Two blocks m1=8.1 kg and mass m2
are connected by a massless cord over a massless pulley as shown
below. the block of mass m2 is placed on a rough inclined surface
at an angle (theta = 55)
Two blocks my = 8.1 kg and mass m2 are connected by a massless cord over a massless pulley as shown below. The block of mass mz is placed on a rough inclined surface at an angle = 55°, and a force...
I need help on #1
1. The 20-N block A and the 30-N block B are supported by an incline that is held in the position shown. Knowing that the coefficient of static friction is 0.25 between the two blocks and zero between block B and the incline, determine the value of e for which motion is impending, 2. A 40-kg packing crate must be moved to the left along the floor without tipping. Knowing that the coefficient of static...
The force P is applied to the 67-kg block when it is at rest. Determine the magnitude and direction of the friction force exerted by the surface on the block if (a) P = 0, (b) P 185 N, and (c) P 296 N. (d) What value of P is required to initiate motion up the incline? The static and kinetic coefficients of friction between the block and the incline are us 0.17 and u 0.14 respectively. The friction force...
The force P is applied to the 49-kg block when it is at rest.
Determine the magnitude and direction of the friction force exerted
by the surface on the block if (a) P = 0, (b) P = 219 N, and (c) P
= 311 N. (d) What value of P is required to initiate motion up the
incline? The static and kinetic coefficients of friction between
the block and the incline are μs = 0.29 and μk = 0.25,...
4. A small block of mass $m_{1}=4 k g$ is placed at rest on a larger block of mass $m_{2}=6 \mathrm{kg}$. The coefficient of friction between the two block is $\mu=0.3 .$ And the horizontal surface is smooth. A constant force $\mathrm{F}$ is applied on the block.
The situation is given in the figure below.
a. Find the value of limiting friction between the two blocks.
b. What is the maximum acceleration by which the upper block can move
c....
The force P is applied to the 42-kg block when it is at rest. Determine the magnitude and direction of the friction force exerted by the surface on the block if (a) P = 0, (b) P = 124 N, and (c) P = 201 N. (d) What value of P is required to initiate motion up the incline? The static and kinetic coefficients of friction between the block and the incline are us = 0.18 and uk = 0.15,...
! Ju pomics JOVE Two blocks with masses m1 =2 kg and m2 =5.2 kg are connected by a massless string. A F= 42.2 N force is applied on meat angle = 14 above the horizontal as shown in the figure. If the coefficient of kinetic friction between each block and the surface Uk=0.1, determine the tension in the cord connecting my and m2. Take g=9.81 m/s2 and round your answer to 1 decimal place. 40.. m2 Mk
Problem 3 (20 points) In the following figure, a horizontal force F is applied to a large block of mass M with a massless pulley attached to it. While the block M is moving to the right, the other two blocks mi and m2 remain stationary problem relative to M. All surfaces are frictionless for this (a) Draw separate free body diagrams for M(including the massless pulley), mi, and m2 respectively. On the free body diagrams, please only draw and...
Save Answer QUESTION 10 points The given figure shows two blocks A and B of masses 200 and 300kg respectively. The blocks are joined by an inextensible cable. As the system was on rest; a force F-5430 N directed horizontally to the left is applied on block A Use the work and energy principles to determine the velocity of block A after it has moved 0.4m. Assume that the coefficient of kinetic friction between block A and the plane is...
As shown in Figure 3(a), a wooden block B with mass mg 2.4 kg on a rough inclined plane is connected to a massless spring (k 160 N/m) by a massless cord passing over a pulley P of radius R 0.25 m and mass M, 0.60 kg. The angle of the inclined plane is 0 37 and the coefficients of static and kinetic frictions are g 0.35 and A 0.30 respectively The frictional force at the axle of the pulley...