Asked by helpless
Tapered bar with end load
The small tapered bar BC has length L=0.1 m and is made of a homogeneous material with Young’s modulus E=10 GPa. The cross sectional area of the bar is slowly varying between A0=160 mm^2 (at B) and A0/2 (at C), as described by the function:
A(x)=A0/(1+(x/L))
The bar is fixed at B and a load P=8kN is applied at the free end C. Determine the total elongation, δ, of the bar. (in mm)
The small tapered bar BC has length L=0.1 m and is made of a homogeneous material with Young’s modulus E=10 GPa. The cross sectional area of the bar is slowly varying between A0=160 mm^2 (at B) and A0/2 (at C), as described by the function:
A(x)=A0/(1+(x/L))
The bar is fixed at B and a load P=8kN is applied at the free end C. Determine the total elongation, δ, of the bar. (in mm)
Answers
Answered by
FLu
-0.71 mm
Problem 3) 184 MPA
Anyone for Problem 1 and 2 please?
Problem 3) 184 MPA
Anyone for Problem 1 and 2 please?
Answered by
Mag
Thanks FLu!
Yes, Problem 1+2 please?
Yes, Problem 1+2 please?
Answered by
Ortum
Great thanks!
Problem 1 and 2 please?
Problem 1 and 2 please?
Answered by
RORO
-0.71 mm is bad answer
Answered by
Anonymous
RORO, it worked for me, there must be tolerance, try -0.73 and let me know if it work?
Do you have problem 1 and 2?
Do you have problem 1 and 2?
Answered by
FLu
Yes, must have something to do with tolerance RORO, try -0.73, there was technical issue before.
RORO did you get problem 1 and 2 please?
RORO did you get problem 1 and 2 please?
Answered by
Saga
Anyone for problem 1&2?
Answered by
RORO
Ok, thanks. No, I hav not solution for 1 and 2!
Answered by
Nura
Anyone Problem 1 and 2 please?
Answered by
mehwish
anybody have the solution of problem 1 and 2?
Answered by
Any
Anyone please?
Answered by
Anonymous
Pretty please with sugar on top?
Answered by
Flaminuous
Yes, as this wannabe Anonymous sais, please help with glucose on top!
Answered by
Anonymous
I figured out the first answer, it was very simple, just had to multiplicate density(kg/m^2) x area(m^2) x gravity(m/s^2)= (kg m/s^2)= (N)
So:fx(x)=rho_1*g*A
I don't understand why f depends on x
So:fx(x)=rho_1*g*A
I don't understand why f depends on x
Answered by
FLu
Anonymous, tried it out but it says rho_1 not allowed in answer. How did you manage?
Answered by
Saga
rho_1 not permitted, please help!
Answered by
Hura
same problem!
Answered by
Nyu
Problem 1 and 2 please?
Answered by
Anonymous
The first answer for the first exercise should be: rho_1*g*A
Try typing it, not copy/paste.
rho_1 isn't allowed for L/2 to L
Try typing it, not copy/paste.
rho_1 isn't allowed for L/2 to L
Answered by
FLu
Thanks Anonymous now it worked.
Have you had luck with Problem 2?
Have you had luck with Problem 2?
Answered by
RORO
fx(x)=rho_2*g*A for L/2 to L
Answered by
FLu
Thanks RORO, any luck with the second Problem set?
Answered by
Mag
THanks guys, anybody managed other problem in 1 and 2?
Answered by
mehwish
I cannot understand the solution of f(x)=rho_1*g*A plz give the two words of question as a hints
Answered by
mehwish
I cannot understand the solution of f(x)=rho_1*g*A plz give the two words of question as a hints
Answered by
Neon
Anybody had luck with other problem 1 and 2 please?
Answered by
F10
If you don't understand the solution then you have to read the exercises at least.
Answered by
Neon
F10 is right. DO you have managed Problem 1 or 2 F10?
Answered by
faryia
I read but I don't understand because some guys talking on one question and some guys talking on other question at the same time.
Answered by
But
Anyone for Problem 1 and 2 please?
Answered by
mono
Rotating blade (body force in axial loading)
A blade is fixed to a rigid rotor of radius R spinning at ω rad/sec around the vertical z-axis (see figure). Neglect the effects of gravity.
4.
5.Calculate the peak stress in the blade: σmaxn
6.Calculate the blade elongation: δ
7.Calculate the displacement of the blade mid-section: ux(L/2)
8.Given:
9.Young's modulus, E , mass density, ρ .
· Constant cross sectional area, A
· Rotor radius R , blade length L
· Angular velocity ω
(Hint: if you work in the non-inertial frame of the rotating blade, the d'Alembert force/unit volume is ρω2r along the +x direction)
1. Try it:
2. σmaxn=
3.
4. unanswered
5.
6.
7.
8.
1.
2. Try it:
3. δ=
4.
5. unanswered
6.
7.
8.
9.
1.
2. Try it:
3. ux(L/2)=
4.
5. unanswered
6.
7.
8.
A blade is fixed to a rigid rotor of radius R spinning at ω rad/sec around the vertical z-axis (see figure). Neglect the effects of gravity.
Calculate the peak stress in the blade: σmaxn
Calculate the blade elongation: δ
Calculate the displacement of the blade mid-section: ux(L/2)
Given:
Young's modulus, E , mass density, ρ .
· Constant cross sectional area, A
· Rotor radius R , blade length L
· Angular velocity ω
(Hint: if you work in the non-inertial frame of the rotating blade, the d'Alembert force/unit volume is ρω2r along the +x direction)
plzzzzzzzzzzzzzzzz help.
A blade is fixed to a rigid rotor of radius R spinning at ω rad/sec around the vertical z-axis (see figure). Neglect the effects of gravity.
4.
5.Calculate the peak stress in the blade: σmaxn
6.Calculate the blade elongation: δ
7.Calculate the displacement of the blade mid-section: ux(L/2)
8.Given:
9.Young's modulus, E , mass density, ρ .
· Constant cross sectional area, A
· Rotor radius R , blade length L
· Angular velocity ω
(Hint: if you work in the non-inertial frame of the rotating blade, the d'Alembert force/unit volume is ρω2r along the +x direction)
1. Try it:
2. σmaxn=
3.
4. unanswered
5.
6.
7.
8.
1.
2. Try it:
3. δ=
4.
5. unanswered
6.
7.
8.
9.
1.
2. Try it:
3. ux(L/2)=
4.
5. unanswered
6.
7.
8.
A blade is fixed to a rigid rotor of radius R spinning at ω rad/sec around the vertical z-axis (see figure). Neglect the effects of gravity.
Calculate the peak stress in the blade: σmaxn
Calculate the blade elongation: δ
Calculate the displacement of the blade mid-section: ux(L/2)
Given:
Young's modulus, E , mass density, ρ .
· Constant cross sectional area, A
· Rotor radius R , blade length L
· Angular velocity ω
(Hint: if you work in the non-inertial frame of the rotating blade, the d'Alembert force/unit volume is ρω2r along the +x direction)
plzzzzzzzzzzzzzzzz help.
Answered by
Hta
Problem 1 and 2?
Answered by
Gaby
Please 1 and 2?
Answered by
Byrta
ANy further Problem 1 and 2 answers?
Answered by
FLu
No, sorry was not succesful, any other had chance with problems 1 and 2?
Answered by
Bart
Please other Problem 1 & 2!
Answered by
Deas
Other problems in 1 and 2 please?
Answered by
Magnum
Help problem 1 and 2?
Answered by
bei
Given the displacement field, find the loading (inverse problem)
The composite bar is composed of an inner core of cross sectional area A and a sleeve of cross sectional area . The Young's modulus of the sleeve is and the modulus of the core is . Under the effects of unknown distributed loading, , the bar is observed to deform. The measured displacement field in the bar is , where is a dimensional constant and is the length of the bar. The origin of the x-axis is at the fixed support,10M . The maximum magnitude (absolute value) of stress in the core is found to be Pa.
plz help
The composite bar is composed of an inner core of cross sectional area A and a sleeve of cross sectional area . The Young's modulus of the sleeve is and the modulus of the core is . Under the effects of unknown distributed loading, , the bar is observed to deform. The measured displacement field in the bar is , where is a dimensional constant and is the length of the bar. The origin of the x-axis is at the fixed support,10M . The maximum magnitude (absolute value) of stress in the core is found to be Pa.
plz help
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