Determine the vertical force P that must be applied at G to maintain the equilibrium of the linkage. Fig. P10.101 and P10.102

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Answer 1

Textbook Question

Chapter 10, Problem 10.101RP

Determine the vertical force P that must be applied at G to maintain the equilibrium of the linkage.

Chapter 10, Problem 10.101RP, Determine the vertical force P that must be appliedat G to maintain the equilibrium of the linkage.

Fig. P10.101 and P10.102

Expert Solution & Answer

To determine

Find the vertical force P that should be applied at G for which the equilibrium is maintained.

Answer to Problem 10.101RP

The vertical force P required for the equilibrium is 60.0 lb(↓)_.

Explanation of Solution

Show the free-body diagram of the arrangement as in Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 10, Problem 10.101RP

Consider the vertical displacement at A as (δyA↓).

Find the vertical displacement (δyC) at C as follows;

8δyA=12δyCδyC=128δyAδyC=1.5δyA(↑)

Find the vertical displacement (δyE) at E as follows;

δyE=δyC=1.5δyA(↑)

Find the vertical displacement (δyD) at D as follows;

18δyD=6δyEδyD=186δyEδyD=3(1.5δyA)=4.5δyA(↑)

Find the vertical displacement (δyG) at G as follows;

18δyD=10δyGδyG=1018δyDδyG=1018(4.5δyA)=2.5δyA(↓)

Use the virtual work principle:

δU=0300δyA−100δyD+PδyG=0

Substitute 4.5δyA for δyD and 2.5δyA for δyG.

300δyA−100(4.5δyA)+P(2.5δyA)=0300−450+2.5P=02.5P=150P=60.0 lb(↓)

Therefore, the vertical force P required for the equilibrium is 60.0 lb(↓)_.

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Answer 2

Textbook Question

Chapter 10, Problem 10.101RP

Determine the vertical force P that must be applied at G to maintain the equilibrium of the linkage.

Chapter 10, Problem 10.101RP, Determine the vertical force P that must be appliedat G to maintain the equilibrium of the linkage.

Fig. P10.101 and P10.102

Expert Solution & Answer

To determine

Find the vertical force P that should be applied at G for which the equilibrium is maintained.

Answer to Problem 10.101RP

The vertical force P required for the equilibrium is 60.0 lb(↓)_.

Explanation of Solution

Show the free-body diagram of the arrangement as in Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 10, Problem 10.101RP

Consider the vertical displacement at A as (δyA↓).

Find the vertical displacement (δyC) at C as follows;

8δyA=12δyCδyC=128δyAδyC=1.5δyA(↑)

Find the vertical displacement (δyE) at E as follows;

δyE=δyC=1.5δyA(↑)

Find the vertical displacement (δyD) at D as follows;

18δyD=6δyEδyD=186δyEδyD=3(1.5δyA)=4.5δyA(↑)

Find the vertical displacement (δyG) at G as follows;

18δyD=10δyGδyG=1018δyDδyG=1018(4.5δyA)=2.5δyA(↓)

Use the virtual work principle:

δU=0300δyA−100δyD+PδyG=0

Substitute 4.5δyA for δyD and 2.5δyA for δyG.

300δyA−100(4.5δyA)+P(2.5δyA)=0300−450+2.5P=02.5P=150P=60.0 lb(↓)

Therefore, the vertical force P required for the equilibrium is 60.0 lb(↓)_.

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Answer 3

Textbook Question

Chapter 10, Problem 10.101RP

Determine the vertical force P that must be applied at G to maintain the equilibrium of the linkage.

Chapter 10, Problem 10.101RP, Determine the vertical force P that must be appliedat G to maintain the equilibrium of the linkage.

Fig. P10.101 and P10.102

Expert Solution & Answer

To determine

Find the vertical force P that should be applied at G for which the equilibrium is maintained.

Answer to Problem 10.101RP

The vertical force P required for the equilibrium is 60.0 lb(↓)_.

Explanation of Solution

Show the free-body diagram of the arrangement as in Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 10, Problem 10.101RP

Consider the vertical displacement at A as (δyA↓).

Find the vertical displacement (δyC) at C as follows;

8δyA=12δyCδyC=128δyAδyC=1.5δyA(↑)

Find the vertical displacement (δyE) at E as follows;

δyE=δyC=1.5δyA(↑)

Find the vertical displacement (δyD) at D as follows;

18δyD=6δyEδyD=186δyEδyD=3(1.5δyA)=4.5δyA(↑)

Find the vertical displacement (δyG) at G as follows;

18δyD=10δyGδyG=1018δyDδyG=1018(4.5δyA)=2.5δyA(↓)

Use the virtual work principle:

δU=0300δyA−100δyD+PδyG=0

Substitute 4.5δyA for δyD and 2.5δyA for δyG.

300δyA−100(4.5δyA)+P(2.5δyA)=0300−450+2.5P=02.5P=150P=60.0 lb(↓)

Therefore, the vertical force P required for the equilibrium is 60.0 lb(↓)_.

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Answer 4

Textbook Question

Chapter 10, Problem 10.101RP

Determine the vertical force P that must be applied at G to maintain the equilibrium of the linkage.

Chapter 10, Problem 10.101RP, Determine the vertical force P that must be appliedat G to maintain the equilibrium of the linkage.

Fig. P10.101 and P10.102

Expert Solution & Answer

To determine

Find the vertical force P that should be applied at G for which the equilibrium is maintained.

Answer to Problem 10.101RP

The vertical force P required for the equilibrium is 60.0 lb(↓)_.

Explanation of Solution

Show the free-body diagram of the arrangement as in Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 10, Problem 10.101RP

Consider the vertical displacement at A as (δyA↓).

Find the vertical displacement (δyC) at C as follows;

8δyA=12δyCδyC=128δyAδyC=1.5δyA(↑)

Find the vertical displacement (δyE) at E as follows;

δyE=δyC=1.5δyA(↑)

Find the vertical displacement (δyD) at D as follows;

18δyD=6δyEδyD=186δyEδyD=3(1.5δyA)=4.5δyA(↑)

Find the vertical displacement (δyG) at G as follows;

18δyD=10δyGδyG=1018δyDδyG=1018(4.5δyA)=2.5δyA(↓)

Use the virtual work principle:

δU=0300δyA−100δyD+PδyG=0

Substitute 4.5δyA for δyD and 2.5δyA for δyG.

300δyA−100(4.5δyA)+P(2.5δyA)=0300−450+2.5P=02.5P=150P=60.0 lb(↓)

Therefore, the vertical force P required for the equilibrium is 60.0 lb(↓)_.

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Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution & Answer

To determine

Find the vertical force P that should be applied at G for which the equilibrium is maintained.

Answer to Problem 10.101RP

The vertical force P required for the equilibrium is 60.0 lb(↓)_.

Explanation of Solution

Show the free-body diagram of the arrangement as in Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 10, Problem 10.101RP

Consider the vertical displacement at A as (δyA↓).

Find the vertical displacement (δyC) at C as follows;

8δyA=12δyCδyC=128δyAδyC=1.5δyA(↑)

Find the vertical displacement (δyE) at E as follows;

δyE=δyC=1.5δyA(↑)

Find the vertical displacement (δyD) at D as follows;

18δyD=6δyEδyD=186δyEδyD=3(1.5δyA)=4.5δyA(↑)

Find the vertical displacement (δyG) at G as follows;

18δyD=10δyGδyG=1018δyDδyG=1018(4.5δyA)=2.5δyA(↓)

Use the virtual work principle:

δU=0300δyA−100δyD+PδyG=0

Substitute 4.5δyA for δyD and 2.5δyA for δyG.

300δyA−100(4.5δyA)+P(2.5δyA)=0300−450+2.5P=02.5P=150P=60.0 lb(↓)

Therefore, the vertical force P required for the equilibrium is 60.0 lb(↓)_.

Answer 8

Expert Solution & Answer

To determine

Find the vertical force P that should be applied at G for which the equilibrium is maintained.

Answer to Problem 10.101RP

The vertical force P required for the equilibrium is 60.0 lb(↓)_.

Explanation of Solution

Show the free-body diagram of the arrangement as in Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 10, Problem 10.101RP

Consider the vertical displacement at A as (δyA↓).

Find the vertical displacement (δyC) at C as follows;

8δyA=12δyCδyC=128δyAδyC=1.5δyA(↑)

Find the vertical displacement (δyE) at E as follows;

δyE=δyC=1.5δyA(↑)

Find the vertical displacement (δyD) at D as follows;

18δyD=6δyEδyD=186δyEδyD=3(1.5δyA)=4.5δyA(↑)

Find the vertical displacement (δyG) at G as follows;

18δyD=10δyGδyG=1018δyDδyG=1018(4.5δyA)=2.5δyA(↓)

Use the virtual work principle:

δU=0300δyA−100δyD+PδyG=0

Substitute 4.5δyA for δyD and 2.5δyA for δyG.

300δyA−100(4.5δyA)+P(2.5δyA)=0300−450+2.5P=02.5P=150P=60.0 lb(↓)

Therefore, the vertical force P required for the equilibrium is 60.0 lb(↓)_.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

Find the vertical force P that should be applied at G for which the equilibrium is maintained.

Answer 12

Answer to Problem 10.101RP

The vertical force P required for the equilibrium is 60.0 lb(↓)_.

Answer 13

Explanation of Solution

Show the free-body diagram of the arrangement as in Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 10, Problem 10.101RP

Consider the vertical displacement at A as (δyA↓).

Find the vertical displacement (δyC) at C as follows;

8δyA=12δyCδyC=128δyAδyC=1.5δyA(↑)

Find the vertical displacement (δyE) at E as follows;

δyE=δyC=1.5δyA(↑)

Find the vertical displacement (δyD) at D as follows;

18δyD=6δyEδyD=186δyEδyD=3(1.5δyA)=4.5δyA(↑)

Find the vertical displacement (δyG) at G as follows;

18δyD=10δyGδyG=1018δyDδyG=1018(4.5δyA)=2.5δyA(↓)

Use the virtual work principle:

δU=0300δyA−100δyD+PδyG=0

Substitute 4.5δyA for δyD and 2.5δyA for δyG.

300δyA−100(4.5δyA)+P(2.5δyA)=0300−450+2.5P=02.5P=150P=60.0 lb(↓)

Therefore, the vertical force P required for the equilibrium is 60.0 lb(↓)_.

Answer 14

Ch. 10.1 - Determine the vertical force P that must be...Ch. 10.1 - Determine the horizontal force P that must be...Ch. 10.1 - Prob. 10.3P Ch. 10.1 - 10.3 and 10.4 Determine the couple M that must be...Ch. 10.1 - A spring of constant 15 kN/m connects points C and...Ch. 10.1 - A spring of constant 15 kN/m connects points C and...Ch. 10.1 - The two-bar linkage shown is supported by a pin...Ch. 10.1 - Determine the weight W that balances the 10-lb...Ch. 10.1 - Prob. 10.9P Ch. 10.1 - Prob. 10.10P

Determine the vertical force P that must be applied at G to maintain the equilibrium of the linkage. Fig. P10.101 and P10.102

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