VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS
VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS
12th Edition
ISBN: 9781260265453
Author: BEER
Publisher: MCG
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Chapter 4.1, Problem 4.24P

(a)

To determine

The reaction at A and B of the plate shown in P4.24(a).

(a)

Expert Solution
Check Mark

Answer to Problem 4.24P

The reaction at A is 20.0lb and reaction at B is 50.0lb and is directed along 36.9° above negative x axis in the upward direction.

Explanation of Solution

Take vectors along positive x and y axis are positive.

Let A is the reaction at the point A , B is the reaction at the point B and Bx and By are the component of the reaction B.

The free body diagram is sketched below as figure 1.

VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS, Chapter 4.1, Problem 4.24P , additional homework tip  1

Here, Bx and By are the magnitude of x and y component of reaction B at the point A and B is the magnitude of reaction B.

Write the expression for the moment at B.

MB=F×D (I)

Here, MB is the net moment at B, F is the force, and D is the perpendicular distance between the B and the point where force is experienced.

Above equation implies that net moment at any point is the sum of product of each force acting on the system and perpendicular distance of the force and the point.

The moment at B is due to the reaction A and forces 50lb and 40lb.

Thus, the complete expression of MB is

MB=A(20in.)+(50lb)(16in.)(40lb)(10in.) (II)

Here, MB is the sum of all anticlockwise moment of force at A.

At equilibrium, the sum of the moment acting at A will be zero

MB=A(20in.)+(50lb)(16in.)(40lb)(10in.)=0 (III)

Write the expression for the net force along the x direction.

Fx=Bx+40lb (IV)

Here, Fx is the sum of all force along the x direction.

At equilibrium, the net force along the x direction will be zero.

Fx=Bx+40lb=0 (V)

Write the expression for the net force along the y direction.

Fy=By+A50lb=0 (VI)

Here, Fy is the sum of all force along the y direction.

At equilibrium, the net force along the y direction will be zero.

Fy=By+A50lb=0 (VII)

Let α be the angle that B makes with x axis.

Write the expression for the magnitude of net reaction at B.

B=Bx2+By2 (VIII)

Here, B is the magnitude of net reaction at point B.

Therefore, write the expression for the tanα.

tanα=ByBx (IX)

Calculation:

Rearrange equation (III) to get B.

A(20in.)+(50lb)(16in.)(40lb)(10in.)=0A=+20lb

From figure 1, the reaction A acts in the upward direction.

Rearrange equation (V) to get Bx .

Bx=40lb

The x component of reaction acts in the x direction.

Rearrange equation (VII) to get By.

By=50lbA

Substitute 20.0lb for A in above equation to get By.

By=50lb20.0lb=30.0lb

Substitute 40lb for Bx and 30.0lb for By in the equation (VIII) to get B.

B=(40lb)2+(30lb)2=50.0lb

Substitute 40lb for Bx and 30.0lb for By in the equation (IX) to get α.

tanα=30.0lb40.0lbα=36.9°

Therefore, the reaction at A is 20.0lb and reaction at B is 50.0lb and is directed along 36.9° above negative x axis in the upward direction.

(b)

To determine

The reaction at A and B of the plate shown in P4.23(b).

(b)

Expert Solution
Check Mark

Answer to Problem 4.24P

The reaction at A is 23.1lb and is directed 60.0° above positive x axis and reaction at B is 59.6lb and is directed 30.2° above negative x axis.

Explanation of Solution

Take vectors along positive x and y axis are positive.

Let A is the reaction at the point A , B is the reaction at the point B and Bx and By are the component of the reaction B.

The free body diagram is sketched below as figure 1.

VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS, Chapter 4.1, Problem 4.24P , additional homework tip  2

Here, Bx and By are the magnitude of x and y component of reaction B at the point A and B is the magnitude of reaction B.

Write the expression for the moment at B.

MB=F×D (I)

Here, MB is the net moment at B, F is the force, and D is the perpendicular distance between the B and the point where force is experienced.

Above equation implies that net moment at any point is the sum of product of each force acting on the system and perpendicular distance of the force and the point.

The moment at B is due to the y component of reaction A and forces 50lb and 40lb.

Thus, the complete expression of MB is

MB=(Acos30°)(20in.)+(50lb)(16in.)(40lb)(10in.) (II)

Here, MB is the sum of all anticlockwise moment of force at A.

At equilibrium, the sum of the moment acting at A will be zero

MB=(Acos30°)(20in.)+(50lb)(16in.)(40lb)(10in.)=0 (III)

Write the expression for the net force along the x direction.

Fx=Asin30°+Bx+40lb (IV)

Here, Fx is the sum of all force along the x direction.

At equilibrium, the net force along the x direction will be zero.

Fx=Asin30°+Bx+40lb=0 (V)

Write the expression for the net force along the y direction.

Fy=By+Acos30°50lb (VI)

Here, Fy is the sum of all force along the y direction.

At equilibrium, the net force along the y direction will be zero.

Fy=By+Acos30°50lb=0 (VII)

Let α be the angle that B makes with x axis.

Write the expression for the magnitude of net reaction at B.

B=Bx2+By2 (VIII)

Here, B is the magnitude of net reaction at point B.

Therefore, write the expression for the tanα.

tanα=ByBx (IX)

Calculation:

Rearrange equation (III) to get B.

(Acos30°)(20in.)+(50lb)(16in.)(40lb)(10in.)=0A=23.1lb

From figure 1, the reaction A is directed at 60° above positive x axis

Rearrange equation (V) to get Bx .

Bx=40lbAsin30°

Substitute 23.09lb for A in above equation to get Bx.

Bx=40lb(23.09lb)sin30°=51.55lb

The x component of reaction B acts in the x direction.

Rearrange equation (VII) to get By.

By=50lbAcos30°

Substitute 23.09lb for A in above equation to get By.

By=50lb(23.09lb)cos30°=30lb

Substitute 51.55lb for Bx and 30lb for By in the equation (VIII) to get B.

B=(51.55lb)2+(30lb)2=59.64lb

Substitute 51.55lb for Bx and 30lb for By in the equation (IX) to get α.

tanα=30lb51.55lbα=30.2°

Therefore, the reaction at A is 23.1lb and is directed 60.0° above positive x axis and reaction at B is 59.6lb and is directed 30.2° above negative x axis.

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Chapter 4 Solutions

VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS

Ch. 4.1 - A hand truck is used to move a compressed-air...Ch. 4.1 - Two external shafts of a gearbox are subject to...Ch. 4.1 - Three loads are applied as shown to a light beam...Ch. 4.1 - The 10-m beam AB rests upon, but is not attached...Ch. 4.1 - The maximum allowable value of each of the...Ch. 4.1 - For the beam of Sample Prob. 4.2, determine the...Ch. 4.1 - The maximum allowable value of each of the...Ch. 4.1 - For the beam and loading shown, determine the...Ch. 4.1 - PROBLEM 4.15 The required tension in cable AB is...Ch. 4.1 - PROBLEM 4.16 Determine the maximum tension that...Ch. 4.1 - Two links AB and DE are connected by a bell crank...Ch. 4.1 - Two links AB and DE are connected by a bell crank...Ch. 4.1 - The bracket BCD is hinged at C and attached to a...Ch. 4.1 - The ladder AB, of length L and weight W, can be...Ch. 4.1 - The ladder AB, of length L and weight W, can be...Ch. 4.1 - A lever AB is hinged at C and attached to a...Ch. 4.1 - 4.23 and 4.24 For each of the plates and loadings...Ch. 4.1 - Prob. 4.24PCh. 4.1 - A rod AB, hinged at A and attached at B to cable...Ch. 4.1 - Prob. 4.26PCh. 4.1 - For the frame and loading shown, determine the...Ch. 4.1 - Determine the reactions at A and C when (a) = 0,...Ch. 4.1 - The spanner shown is used to rotate a shaft. 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