outdoor temperature) SOTi degree C Heating load of the building under the standard climate data

SQ GJ

Average COP of heat pump under the standard climate data

SCOP －

Data necessary to be monitored after implementation of the project Item Description of data Symbol Value Unit


Emission factor of grid GEF tCO2/MWhClimate data (outdoor temperature) OTi ℃

Data that should be received from the reference project

Conservativeness factor C －


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5.3 Common to both calculation method 1 and 2



Lower heating value of fuel of the existing boilers

HV GJ/ton or

GJ/Nm3

Data necessary to be monitored after implementation of the project (In case of coal) Item Description of data Symbol Value Unit


Fuel consumption of the existing boilers FQ ton or

Nm3

Data necessary to be monitored after implementation of the project (In case of all types of fuel) Item Description of data Symbol Value Unit


Calorie of hot water supplied by the existing boilers

BQ GJ

6. Terms and Definitions Term Definition

Climate data (outdoor temperature)

Outdoor temperature that is monitored every hour on the hour or at fixed time every day by meteorological agency or its alternative public organization.

Standard climate data (outdoor temperature)

Outdoor temperature that is averaged every hour on the hour or at fixed time every day among certain years by meteorological agency or its alternative public organization.

Heating load of a building Characteristics of heating load of a building that are calculated for certain period based on the building’s insulation characteristics, indoor preset temperature, and operating hour of heating. The unit should be GJ.

Conservativeness factor The value equals to emission reduction applying calculation method 1 (based on calorie meter and watt hour meter) divided by emission reduction applying calculation method 2 (based on degree day) in the reference project. If this value is calculated as more than 1, then this value should be 1.

Degree day Annually integrated product of time and difference between indoor temperature and outdoor temperature.

Standard degree day Degree day calculated using standard climate data. COP Efficiency of heat pump. Energy output divided by energy input. For more

specific, calorie of supplied hot water divided by watt hour consumed. Climate zone Zone in which climate is generally regarded as same in the host country. Reference project A project that can provide conservativeness factors to other projects located in

the same climate zone. In accordance with the calculation method 1, it should have a calorie meter and a watt hour meter.

Pump for anti-freezing liquid A circulation pump for anti-freezing liquid located at the heat source side of a heat pump.

secondary heating system Facilities such as hot water circulation pump, hot water piping, and radiators located at the heat dissipation side of a heat pump.

Positive list A list that includes projects eligible for BOCM. Calorie meter Monitoring equipment that consists of a flow meter, a pair of thermo meters, a

computing unit, and connecting wires, which can calculate integrated calorie of supplied heating medium and can show the calculation result. All the equipment has to show is integrated calorie. It doesn’t need to show instantaneous calorie.

Watt hour meter Equipment that can monitor watt hour consumed both by heat pumps that replaces boilers and by pumps for anti-freezing liquid. All the equipment has to show is integrated watt hour. It doesn’t need to show instantaneous watt hour.


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7. Project Boundaries

The project boundary shall include the following GHG emission sources and GHG emissions.

CO2 emitted when fuel is combusted at the boilers in the reference scenario.

CO2 emitted at the time of generating power to the heat pump in the project scenario.

8. Reference Scenario

In the reference scenario, boilers that consume fossil fuel only continue to be used, and heat

pumps are not used during the project period envisaged. This shall be demonstrated by using

“Check list for determining the reference scenario”.

9. Reference Emissions and Calculation

9.1 Calculation method 1:

REy=Q/EF*FEF (1-1)

Where,

REy Reference CO2 emission (tCO2)

Q Calorie of hot water supplied by heat pumps (GJ)

EF Efficiency of boilers in the reference scenario (－)

FEF Emission factor of fuel for boilers in the reference scenario (tCO2/GJ)


REy=DD*SRE/SDD (2-1)

Where,


DD Degree day (degree Cday)

SRE Standard reference CO2 emission (tCO2)

SDD Standard degree day (degree Cday)

DD=Σ(RT－OTi) (2-2)

Where,


RT Indoor temperature (degree C)

OTi Outdoor temperature (degree C)


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SRE=SQ/EF*FEF (2-3)

Where,

SRE Standard reference CO2 emission (tCO2)

SQ Heating load of the building under the standard climate data (GJ)

EF Efficiency of boilers in the reference scenario (－)

FEF Emission factor of fuel for boilers in the reference scenario (tCO2/GJ)

SDD=Σ(RT－SOTi) (2-4)

Where,


RT Indoor temperature (degree C)

SOTi Standard outdoor temperature (degree C)

10. Project Emissions and Calculation


PEy=W*GEF+PEB (1-2)

Where,

PEy Project CO2 emission (tCO2)

W Watt hour consumed by heat pumps (MWh)

GEF Emission factor of grid (tCO2/MWh)

PEB Emission from the existing boilers (tCO2)


PEy=DD*SPE/SDD+PEB (2-5)

Where,



SPE Standard project CO2 emission (tCO2)



SPE=SQ/3.6/SCOP*GEF (2-6)


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Where,

SPE Standard project CO2 emission (tCO2)

SQ Heating load of the building under the standard climate data (GJ)

3.6 Unit conversion factor (GJ/MWh)

SCOP Average COP of heat pump under the standard climate data (－)

GEF Emission factor of grid (tCO2/MWh)

10.3 Calculation of PEB (Common to both calculation method 1 and 2):

PEB=FQ*HV*FEF (2-7-1)

or

PEB=BQ/EF*FEF (2-7-2)

Where,


FQ Fuel consumption of the existing boilers (ton or Nm3)

HV Lower heating value of fuel of the existing boiler (GJ/ton or GJ/Nm3)

FEF Emission factor of fuel for the existing boilers (tCO2/GJ)

BQ Calorie of hot water supplied by the existing boilers (GJ)

EF Efficiency of the existing boilers (－)

11. Leakage emissions and Calculation

Leakage is not envisaged.

12. Calculation of Emission Reduction

Emission reduction can be calculated from reference CO2 emission and project CO2 emission.


ERy=REy－PEy (1-3)

Where,

ERy Emission reduction (tCO2)




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ERy=C*(REy － PEy) (2-8)

Where,

ERy Emission reduction (tCO2)

C Conservativeness factor (－)



C=ER1/ER2 (2-9)

Where,

ER1 Emission reduction of the reference project calculated in accordance with calculation

method 1 (tCO2)

ER2 Emission reduction of the reference project calculated in accordance with calculation

method 2 (tCO2)

(When calculating ER2 by using formula (2-7), C=1 shall be applied.)

13. Monitoring

The project developers must monitor the parameters described in the table below based on the

calculation method of the selected GHG emission reductions.


Data necessary at ex-ante calculation at the stage of registration Item Description of data Symbol Source Frequency



EF Specialist in this field such as boiler man

When registration


FEF Host government (Ministry of

Environment and Green Development)

When registration



SOTi Host government (meteorological

observatory)

When registration, data for every hour

on the hour or at fixed time every

day (*1) Heating load of the building under the standard climate data

SQ Utilization of simulation (*2)

When registration

Average COP of heat pumps under the standard climate data

SCOP Utilization of simulation (*3)

When registration


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Data necessary to be monitored after implementation of the project Item Description of data Symbol Source Frequency


Calorie of hot water supplied by heat pumps

Q Calorie meter At the start and the end of each

monitoring periodWatt hour consumed by heat pumps (including watt hour consumed by pump for anti-freezing liquid)

W Watt hour meter At the start and the end of each

monitoring period

Emission factor of grid GEF Host government (Ministry of


After monitoring period ends


Climate data (outdoor temperature) OTi Host government (meteorological

observatory)

At the end of each monitoring period, data for every hour


day (*1) Conservativeness factor C Calculation After monitoring

period ends





EF Specialist in this field such as boiler man

When registration


FEF Host government (Ministry of


When registration


SOTi Host government (meteorological

observatory)

When registration, data for every hour


day (*1) Heating load of the building under the standard climate data

SQ Utilization of simulation (*2)

When registration

Average COP of heat pump under the standard climate data

SCOP Utilization of simulation (*3)

When registration


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Data necessary to be monitored after implementation of the project Item Description of data Symbol Source Frequency


Emission factor of grid GEF Host government (Ministry of


After monitoring period ends

Climate data (outdoor temperature) OTi Host government (meteorological

observatory)

At the end of each monitoring period, data for every hour


day (*1) Data that should be received from the reference project

Conservativeness factor C Reference project After monitoring period ends

Remarks (13.1 and 13.2) *1: It is preferable to collect hourly data, but if it is impossible, data at fixed time is acceptable. *2: Hand calculation is possible, but an example of the simulation software is “LOAD2000”. *3: An example of the simulation software available is “Ground Club”. Hand calculation is not feasible.

13.3 Common to both calculation method 1 and 2



Lower heating value of fuel of the existing boilers

HV Host government (Ministry of


When registration

Data necessary to be monitored after implementation of the project (In case of coal) Item Description of data Symbol Source Frequency


Emission factor of grid FQ Fuel transaction document

At the start and the end of each

monitoring period

Data necessary to be monitored after implementation of the project (In case of all types of fuel) Item Description of data Symbol Source Frequency


Emission factor of grid BQ Calorie meter At the start and the end of each

monitoring period


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Annex: Information on the calculation tool

The calculation tools consist of the following 3 tools. (1) Calculation tool 1

This provides emission reduction calculation tool for calculation method 1.

Name of worksheet

Function How to use

1 Plan Calculating emission reduction at the stage of project registration

Input necessary data into the yellow cells.

2 Ex-ante cal Calculating emission reduction at the stage of project registration


3 Climate data Calculating degree day Input necessary data into the yellow cells. If necessary, sum degree day during monitoring period.

4 Report Calculating real emission reduction after each monitoring period


5 Ex-post cal Calculating real emission reduction after each monitoring period


(2) Calculation tool 2

This provides annual heating load calculation tool for calculation method 1 and 2.

Name of worksheet

Function How to use

condition 1 Calculating overall heat transfer coefficient of outer wall, roof, foundation, and window

Input necessary data into the yellow cells. If necessary, add rows.

condition 2 Setting area, volume, indoor temperature, and ventilation frequency for draft calculation


condition 3 Setting standard outdoor temperature Input necessary data into the yellow cells. condition 4 Setting underground temperature Input necessary data into the yellow cells. calculation Showing calculation result If necessary, sum heating load during

monitoring period. (3) Calculation tool 3

This provides emission reduction calculation tool for calculation method 2.

Name of worksheet

Function How to use

1 Plan Calculating emission reduction at the stage of project registration


2 Ex-ante cal Calculating emission reduction at the stage of project registration


3 Climate data Calculating degree day Input necessary data into the yellow cells. If necessary, sum degree day during monitoring period.

4 Report Calculating real emission reduction after each monitoring period


5 Ex-post cal Calculating real emission reduction after each monitoring period


I-19

[Attachment to G

EC’s D

emonstration/Feasibility Study R

eport JFY2012]

Calculation method 1, Plan

Name of the project: Geothermal Heat Pump Project at a Kindergarten in Zuunmod Aimag

1. Monitoring plan and input values for ex-ante estimation

Parameters Description of dataEstimated

valuesUnits

Monitoringpattern

Source ofdata

Measurement methods andprocedures

Monitoringfrequency

QA/QC procedures Other comments

QCalorie of hot water supplied by heatpumps

1,382.5 GJ pattern Cmonitored

data

Collecting calorie data from acontroled calorie meter and inputingto an spread sheet electrically.

At the start andthe end of eachmonitoring period

A controled monitoring device is installed. Personresponsible for monitoring double check the inputdata.

N/A

WWatt hour consumed by heat pumps(including watt hour consumed bypump for anti-freezing liquid)

169.9 MWh pattern Cmonitored

data

Collecting electricity consumptiondata from a controled watt hourmeter and inputing to an spreadsheet electrically.



N/A

GEF Emission factor of grid 1.1501 tCO2/MWh pattern ADNA's web

siteCollecting emission factor at DNA'sweb site.

At the time beforedrawing upmonitoring report

QA/QC is conducted by DNA. N/A

Oti Climate data (outdoor temperature)

(fill in the tablein the

worksheet "3Climate data")

degree C pattern A

NationalAgency for

Meteorologyand

EnvironmentMonitoring

Collecting climate data from NationalAgency for Meteorology andEnvironment Monitoring.


QA/QC is conducted by National Agency forMeteorology and Environment Monitoring.

N/A

FQFuel consumption of the existingboilers

0.0 ton or Nm3 pattern Cmonitored

data

Collecting fuel consumption datafrom a controled meter (weight scaleor flow meter) and inputing to anspread sheet electrically.

In case of weightscale: everytimefuel is carried inand accumulatethe dataIn case of flowmeter: at the startand the end ofeach monitoringperiod


If BQ ismonitored, FQneeds not to bemonitored.

BQCalorie of hot water supplied by theexisting boilers

0.0 GJ pattern Cmonitored

data




If FQ is monitored,BQ needs not tobe monitored.

2. Ex-ante estimation of CO2 emission reductions

Units

tCO2

[Attachment to Project Designe Document] Monitoring Plan and Ex-ante Estimation of Emission Reductions -input sheet-

CO2 emission reductions

131

2012/09/6Ver1.0


I-20

Calculation method 1, Ex-ante calculation


1. Calculations for emission reductions Cell type Value Units Parameter

Emission reductionAutomaticcalculation

131.5 tCO2 ERy

2. Selected default values, etc. Cell type Value Units Parameter

Efficiency of boilers in the reference scenarioInput

manually0.40 - EF

Emission factor of fuel for boilers in the reference scenarioInput

manually0.0946 tCO2/GJ FEF

Standard climate data (outdoor temperature)Input

manually



degree C SOTi

Heating load of the building under the standard climate dataInput

manually1,382.5 GJ SQ

Average COP of heat pump under the standard climate dataInput

manually2.26 - SCOP

Lower heating value of fuel of the existing boilerInput

manually14.24

GJ/ton orGJ/Nm3

HV

3. Calculations for reference emissions Cell type Value Units Parameter

Reference CO2 emissionAutomaticcalculation

327.0 tCO2 REy

4. Calculations of the project emissions Cell type Value Units Parameter

Project CO2 emissionAutomaticcalculation

195.4 tCO2 PEy

5. Calculations of the conservativeness factor Cell type Value Units Parameter

Standard reference CO2 emissionAutomaticcalculation

327.0 tCO2 SRE

Standard degree dayAutomaticcalculation

6,588 degree Cday SDD

Degree dayAutomaticcalculation

6,588 degree Cday DD

Reference CO2 emission REy2Automaticcalculation

327.0 tCO2 REy2

Standard project CO2 emissionAutomaticcalculation

195.4 tCO2 SPE

Project CO2 emission REy2Automaticcalculation

195.4 tCO2 PEy2

Emission reduction in accordance with calculation method 1Automaticcalculation

131.5 tCO2 ER1


131.5 tCO2 ER2

Conservativeness factorAutomaticcalculation

1.00 - C

[Attachment to Project Designe Document] Ex-ante Estimation of Emission Reductions -automated calculation sheet-

I-21

[Attachment to G

EC’s D


eport JFY2012]

Calculation method 1, Report


1. Monitoring records

Monitoringperiod

Parameters Description of dataMonitored

valuesUnits

Monitoringpattern

Source ofdata


Monitoringfrequency

QA/QC procedures takenOther

comments

2012/09/15-2012/10/31

QCalorie of hot water supplied by heatpumps


data



A controled monitoring device isinstalled. Person responsible formonitoring double check the inputdata.

N/A

2012/09/15-2012/10/31

WWatt hour consumed by heat pumps(including watt hour consumed bypump for anti-freezing liquid)

6.685 MWh pattern Cmonitored

data

Collecting electricity consumptiondata from a controled watt hourmeter and inputing to an spreadsheet electrically.



N/A

N/A GEF Emission factor of grid 1.1501 tCO2/MWh pattern ADNA's web




2012/09/15-2012/10/31




degree C pattern A

NationalAgency for

Meteorologyand




QA/QC is conducted by NationalAgency for Meteorology andEnvironment Monitoring.

N/A

2012/09/15-2012/10/31



data


In case of weightscale: everytimefuel is carried inand accumulatethe dataIn case of flowmeter: at the startand the end of


If BQ ismonitored, FQneeds not tobe monitored.

2012/09/15-2012/10/31



data




If FQ ismonitored, BQneeds not tobe monitored.

2. Ex-post calculation of CO2 emission reductions

CO2 emission reductions Units

9 tCO2

[For Verification] Monitoring Report -input sheet-

Offseting Period

2012/09/15-2012/10/31


I-22

Calculation method 1, Ex-post calculation




9.7 tCO2 ERy



manually0.40 - EF




manually



degree C SOTi


manually153.5 GJ SQ


manually2.30 - SCOP


manually14.24

GJ/ton orGJ/Nm3

HV



17.4 tCO2 REy



7.7 tCO2 PEy

5. Calculations of the conservativeness factor Cell type Value Units Parameter


36.3 tCO2 SRE


743 degree Cday SDD


736 degree Cday DD

Reference CO2 emission REy2Automaticcalculation

36.0 tCO2 REy2


21.3 tCO2 SPE

Project CO2 emission REy2Automaticcalculation

21.1 tCO2 PEy2


9.7 tCO2 ER1


14.8 tCO2 ER2

Conservativeness factorAutomaticcalculation

0.6543 - C

[For Verification] Monitoring Report -automated calculation sheet-

I-23

[Attachment to G

EC’s D


eport JFY2012]

Calculation method 2, Plan


1. Monitoring plan and input values for ex-ante estimation

Parameters Description of dataEstimated

valuesUnits

Monitoringpattern

Source ofdata


Monitoringfrequency

QA/QC procedures Other comments

C Conservativeness factor 1.00 - pattern AReference

projectCollecting conservativeness factorfrom the reference project.


QA/QC is conducted by the reference project. N/A

GEF Emission factor of grid 1.1501 tCO2/MWh pattern ADNA's web







degree C pattern A

NationalAgency for

Meteorologyand




QA/QC is conducted by National Agency forMeteorology and Environment Monitoring.

N/A



data




If BQ ismonitored, FQneeds not to bemonitored.



data




If FQ is monitored,BQ needs not tobe monitored.

2. Ex-ante estimation of CO2 emission reductions

Units

tCO2

[Attachment to Project Designe Document] Monitoring Plan and Ex-ante Estimation of Emission Reductions -input sheet-

CO2 emission reductions

131

2012/09/6Ver1.0


I-24

Calculation method 2, Ex-ante calculation




131.5 tCO2 ERy



manually0.40 - EF




manually



degree C SOTi


manually1,382.5 GJ SQ


manually2.26 - SCOP


manually14.24

GJ/ton orGJ/Nm3

HV



6,588 degree Cday SDD


6,588 degree Cday DD


327.0 tCO2 SRE


327.0 tCO2 REy



195.4 tCO2 SPE


195.4 tCO2 PEy

[Attachment to Project Designe Document] Ex-ante Estimation of Emission Reductions -automated calculation sheet-

I-25

[Attachment to G

EC’s D


eport JFY2012]

Calculation method 2, Report


1. Monitoring records

Monitoringperiod

Parameters Description of dataMonitored

valuesUnits

Monitoringpattern

Source ofdata


Monitoringfrequency

QA/QC procedures takenOther

comments

N/A C Conservativeness factor 0.6543 - pattern AReference

projectCollecting conservativeness factorfrom the reference project.


QA/QC is conducted by the reference N/A

N/A GEF Emission factor of grid 1.1501 tCO2/MWh pattern ADNA's web




2012/09/15-2012/10/31




degree C pattern A

NationalAgency for

Meteorologyand




QA/QC is conducted by NationalAgency for Meteorology andEnvironment Monitoring.

N/A

2012/09/15-2012/10/31



data




If BQ ismonitored, FQneeds not tobe monitored.

2012/09/15-2012/10/31



data




If FQ ismonitored, BQneeds not tobe monitored.

2. Ex-post calculation of CO2 emission reductions

CO2 emission reductions Units

9 tCO2

[For Verification] Monitoring Report -input sheet-

Offseting Period

2012/09/15-2012/10/31


I-26

Calculation method 2, Ex-post calculation




9.7 tCO2 ERy



manually0.40 - EF




manually



degree C SOTi


manually153.5 GJ SQ


manually2.30 - SCOP


manually14.24

GJ/ton orGJ/Nm3

HV



743 degree Cday SDD


736 degree Cday DD


36.3 tCO2 SRE


36.0 tCO2 REy



21.3 tCO2 SPE


21.1 tCO2 PEy

[For Verification] Monitoring Report -automated calculation sheet-

Documents

MRV Methodology Title: “Replacement of boiler by heat pump in …gec.jp/gec/jp/Activities/fs_newmex/2012/preliminary... · 2013-02-20 · the same climate zone. In accordance with