Thank you
Chapter 13, Reserve Problem 118 The strain rosette shown in the figure was used to obtain...
The strain rosette shown in the figure was used to obtain the following normal strain data at a point on the free surface of a machine part: Ea = 640 pe Eb = -1600 ue Ec = -1255 ue 45° 45° Calculate the strain components on the machine part at this point. Ex = με με Ey = Yxy = i i urad
Problem 14.044 The strain rosette shown in the figure was used to obtain normal strain data at a point on the free surface of a machine part. The rosette measures: 900 HE; Eb -350 με; Ec-1420 με; v-0.14. (a) Determine the strain components εχ,ey, and Yxy at the point. (b) Determine the principal strains (p1> Ep2) and the maximum in-plane shear strain Yip at the point. c) Determine the angle e, counterclockwise is positive, clockwise is negative), and then draw...
The strain rosette shown in the figure was used to obtain the
following normal strain data at a point on the free surface of a
machine part: εa = -1420 με,
εb = -900 με, and εc = -240
με. Poisson’s ratio for the material is ν = 0.33.
Determine the strain component εx at the
point.
-887 με
-1420 με
-995 με
-1501 με
-1191 με
which of these answers
b с .09 .09 X a
strain rosette shown in the figure was used to obtain normal strain data at a point on the free surface of a machine component. E-220 GPa, va0.3, a,--1 25 με, 6-95 μ, e-310 μα] Determine the shear stress in the xy plane. 71.1 MPa -89.7 MPa 41.8 MPa 97.1 MPa -33.3 MPa
strain rosette shown in the figure was used to obtain normal strain data at a point on the free surface of a machine component. E-220 GPa, va0.3, a,--1...
The strain rosette shown in the figure was used to obtain normal strain data at a point on the free surface of a machine component. Determine the principle stress op -148 MPa 95.8 MPa 118.7 MPa 233.4 MPa 38.7 MPa
The strain rosette shown in the figure was used to obtain normal strain data at a point on the free surface of a machine component. Determine the principle stress op -148 MPa 95.8 MPa 118.7 MPa 233.4 MPa 38.7 MPa
Will rate.
P13.067 The strain rosette shown was used to obtain normal strain data at a point on the free surface of a machine component. Given the values Ea = eb -165 ?? , ec- 130 ?? , E = 10,200 ksi, and v = 0.33, determine -170 ?? , (a) the stress components Ox , ? ? , and Txy at the point (b) the principal stresses and the maximum in-plane shear stress at the point; on paper, show...
Please work the problem out rather than copying someone else's
answer. The other post's answer was wrong and I don't understand
this practice problem
The strain rosette was used to obtain normal strain data at a point on the free surface of a machine part. The measurement are -1110 με. Poisson's ratio for this material is v 0.34. 1290 με, eb-2210 με, and Ec (a) Determine the strain components Ex, £y, (b) Determine the principal strains and the maximum in-plane...
The strain rosette shown was
used to obtain normal strain data at a point on the free surface of
a machine component. Given the values εa= -185 με, εb= -150 με, εc=
55 με, E = 10,800 ksi, and v = 0.33,
determine
(a) the stress components σx, σy, and τxy at the point.
(b) the principal stresses and the maximum in-plane shear stress at
the point; on paper, show these stresses on an appropriate sketch
that indicates the orientation...
A rosette strain gage is an electromechanical device that can measure relative surface elongations in three directions. Bonding such a device to the surface of a structure allows determination of elongational strains in particular directions. A schematic of one such gage is shown in the following figure, and the output of the device will provide data on the strains along the gage arms a, b, and c. During one application, it is found that ea = 0.001, ep = 0.002,...
Question 4 - (25 marks) 4a) The 60° strain rosette, shown in Figure 6, -is mounted on a beam. The following readings are obtained from each gauge: Ea= 250 u ; Eb= -400 u ; Ec= 280 u Determine:- (9) i. The in-plane principal strains and their orientation, and ii. The maximum in-plane shear strain and the average normal strain. of the principal plane. (6) b a 60° 60° 60°