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In many structures the members are required to resist more than one kind of loading (combined loading). These can often be analyzed by superimposing the stresses and strains cause by each load acting separately.
Superposition of stresses and strains is permissible only under the following conditions:
a.The stresses and the strains must be a linear function of the applied loads (Hooke’s law must be obeyed and the displacements must be small).
b.There must be no interaction between the various loads.
COMBINED LOADS
Examples: wide‐flange beam supported by a cable (combined bending and axial load), cylindrical pressure vessel supported as a beam, and shaft in combined torsion and bending.
1.Select the point on the structure where the stresses and the strains are to be determined.
2.For each load on the structure, determine the stress resultant at the cross section containing the selected point..
3.Calculate the normal and shear stresses at the selected point due to each of the stress resultant.
4.Combine the individual stresses to obtain the resultant stresses at the selected point.
5.Determine the principal stresses and maximum shear stresses at the selected point.
6.Determine the strains at the point with the aid of Hooke’s law for plane stress.
7.Select additional points and repeat the process.
tpr
IbVQ
IMy
AP
==
−=ΙΤ
==
στ
σρτσρ
Method of Analysis:
The bar shown is subjected to two types of loads: a torque T and a vertical load P.
Let us select arbitrarily two points. Point A (top of the bar) and point B (side of the bar ‐ in the same cross section).
The resulting stresses acting across the section are the following:
‐ A twisting moment equal to the torque T.
‐ A bending moment M equal to the load P times the distance b.
‐ A shear force V equals to the load P.
Illustration of the Method:
The twisting moment Τ produces a torsional shear stresses
The stress τ1 acts horizontally to the left at point A and vertically downwards at point B.
The bending moment M produces a tensile stress at point A
However, the bending moment produces no stress at point B, because B is located on the neutral axis.
32rT
ITr
Polartorsion π
τ ==
34
rM
IMr
bending πσ ==
The shear force V produces no shear stress at the top of the bar (point A), but at point B the shear stress is as follows:
σA and τ1 are acting in point A, while the τ1 and τ2 are acting in point B.
AV
IbVQ
shear 34
==τ
Note that the element is in plane stress with
σx = σA, σy = 0 , and τxy = - τ1.
A stress element in point B is also in plane stress and the only stresses acting on this element are the shear stresses τ1 and τ2. Therefore
σx = σy = 0 and τxy = - (τ1 + τ2).
At point A: σx = σA, σy = 0 , and τxy = - τ1
At point B σx = σy = 0 and τxy = - (τ1 + τ2).
Of interest are the points where the stresses calculated from the flexure and shear formulas have maximum or minimum values, called critical points.
If the objective of the analysis is to determine the largest stresses anywhere in the structure, then the critical points should be selected at cross sections where the stress resultants have their largest values.
Furthermore, within those cross sections, the points should be selected where either the normal stresses or the shear stresses have their largest values.
Selection of Critical Areas and Points
For instance, the normal stresses due to bending are largest at the cross section of maximum bending moment, which is at the support. Therefore, points C and D at the top and bottom of the beam at the fixed ends are critical points where the stresses should be calculated.
Stress at which point?
The rotor shaft of an helicopter drives the rotor blades that provide the lifting force to support the helicopter in the air. As a consequence, the shaft is subjected to a combination of torsion and axial loading.
For a 50mm diameter shaft transmitting a torque Τ = 2.4kN.m and a tensile force P = 125kN, determine the maximum tensile stress, maximum compressive stress, and maximum shear stress in the shaft.
Solution
The stresses in the rotor shaft are produced by the combined action of the axial force P and the torque Τ. Therefore the stresses at any point on the surface of the shaft consist of a tensile stress σo and a shear stress τo.
( )MPa
mkN
AP 66.63
05.04
1252 === πσThe tensile
stress
The shear stress to is obtained from the torsion formula
( )
( )MPa
mkN
ITr
PTorsion 78.97
3205.0
205.0.4.2
4 =⎟⎠⎞
⎜⎝⎛
==π
τ
( ) MPaxyyx
MAX 1032
22
=+⎟⎟⎠
⎞⎜⎜⎝
⎛ −= τ
σστ
33.2103
2480
==⇒MPa
MPaSFMSST
Knowing the stresses σo and τo, we can now obtain the principal stresses and maximum shear stresses . The principal stresses areobtained from
( )22
2,1 22 xyyxyx τ
σσσσσ +⎟⎟
⎠
⎞⎜⎜⎝
⎛ −±⎟⎟
⎠
⎞⎜⎜⎝
⎛ +=
The maximum in-plane shear stresses are obtained using the formula
Because the principal stresses σ1 and σ2 have opposite signs, the maximum in-plane shear stresses are larger than the maximum out-of-plane shear stresses. Therefore, the maximum shear stress in the shaft is 103MPa.
( )
MPaMPa
71135
78.972
66.6302
66.630
2
1
22
2,1
−==
−+⎟⎠⎞
⎜⎝⎛ −
±⎟⎠⎞
⎜⎝⎛ +
=
σσ
σ
Will it fail if σyield=480MPa?
( ) ( )( ) ( )
65.22.181
4802.1817171135135 22
==⇒
=−+−−=
MPaMPaSFDET
MPaVMσ
A thin wall cylindrical pressure vessel with a circular cross section is subjected to internal gas pressure p and simultaneously compressed by an axial load P = 12k. The cylinder has inner radius r = 2.1in. And wall thickness t = 0.15in. Determine the maximum allowable internal pressure pallow based upon an allowable shear stress of 6500psi in the wall of the vessel.
Solution
The stresses on the wall of the pressure vessel are caused by a combined action of the internal pressure and the axial force. We can isolate a stress element in point A. The x-axis is parallel to the longitudinal axis of the pressure vessel and the y-axis is circumferential. Note that there are no shear stresses acting on the element.
The longitudinal stress σx is equal to the tensile stress produced by the internal pressure minus the compressive stress produced by the axial force.
rtP
tpr
AP
tpr
x πσ
222−=−=
The circumferential stress σy is equal to the tensile stress produced by the internal pressure.Note that σy > σx .
tpr
y =σ
Since no shear stresses act on the element the above stresses are also the principal stresses
rtP
tprtpr
x
y
πσσ
σσ
222
1
−==
==
( )
( )( ) ( )( )[ ] psip
inink
in.in.p
rtP
tpr
pin.in.p
tpr
60630.715.01.22
12150212
22
0.14150
12
2
1
−=−=−=
===
ππσ
σ
substituting numerical values
In-Plane Shear StressesThe maximum in-plane shear stress is
( ) ( ) ( )( ) psippsippMax 30325.3
260630.70.14
221 +=
−−=
−=
σστ
Since τmax is limited to 6500psi then
psippsippsi allowed 99030324.365000 =⇒+=
Out-of-Plane Shear StressesThe maximum out-of-plane shear stress is either
Comparing the three calculated values for the allowable pressure, we see that (pallow)3 = 928psi governs.At this pressure, the principal stresses are σ1 = 13000psi and σ2 = 430psi.These stresses have the same signs, thus confirming that one of the out-of-plane shear stresses must be the largest shear stress.
2
22
1
στ
στ
=
=
Max
Max
From the first equation we get
From the second equation we get:
psippsippsi
allowed 272030325.365000
=−=
psipppsi allowed 9280.765000 =⇒=
Allowable internal pressure
A sign of dimensions 2.0mx1.2m is supported by a hollow circular pole having outer diameter 220mm and inner diameter 180mm (see figure). The sign offset 0.5m from the centerline of the pole and its lower edge is 6.0m above the ground.
Determine the principal stresses and maximum shear stresses at points A and B at the base of the pole due to wind pressure of 2.0kPa against the sign.
SolutionStress Resultant: The wind pressure against the sign produces a resultant force W that acts at the midpoint of the sign and it is equal to the pressure p times the area A over which it acts:
( )( ) kNmmkPapAW 8.42.10.20.2 =×==
The line of action of this force is at height h = 6.6m above the ground and at distance b = 1.5m from the centerline of the pole.The wind force acting on the sign is statically equivalent to a lateral force Wand a torque Τ acting on the pole.
The torque is equal to the force Wtimes the distance b:
( )( )mkNT
mkNWbT−=
==2.7
5.18.4
The stress resultant at the base of the pole consists of a bending moment M, a torque Τ and a shear force V. Their magnitudes are:M = Wh = (4.8kN)(6.6m) = 31.68kN.mΤ = 7.2kN.mV = W = 4.8kN
Examination of these stress resultants shows that maximum bending stresses occur at point A and maximum shear stresses at point B.Therefore, A and B are critical points where the stresses should be determined.Stresses at points A and BThe bending moment M produces a tensile stress σa at point A, but no stress at point B (which is located on the neutral axis)
( )( )( )
( ) MPamkNdd
dMa 91.54
6418.022.011.068.31
64
2444
142
2
=
⎥⎦
⎤⎢⎣
⎡ −=
⎥⎦
⎤⎢⎣
⎡ −
⎟⎠⎞
⎜⎝⎛
=ππ
σ
The torque Τ produces shear stresses τ1 at points A and B.
Finally, we need to calculate the direct shear stresses at points A and Bdue to the shear force V.
( )( )( )
( ) MPammkNdd
dTTorsion 24.6
3218.022.011.0.2.7
32
2444
142
2
=
⎥⎦
⎤⎢⎣
⎡ −=
⎥⎦
⎤⎢⎣
⎡ −
⎟⎠⎞
⎜⎝⎛
=ππ
τ
The shear stress at point A is zero, and the shear stress at point B (τ2) is obtained from the shear formula for a circular tube
The stresses acting on the cross section at points A and Bhave now been calculated.
( )
( ))(2
32
64
12
31
32
41
42
2
rrb
rrQ
ddI
IbVQ
−=
−=
⎥⎦
⎤⎢⎣
⎡ −=
=
π
τ
( ) MPamA
VMax 7637.0
01257.0480022
2,2 ===τ
Stress ElementsFor both elements the y-axis is parallel to the longitudinal axis of the pole and the x-axis is horizontal.Point A :σx = 0 σy = σa = 54.91MPa τxy = τ1 = 6.24MPa
( )22
2,1 22 xyyxyx τ
σσσσσ +⎟⎟
⎠
⎞⎜⎜⎝
⎛ −±⎟⎟
⎠
⎞⎜⎜⎝
⎛ +=Principal stresses at Point A
Substituting σ1,2 = 27.5MPa +/- 28.2MPaσ1 = 55.7MPa and σ2 = - 0.7MPa
The maximum in-plane shear stresses can be obtained from the equation
( ) MPaxyyx
MAX 2.282
22
=+⎟⎟⎠
⎞⎜⎜⎝
⎛ −= τ
σστ
Because the principal stresses have opposite signs, the maximum in-plane shear stresses are larger than the maximum out-of-plane shear stresses. Then, τmax = 28.2MPa.
Point B :σx = σy = 0 τxy = τ1 + τ2τxy = 6.24MPa + 0.76MPa = 7.0MPaPrincipal stresses at point B areσ1 = 7.0MPa σ2 = - 7.0 MPaAnd the maximum in-plane shear stress is
τmax = 7.0MPaThe maximum out-of-plane shear stresses are half of this value.Note
If the largest stresses anywhere in the pole are needed, then we must also determine the stresses at the critical point diametrically opposite point A, because at that point the compressive stress due to bending has its largest value.The principal stresses at that point are σ1 = 0.7MPa and σ2 = - 55.7MPa The maximum shear stress is 28.2MPa.(In this analysis only the effects of wind pressure are considered. Other loads, such as weight of the structure, also produce stresses at the base of the pole).
A tubular post of square cross section supports a horizontal platform (see figure). The tube has outer dimension b = 6in. And wall thickness t = 0.5in.The platform has dimensions 6.75in x 24.0in and supports an uniformly distributed load of 20psi acting over its upper surface. The resultant of this distributed load is a vertical force P1 = (20psi)(6.75in x 24.0in) = 3240lb
This force acts at the midpoint of the platform, which is at distance d = 9in. from the longitudinal axis of the post. A second load P2 = 800lb acts horizontally on the post at height h = 52in above the base.Determine the principal stresses and maximum shear stresses at points A and B at the base of the post due to the loads P1 and P2.
Stress ResultantsThe force P1 acting on the platform is statically equivalent to a force P1 and a moment M1 = P1d acting on the centroid of the cross section of the post. The load P2 is also shown.
Solution
The stress resultant at the base of the post due to the loads P1 and P2 and the moment M1 are as follows:(A) An axial compressive force P1 = 3240lb(B) A bending moment M1 produced by the force P1:
M1 = P1d = (3240lb)(9in) = 29160lb-in(C) A shear force P2 = 800lb(D) A bending moment M2 produced by the force P2:
M2 = P2h = (800lb)(52in) = 41600lb.in
Examinations of these stress resultants shows that both M1 and M2 produce maximum compressive stresses at point A and the shear force produces maximum shear stresses at point B. Therefore, A and B are the critical points where the stresses should be determined.
Stresses at points A and B(A) The axial force P1 produces uniform compressive stresses throughout the post. These stresses are σP1 = P1 / A where A is the cross section area of the postA = b2 – (b – 2t)2 = 4t(b-t) = 4 (0.5in)(6in – 0.5in) = 11.0in2
σP1 = P1 / A = 3240lb / 11.00in2 = 295psi
(B) The bending moment M1 produces compressive stresses σM1 at points Aand B. These stresses are obtained from the flexure formula σM1 = M1 (b / 2) / Ιwhere Ι is the moment of inertia of the cross section. The moment of inertia isΙ = [b4 - (b -2t)4] / 12 = [(6in)4 – (5in)4] / 12 = 55.92in4
Thus, σM1 = M1 b / 2Ι = (29160lb.in)(6in) / (2)(55.92in4) = 1564psi
(C) The shear force P2 produces a shear stress at point B but not at point A. We know that an approximate value of the shear stress can be obtained by dividing the shear force by the web area.τP2 = P2 / Aweb =P2 /(2t(b – 2t)) =800lb / (2)(0.5in)(6in–1in)= 160psiThe stress τp2 acts at point B in the direction shown in the above figure.We can calculate the shear stress τP2 from the more accurate formula. The result of this calculation is τP2 = 163psi, which shows that the shear stress obtained from the approximate formula is satisfactory.
D) The bending moment M2 produces a compressive stress at point A but no stress at point B. The stress at A is σM2 = M2 b / 2Ι = (41600lb.in)(6in) / (2)(55.92in4) = 2232psi.This stress is also shown in the above figure.
Stress ElementsEach element is oriented so that the y-axis is vertical (i.e. parallel to the longitudinal axis of the post) and the x-axis is horizontal axisPoint A : The only stress in point A is a compressive stress σa in the y directionσA = σP1 + σM1 + σM2σA = 295psi + 1564psi + 2232psi = 4090psi (compression)Thus, this element is in uniaxial stress.
Principal Stresses and Maximum Shear Stressσx = 0 σy = - σa = - 4090psiτxy = 0
Since the element is in uniaxial stress, σ1 = σx and σ2 = σy = - 4090psi
And the maximum in-plane shear stress isτmax = (σ1 - σ2) / 2 = ½ (4090psi) = 2050psiThe maximum out-of-plane shear stress has the same magnitude.
Point B:Here the compressive stress in the y direction isσB = σP1 + σM1σB = 295psi + 1564psi = 1860psi (compression)And the shear stress is τB = τP2 = 160psiThe shear stress acts leftward on the top face and downward on the x face of the element.Principal Stresses and Maximum Shear Stressσx =0 σy = - σB = - 1860psi τxy = - τP2 = - 160psiSubstituting σ1,2 = - 930psi +/- 944psiσ1 = 14psi and σ2 = - 1870psi
( )22
2,1 22 xyyxyx τ
σσσσσ +⎟⎟
⎠
⎞⎜⎜⎝
⎛ −±⎟⎟
⎠
⎞⎜⎜⎝
⎛ +=
The maximum in-plane shear stresses can be obtained from the equation Because the principal stresses have opposite signs, the maximum in-plane shear stresses are larger than the maximum out-of-plane shear stresses. Then, τmax = 944psi. ( ) psixy
xMAX 944
22
2
=+⎟⎠⎞
⎜⎝⎛= τ
στ
Three forces are applied to a short steel post as shown. Determine the principle stresses, principal planes and maximum shearing stress at point H.
Determine internal forces in Section EFG.
Solution
( )( ) ( )( )
( )( ) mkN3m100.0kN30 0mkN5.8
m200.0kN75m130.0kN50kN75kN50kN 30
⋅===⋅−=
−=−==−=
zy
x
x
zx
MMMM
VPV
Note: Section properties, ( )( )
( )( )
( )( ) 463121
463121
23
m10747.0m040.0m140.0
m1015.9m140.0m040.0
m106.5m140.0m040.0
−
−
−
×==
×==
×==
z
x
I
I
A
( )( )
( )( )
( ) MPa66.0MPa2.233.8093.8m1015.9
m025.0mkN5.8m10747.0
m020.0mkN3m105.6
kN50
46
4623-
=−+=×
⋅−
×
⋅+
×=
−++=
−
−
x
x
z
zy I
bMI
aMAPσ
Evaluate the stresses at H.
Shear stress at H.
( )( )[ ]( )
( )( )( )( )
MPa52.17
m040.0m1015.9m105.85kN75
m105.85
m0475.0m045.0m040.0
46
36
36
11
=
×
×==
×=
==
−
−
−
tIQV
yAQ
x
zyzτ
Normal stress at H.
Calculate principal stresses and maximum shearing stress.
°=
°===
−=−=−=
=+=+=
=+==
98.13
96.2720.33
52.172tan
MPa4.74.370.33
MPa4.704.370.33
MPa4.3752.170.33
pp
min
max
22max
p
CDCY
ROC
ROC
R
θ
θθ
σ
σ
τ
°=
−=
=
=
98.13
MPa4.7
MPa4.70
MPa4.37
min
max
max
pθ
σ
σ
τ
The cantilever tube shown is to be made of 2014 aluminum alloy treated to obtain a specified minimum yield strength of 276MPa. We wish to select a stock size tube (according to the table below). Using a design factor of n=4. The bending load is F=1.75kN, the axial tension is P=9.0kN and the torsion is T=72N.m. What is the realized factor of safety?
Consider the critical area ( top surface).
IMc
AP
x +=σ
Maximum bending moment = 120F
I
dkNxmm
AkN
x
⎟⎠⎞
⎜⎝⎛×
+= 275.1120
9σ
Jd
J
d
JTr
zx362
72=
⎟⎠⎞
⎜⎝⎛×
==τ
( ) 2122 3 zxxVM τσσ +=
GPaGPanSy
VM 0690.04276.0
==≤σ
For the dimensions of that tube
57.406043.0276.0
===VM
ySn
σ
A certain force F is applied at D near the end of the 15-in lever, which is similar to a socket wrench. The bar OABC is made of AISI 1035 steel, forged and heat treated so that it has a minimum (ASTM) yield strength of 81kpsi. Find the force (F) required to initiate yielding. Assume that the lever DC will not yield and that there is no stress concentration at A.
Solution:
1) Find the critical section
The critical sections will be either point A or Point O. As the moment of inertia varies with r4
then point A in the 1in diameter is the weakest section.
Fd
inFd
dM
IMy
x 6.1421432
64
234 =××
=⎟⎠⎞
⎜⎝⎛
==ππ
σ
2) Determine the stresses at the critical section
Fin
inFd
dT
JTr
zx 4.76)1(1516
32
234 =
××=
⎟⎠⎞
⎜⎝⎛
==ππ
τ
3) Chose the failure criteria.
The AISI 1035 is a ductile material. Hence, we need to employ the distortion-energy theory.
lbfS
F
F
VM
y
zxxxyyxyxVM
4165.194
81000
5.19433 22222
===
=+=+−+=
σ
τστσσσσσ
Apply the MSS theory. For a point undergoing plane stress with only one non-zero normal stress and one shear stress, the two non-zero principal stresses (σA and σB) will have opposite signs (Case 2).
( ) ( )( )lbfF
FF
S
S
zxxzxx
yBA
zxxyBA
3884.7646.14281000
42
2
222
2122
2222
22
max
=×+=
+=+⎟⎠⎞
⎜⎝⎛=≥−
+⎟⎠⎞
⎜⎝⎛±==
−=
τστσσσ
τσσστ
A round cantilever bar is subjected to torsion plus a transverse load at the free end. The bar is made of a ductile material having a yield strength of 50000psi. The transverse force (P) is 500lb and the torque is 1000lb-in applied to the free end. The bar is 5in long (L) and a safety factor of 2 is assumed. Transverse shear can be neglected. Determine the minimum diameter to avoid yielding using both MSS and DET criteria.
Solution
1) Determine the critical section
The critical section occurs at the wall.
3432
64
2dPL
d
dPL
IMc
x ππσ =
⎟⎠⎞
⎜⎝⎛
==34
16
32
2dT
d
dT
JTc
xy ππτ =
⎟⎠⎞
⎜⎝⎛
==
( ) ( )
( )
( ) ⎥⎦⎤
⎢⎣⎡ +×±×=
⎥⎦⎤
⎢⎣⎡ +±=⎟
⎠⎞
⎜⎝⎛+⎟
⎠⎞
⎜⎝⎛±=
+⎟⎠⎞
⎜⎝⎛±⎟
⎠⎞
⎜⎝⎛=+⎟⎟
⎠
⎞⎜⎜⎝
⎛ −±⎟⎟
⎠
⎞⎜⎜⎝
⎛ +=
2232,1
223
2
3
2
332,1
22
22
2,1
10005500550016
16161616
2222
d
TPLPLdd
TdPL
dPL
xyxx
xyyxyx
πσ
ππππσ
τσστσσσσ
σ
indn
Sdd
yMAX
MAX
031.1
000,252
500002
4.137152
)8.980(264502
31
3331
≥
==≤=−
=−−
=−
=
τσσ
σστ
3126450
d=σ 32
8.980d
−=σ The stresses are in the wrong order.. Rearranged to
3126450
d=σ 33
8.980d
−=σ
MSS
indnS
d
dddd
yVM
VM
025.12
5000026950
8.980264508.98026450
3
33
2
3
2
3312
32
1
≥
=≤=
⎟⎠⎞
⎜⎝⎛−⎟
⎠⎞
⎜⎝⎛−⎟
⎠⎞
⎜⎝⎛−+⎟
⎠⎞
⎜⎝⎛=−+=
σ
σσσσσDET
The factor of safety for a machine element depends on the particular point selected for the analysis. Based upon the DET theory, determine the safety factor for points A and B.
This bar is made of AISI 1006 cold-drawn steel (Sy=280MPa) and it is loaded by the forces F=0.55kN, P=8.0kN and T=30N.m
Solution:Point A 2324
432
464
2dP
dFl
dP
d
dFl
AreaP
IMc
x ππππσ +=+
⎟⎠⎞
⎜⎝⎛
=+=
( )( )( )( )
( )( )( )
MPax 49.9502.01084
02.01.01055.032
2
3
3
3
=+=ππ
σ
( )( )
MPadT
JTr
xy 10.19020.0301616
33 ====ππ
τ
( ) ( )[ ]77.2
1.101280
1.1011.19349.953 212222
===
=+=+=
VM
y
xyxVM
Sn
MPa
σ
τσσ
Point B ( )( )( )
( )( )
( )( )( )
( )[ ]22.6
02.45280
02.4543.21347.25
43.2102.0
43
1055.0402.03016
3416
47.2502.010844
2122
2
3
33
2
3
2
==
=+=
=⎟⎠⎞
⎜⎝⎛
+=+=
===
n
MPa
MPaAV
dT
MPadP
VM
xy
x
σ
πππτ
ππσ
The shaft shown in the figure below is supported by two bearings and carries two V-belt sheaves. The tensions in the belts exert horizontal forces on the shaft, tending to bend it in the x-z plane. Sheaves B exerts a clockwise torque on the shaft when viewed towards the origin of the coordinate system along the x-axis. Sheaves C exerts an equal but opposite torque on the shaft. For the loading conditions shown, determine the principal stresses and the safety factor on the element K, located on the surface of the shaft (on the positive z-side), just to the right of sheave B. Consider that the shaft is made of a steel of a yield strength of 81ksi
Shearing force = 165lbBending Moment = -1540lb-in
( )( )
ksirrM
IMc
x 031.8625.0
15404
4
34 =−
−=−=−=ππ
σ
( )( )
ksirT
JTr
xz 868.2625.0
11002233 ====
ππτ
( ) ( )
( )
ksiksi
xyxx
xyyxyx
92.0 95.8
868.2203.8
203.8
2222
21
22
2,1
22
22
2,1
−==
+⎟⎠⎞
⎜⎝⎛±=
+⎟⎠⎞
⎜⎝⎛±⎟
⎠⎞
⎜⎝⎛=+⎟⎟
⎠
⎞⎜⎜⎝
⎛ −±⎟⎟
⎠
⎞⎜⎜⎝
⎛ +=
σσ
σ
τσστσσσσ
σ
( )
2.8935.4
281
2..
935.42
92.095.82
..... 31
====
=−−
=−
=
Max
Y
Max
SnFactorSafety
ksiMSS
τ
σστ
( ) ( ) ( )( )
58.844.9
81..
44.992.095.892.095.8...... 2231
23
21
====
=−−−+=−+=
VM
y
VM
SnFactorSafety
ksiDET
σ
σσσσσ
A horizontal bracket ABC consists of two perpendicular arms AB and BC, of 1.2m and 0.4m in length respectively. The Arm AB has a solid circular cross section with diameter equal to 60mm. At point C a load P1=2.02kN acts vertically and a load P2=3.07kN acts horizontally and parallel to arm AB.For the points p and q, located at support A, calculate:(1)The principal stresses.(2) the maximum in-plane shear stress.
1.2m
q
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