A tapered thin-wall circular shaft has constant wall thickness, t, length L, and diameters linearly varying between dA at the support A(x=0) and dB at its free end B(x=L). The shaft is homogeneous with shear modulus G

HW6_1A : 20.0 POINTS

Obtain a symbolic expression for the torsional stiffness of the shaft KT=Q/Φ, in terms of t, L, G, dA (you will have factors of π in your answers: enter π as "pi" ):
KT=
unanswered

HW6_1B : 20.0 POINTS

Obtain a symbolic expression for the maximum shear strain on the generic x-section along the shaft, γmax(x), in terms of t, L, G, Q, x, dA (you will have factors of π in your answers: enter π as "pi" ):

γmax(x)=
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HW6_1CX : 0.0 POINTS

CHALLENGE QUESTION! (no points, just for fun!)
This challenge question is just for fun: it gives you no points, so you do not NEED to get the right solution. Indeed it is not even graded.

For L=0.5 m, t=2 mm, dA=4 cm, and G=70 GPa, obtain the torque Q0 that you need to apply to the shaft if you want to obtain a maximum value of 2% strain.

Then, use these values to plot γmax(x) by writing MATLAB code in the blank command window below. If you succeed, take a screenshot of your plot (NOT THE CODE) and post it in the discussion forum under the "Gamma- Challenge!" thread.

Note: be careful when you write your expression for γmax(x) in MATLAB. Remember that element-wise division needs the period, so if you need to define a vector y = 1/x where you want to obtain each element of y as the inverse of the corresponding element of x, you need to define y as: y = 1./x

22/7*pi*t*G/L

Help with the rest?

gamma= r*Q/(L*Kt)

tapered thin-wall circular shaft has constant wall thickness, t, length L, and diameters linearly varying between dA at the support A(x=0) and dB at its free end B(x=L). The shaft is homogeneous with shear modulus G

HW6_1A : 20.0 POINTS

Obtain a symbolic expression for the torsional stiffness of the shaft KT=Q/Φ, in terms of t, L, G, dA (you will have factors of π in your answers: enter π as "pi" ):
KT=
unanswered

HW6_1B : 20.0 POINTS

Obtain a symbolic expression for the maximum shear strain on the generic x-section along the shaft, γmax(x), in terms of t, L, G, Q, x, dA (you will have factors of π in your answers: enter π as "pi" ):

γmax(x)=
unanswered

HW6_1CX : 0.0 POINTS

CHALLENGE QUESTION! (no points, just for fun!)
This challenge question is just for fun: it gives you no points, so you do not NEED to get the right solution. Indeed it is not even graded.

For L=0.5 m, t=2 mm, dA=4 cm, and G=70 GPa, obtain the torque Q0 that you need to apply to the shaft if you want to obtain a maximum value of 2% strain.

Then, use these values to plot γmax(x) by writing MATLAB code in the blank command window below. If you succeed, take a screenshot of your plot (NOT THE CODE) and post it in the discussion forum under the "Gamma- Challenge!" thread.

Note: be careful when you write your expression for γmax(x) in MATLAB. Remember that element-wise division needs the period, so if you need to define a vector y = 1/x where you want to obtain each element of y as the inverse of the corresponding element of x, you need to define y as: y = 1./x

1
None
UnansweredUnsubmitted

HW6_2: SOLID COMPOSITE SHAFT SUBJECTED TO DISTRIBUTED TORQUE

A composite shaft of length L is constructed from an inner core of radius R and modulus Gc=5G0, and a sleeve of outer radius 2√R and modulus Gs=G0, bonded together. One end of the shaft, B, is fixed and the other, A, is free to rotate as shown in the figure. A uniform distributed torque, tx(x)=t0 (t0 = constant with units of N⋅m/m), is applied to the shaft in the direction shown in the figure.

Obtain symbolic expressions in terms of R0, G0, L, t0, x for the following quantities.

(NOTE: you will have factors of π in your answers: enter π as "pi".)

HW6_2A : 10.0 POINTS

The axial torque resultant:
T(x)=
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HW6_2B : 10.0 POINTS

The rotation field φ(x) along the shaft:
φ(x)=
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HW6_2C : 10.0 POINTS

The angle of twist:
ΦAB=
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HW6_2D : 10.0 POINTS

The maximum magnitude of shear stress, τmax, in the shaft:
τmax=
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HW6_3: STATICALLY INDETERMINATE SHAFT UNDER DISTRIBUTED LOADING

The round shaft in the figure has length L and is fixed at both ends. The shaft is loaded by a constant distributed torque t0. The modulus of the material, G, and the polar moment of inertia of the cross section, Ip, are known.

HW6_3 : 40.0 POINTS

If we want to limit the rotation of the midsection of the shaft to a maximum value, φ(L2)=φm, what is the maximum value of the distributed load, t0,m, that can be applied to the shaft?

Provide your answer as a symbolic expression in terms of L, G, Ip, φm (write as "I_p" and "phi_m"):

t0,m=
unanswered
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HW6_1A : 2*d_A^3*pi*t*G/(3*L )

6.1B, 6.1C, 6_2a to 6_2d, 6_3

6_2A= -t_0*x

6_2B= -t_0*(x^2-L^2)/(8*pi*G_0*R^4)
6_2C= -L^2*t_0/(8*pi*G_0*R^4)
6_2D= 5*t_0*L/(4*pi*R^3)
6_3= 8*psi*G*I_o/(L^2)
i need 6_1B

6_3 = 8*phi_m*G*I_p/(L^2)

anyone has hw6_1B answer?

HW6_1B: (2*Q*L^2)/(G*pi*t*d_A^2*(L+x)^2)

Why? You have to start by describing the linear function of diameter/radius variations (whatever)

r(x)=(d_A/2L)*x+d_A/2
d_A(x)=(d_A/L)*x+d_A

We can obtain

I(x)=pi*t*d_A^3*(x+L)^3/(4*L^3)

We know that

gamma=r(x)*(d_Phi/d_x)

and

d_Phi/d_x)=T(x)/(G*I)_eff(x)

and

(G*I)_eff(x)=G*I(x)