Learning Goal:The crate shown is held against wedge B by a spring. The spring is 95.5% of its originaluncompressed length 1=2.50 m, and the spring constant is given as k = 1650 N/mThe coefficient of static friction at all contacting surfaces is 0.100. The mass of thecrate is m=21.0 kg. The angle is 0 = 14.0° Neglect the mass of the wedge. Assumethe crate only moves in the y direction and that wedge A cannot move. (Figure 1)B7xDetermine the normal force Nc that the crate exerts on the wedge when the system is at rest.Express your answer to three significant figures and include the appropriate unitsDetermine the magnitude of the smallest horizontal force P that is necessary to begin moving the crate upward.Express your answer to three significant figures and include the appropriate units.

First, we need to calculate the compression of the spring. The spring is 95.5% of its original…

Answered: Learning Goal: The crate shown is held…

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

See similar textbooks

Similar questions

WA 4-m bar of negligible weight rests in a horizontal position on the smooth planes shown in Figure. Compute the distance x at which load T = 10 KN should be place from point B to keep the bar horizontal. * 1m P = 20 kN 30° 450 4 m 1.61 m O None of the above O 4.83 m О 3.00 m 1.00 m
The 440-N force is applied to the 91-kg block, which is stationary before the force is applied. Determine the magnitude and direction of the friction force F exerted by the horizontal surface on the block. The force is positive if to the right, negative if to the left. H₂ = 0.64 M = 0.41 Answer: F= i 30° N P = 440 N
For the beam and loading shown, determine the magnitude of the deflection at point C. The length of the beam, L, is 1,000 mm. The moment, M, is 55 kN·m. The flexural rigidity, EI, is 4.5X108 kN·mm2.
None
Consider a 3 metre long uniform beam with flexural rigidity of 100 kNm². The beam is supported with a fixed (clamped) support on the left, and a roller support 1 metre from the right hand side. 3m 2m A 1kN/m point load is applied 1 metre from the left hand side. If we find the deflection for this beam, using the boundary conditions for the fixed (clamped) end and for the roller support, we get the equation. y(z) 9600 ((16³-48x² +48r - 16) H(r− 1) - 112³ +18r²) (you do not need to calculate this yourself, but you may verify it if you wish) Have Desmos (or any other computer graphing system you like) draw a picture of the beam under load. Make sure the picture is accurate, and is zoomed appropriately to see the actual bends in the curve. What is wrong with the deflection function to the right of the roller support? b) Solve the deflection for this beam in two parts, as if there were two separate beams: 3m Om 2m 2m For the roller support use the following boundary conditions: y (2)= 0 and…
The block A and the wedge B weighs 100 kN and 40 kN, respectively. The coefficient of fritction for all contacting surfaces is µ = 0.268. Determine the following: a. What value of P in kN would be required to push to the right the wedge under the block? b. What value of P in kN would be required to pull to the left the wedge under the block? Assume the block A is stll in contact with the wall just as motion starts.
Dont forget to draw the FREE BODY DIAGRAMS ALSO PLEASE! (:
6/47 A block of mass mo is placed between the vertical wall and the upper end A of the uniform slender bar of mass m. If the coefficient of static friction is µg be- tween the block and the wall and also between the block and the bar, determine a general expression for the minimum value 0min Oof the angle 0 for which the block will remain in equilibrium. Evaluate your expression for the conditions µ = 0.5 and %3D т (a) mo 0.1, m (b) mo 1, and m (c) mo 10. %3D For each case, state the minimum coefficient of sta- tic friction (u)B necessary to prevent slippage at B. Ans. (a) 0min = 61.2°, (µ,)B = 1.667 (unusual!) (b) 0min = 45°, (µ)B = 0.667 (c) 0min = 10.30°, (µ,)B = 0.0952 %3D %3D %3D %3D %3D mo m (Ha)B Problem 6/47
Friction-static and rigid bodies DRAW YOUR OWN FIGURE.
Solve the problem using BELT FRICTION.

Recommended textbooks for you

Structural Analysis

Civil Engineering

ISBN:

9781337630931

Author:

KASSIMALI, Aslam.

Publisher:

Cengage,

Structural Analysis (10th Edition)

Civil Engineering

ISBN:

9780134610672

Author:

Russell C. Hibbeler

Publisher:

PEARSON

Principles of Foundation Engineering (MindTap Cou…

Civil Engineering

ISBN:

9781337705028

Author:

Braja M. Das, Nagaratnam Sivakugan

Publisher:

Cengage Learning

Structural Analysis

Civil Engineering

ISBN:

9781337630931

Author:

KASSIMALI, Aslam.

Publisher:

Cengage,

Structural Analysis (10th Edition)

Civil Engineering

ISBN:

9780134610672

Author:

Russell C. Hibbeler

Publisher:

PEARSON

Principles of Foundation Engineering (MindTap Cou…

Civil Engineering

ISBN:

9781337705028

Author:

Braja M. Das, Nagaratnam Sivakugan

Publisher:

Cengage Learning

Fundamentals of Structural Analysis

Civil Engineering

ISBN:

9780073398006

Author:

Kenneth M. Leet Emeritus, Chia-Ming Uang, Joel Lanning

Publisher:

McGraw-Hill Education

Sustainable Energy

Civil Engineering

ISBN:

9781337551663

Author:

DUNLAP, Richard A.

Publisher:

Cengage,

Traffic and Highway Engineering

Civil Engineering

ISBN:

9781305156241

Author:

Garber, Nicholas J.

Publisher:

Cengage Learning

SEE MORE TEXTBOOKS