Two blocks of masses m 1 and m 2 , are placed on a table in contact with each other as discussed in Example 5.7 and shown in Figure 5.13a. The coefficient of kinetic friction between the block of mass m 1 and the table is μ 1 , and that between the block of mass m 2 and the table is μ 2 . A horizontal force of magnitude F is applied to the block of mass m 1 . We wish to find P , the magnitude of the contact force between the blocks. (a) Draw diagrams showing the forces for each block. (b) What is the net force on the system of two blocks? (c) What is the net force acting on m 1 ? (d) What is the net force acting on m 2 ? (e) Write Newton’s second law in the x direction for each block. (f) Solve the two equations in two unknowns for the acceleration a of the blocks in terms of the masses, the applied force F , the coefficients of friction, and g . (g) Find the magnitude P of the contact force between the blocks in terms of the same quantities.
Two blocks of masses m 1 and m 2 , are placed on a table in contact with each other as discussed in Example 5.7 and shown in Figure 5.13a. The coefficient of kinetic friction between the block of mass m 1 and the table is μ 1 , and that between the block of mass m 2 and the table is μ 2 . A horizontal force of magnitude F is applied to the block of mass m 1 . We wish to find P , the magnitude of the contact force between the blocks. (a) Draw diagrams showing the forces for each block. (b) What is the net force on the system of two blocks? (c) What is the net force acting on m 1 ? (d) What is the net force acting on m 2 ? (e) Write Newton’s second law in the x direction for each block. (f) Solve the two equations in two unknowns for the acceleration a of the blocks in terms of the masses, the applied force F , the coefficients of friction, and g . (g) Find the magnitude P of the contact force between the blocks in terms of the same quantities.
Two blocks of masses m1 and m2, are placed on a table in contact with each other as discussed in Example 5.7 and shown in Figure 5.13a. The coefficient of kinetic friction between the block of mass m1 and the table is μ1, and that between the block of mass m2 and the table is μ2. A horizontal force of magnitude F is applied to the block of mass m1. We wish to find P, the magnitude of the contact force between the blocks. (a) Draw diagrams showing the forces for each block. (b) What is the net force on the system of two blocks? (c) What is the net force acting on m1? (d) What is the net force acting on m2? (e) Write Newton’s second law in the x direction for each block. (f) Solve the two equations in two unknowns for the acceleration a of the blocks in terms of the masses, the applied force F, the coefficients of friction, and g. (g) Find the magnitude P of the contact force between the blocks in terms of the same quantities.
(a)
Expert Solution
To determine
The free body diagram of each block with forces.
The free body diagram of an object represents the direction and magnitude of forces acting on the body.
Explanation of Solution
The mass of block 1 is m1, the mass of block 2 is m2, the coefficient of kinetic friction between m1 and the table is μ1, the coefficient of kinetic friction between m2 and the table is μ2 and the magnitude of horizontal force is F.
The free body diagram of the book is given below.
Figure (1)
The sum of all vertical forces is zero because the block moves on a horizontal surface. So the vertical acceleration, ay=0.
Write the net force in the y-direction for mass m1 using Newton’s law
∑F1y=m1ay−m1g+n1=0n1=m1g
Here, F1y is the vertical force of block 1, ay is the acceleration in the y-direction, n1 is the normal force of block 1 and g is the acceleration due to gravity.
Write the net force in the y-direction for mass m2 using Newton’s law
∑F2y=m2ay−m2g+n2=0n2=m2g
Here, F2y is the vertical force of block 2 and n2 is the normal force of block 2.
Write the equation for kinetic friction for block 1
f1=μ1n1=μ1m1g
Here, f1 is the frictional force due to mass m1.
Write the equation for kinetic friction for block 2
f2=μ2n2=μ2m2g
Here, f2 is the frictional force due to mass m2.
In the figure, P→ is the contact force that arises due to the contact between m1 and m2.
Conclusion:
Therefore, the free body diagram of each block to show the forces is given in figure I.
(b)
Expert Solution
To determine
The net force on the system of two blocks.
Answer to Problem 5.79AP
The net force on the system of two blocks is the external force applied minus the frictional force.
Explanation of Solution
Write the expression for the net force in x-direction for the system of two blocks from the figure I,
∑F=F−f1−f2+P−P=F−f1−f2
Here, ∑F is the net force on the system of two blocks.
Conclusion:
Therefore, the net force on the system of two blocks is the external force applied minus the frictional force.
(c)
Expert Solution
To determine
The net force acting on m1.
Answer to Problem 5.79AP
The net force acting on m1 is F−f1−P.
Explanation of Solution
Write the expression for the net force in x-direction for the system of two blocks from the figure I,
∑F1x=F−f1−P
Here, ∑F1x is the net force on the block of mass m1 .
Conclusion:
Therefore, the net force acting on m1 is F−f1−P.
(d)
Expert Solution
To determine
The net force acting on m2.
Answer to Problem 5.79AP
The net force acting on m2 is P−f2.
Explanation of Solution
Write the expression for the net force in x-direction for the system of two blocks from the figure I,
∑F2x=−f2+P=P−f2
Here, ∑F2x is the net force on the block of mass m2 .
Conclusion:
Therefore, the net force acting on m2 is P−f2.
(e)
Expert Solution
To determine
The Newton’s second law in the x direction for each block.
Answer to Problem 5.79AP
The Newton’s second law in the x direction, for m1 is F−P=m1a and for m2 is P=m2a.
Explanation of Solution
The block has on a horizontal acceleration ax=a.
Write the Newton’s second law for block 1
∑F1x=m1ax
Substitute F−f1−P for ∑F1x in the above equation
F−f1−P=m1a
Substitute μ1m1g for f1 in the above equation
F−μ1m1g−P=m1a
Write the Newton’s second law for block 2
∑F2x=m2ax
Substitute P−f2 for ∑F2x in the above equation
P−f2=m2a
Substitute μ2m2g for f2 in the above equation
P−μ2m2g=m2a
Conclusion:
Therefore, the Newton’s second law in the x direction, for m1 is F−μ1m1g−P=m1a and for m2 is P−μ2m2g=m2a.
(f)
Expert Solution
To determine
The acceleration of the blocks.
Answer to Problem 5.79AP
The acceleration of the blocks is (F−μ1m1g−μ2m2gm1+m2).
Explanation of Solution
Write the Newton’s second law is for block 1
F−P−μ1m1g=m1a (I)
Write the Newton’s second law is for block 2
P−μ2m2g=m2a (II)
Conclusion:
Add the equation (I) and equation (II) and solve for a.
F−P−μ1m1g+P−μ2m2g=m1a+m2aa=(F−μ1m1g−μ2m2gm1+m2)
Therefore, the acceleration of the blocks is (F−μ1m1g−μ2m2gm1+m2).
(g)
Expert Solution
To determine
The magnitude of the contact force between the blocks in terms of acceleration, mass, applied force and the friction coefficient.
Answer to Problem 5.79AP
The magnitude P of the contact force between the blocks is (m2m1+m2)(F+(μ2−μ1)m1g).
Explanation of Solution
Recall the equation (II).
P−μ2m2g=m2aP=μ2m2g+m2a
Substitute (F−μ1m1g−μ2m2gm1+m2) for a in above expression.
14
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In figure, a closed surface with q=b=
0.4m/
C =
0.6m
if the left edge
of the closed surface at position X=a,
if E is non-uniform and is given by
€ = (3 + 2x²) ŷ N/C, calculate the
(3+2x²)
net electric flux leaving the closed
surface.
No chatgpt pls will upvote
suggest a reason ultrasound cleaning is better than cleaning by hand?
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