Five separate force-couple systems act at the corners of a piece of sheet metal that has been bent into the shape shown. Determine which of these systems is equivalent to a force F = (10 lb) i and a couple of moment M = (15 lb·ft) j + (15 lb·ft) k located at the origin.

Question

Want to see more full solutions like this?

Answer 1

Textbook Question

Chapter 3.4, Problem 3.104P

Five separate force-couple systems act at the corners of a piece of sheet metal that has been bent into the shape shown. Determine which of these systems is equivalent to a force F = (10 lb)i and a couple of moment M = (15 lb·ft)j + (15 lb·ft)k located at the origin.

Chapter 3.4, Problem 3.104P, Five separate force-couple systems act at the corners of a piece of sheet metal that has been bent

Expert Solution & Answer

To determine

Identify the system having force equivalent $F=(10 lb )i$ and moment equivalent $M=(15 lb⋅ft)j+((15 lb⋅ft))k$ at origin.

Answer to Problem 3.104P

System at corner D is the equivalent force-couple system.

Explanation of Solution

Take counterclockwise torques as positive quantities and clockwise torques as negative quantities.

Refer Figure P3.104.

There are five systems at corners A,D,I,F, and Among these, system at corner F cannot be equivalent. This is because that it does not have force in x-direction. All other systems have force $F=(10 lb )i$ . Now, to identify the equivalent system, move all other systems to origin O. This will noT change the forces.

Write the expression to calculate the force part of force couple system.

$R=∑F$

Here, $R$ is the vector sum of all forces acting on the beam and $F$ denotes any individual force.

Let check the couple part of force-couple system.

Write the expression to calculate the couple part of force couple system.

$MR=∑(r×F)$

Here, $MR$ is the resultant moment and $r$ is the length from axis of rotation to the point of application of force.

In the given system, at points A,D,G and I, moments in two directions are directly given. So the expression to find $∑(r×F)$ is as follows.

$∑(r×F)=M1+M2+(r×F)$

Here, $M1 and M2$ are the given couple moments

Rewrite the equation for $MR$ by substituting the above expression for $∑(r×F)$ .

$MR=M1+M2+(r×F)$ (I)

Write the determinant form to calculate $r×F$ .

$r×F=|ijkrirjrkFiFjFk|$ (II)

Here, $ri$ is the component of $r$ in x-direction, $rj$ is the component of $r$ in y-direction, $rk$ is the is the component of $r$ in z-direction, $Fi$ is the component of $F$ in x-direction, $Fj$ is the component of $F$ in y-direction, and $Fk$ is the component of $F$ in z-direction.

Conclusion:

Substitute $(5 lb⋅ft)j$ for $M1$ , $(15 lb⋅ft)k$ for $M2$ , $(2 ft)k$ for $r$ and $(10 lb)i$ for $F$ in equation (I) to find moment resultant of system at corner A about point O $(MA)$ .

$MA=(5 lb⋅ft)j+(15 lb⋅ft)k+((2 ft)k×(10 lb)i)$ (III)

Solve $(2 ft)k×(10 lb)i$ using equation (II).

$(2 ft)k×(10 lb)i=|ijk002 ft10 lb00|=(0 lb⋅ft) i−(0 lb⋅ft−20 lb⋅ft)j+(0 lb⋅f)k=(20 lb⋅ft)j$

Calculate $MA$ by substituting $(2 ft)k×(10 lb)i$ for $(−20 lb⋅ft)j$ in equation (III).

$MA=(5 lb⋅ft)j+(15 lb⋅ft)k+(20 lb⋅ft)j=(25 lb⋅ft)j+(15 lb⋅ft)k$

Substitute $(−5 lb⋅ft)j$ for $M1$ , $(25 lb⋅ft)k$ for $M2$ , $[(4.5 ft)i+(1 ft )j+(2 ft)k]$ $(2 ft)k$ for $r$ and $(10 lb)i$ for $F$ in equation (I) to find moment resultant of system at corner D about point O $(MD)$ .

$MD=(−5 lb⋅ft)j+(25 lb⋅ft)k+[(4.5 ft)i+(1 ft )j+(2 ft)k]×(10 lb)i$ (IV)

Solve $[(4.5 ft)i+(1 ft )j+(2 ft)k]×(10 lb)i$ using equation (II).

$[(4.5 ft)i+(1 ft )j+(2 ft)k]×(10 lb)i=|ijk4.5 ft1 ft2 ft10 lb00|=(0 lb⋅f) i−(0 lb⋅ft−20 lb⋅ft)j+(0 lb⋅ft−10 lb⋅ft)k=(20 lb⋅ft)j−(10 lb⋅ft)k$

Calculate $MD$ by substituting $(20 lb⋅ft)j−(10 lb⋅ft)k$ $(2 ft)k×(10 lb)i$ for $[(4.5 ft)i+(1 ft )j+(2 ft)k]×(10 lb)i$ $(−20 lb⋅ft)j$ in equation (IV).

$MD=(−5 lb⋅ft)j+(25 lb⋅ft)k+(20 lb⋅ft)j−(10 lb⋅ft)k=(15 lb⋅ft)j+(15 lb⋅ft)k$

Substitute $(15 lb⋅ft)i$ for $M1$ , $(15 lb⋅ft)j$ for $M2$ , $[(0 ft)i+(0 ft )j+(0 ft)k]$ for $r$ and $(10 lb)i$ for $F$ in equation (I) to find moment resultant of system at corner G about point O $(MG)$ .

$MG=(15 lb⋅ft)i+(15 lb⋅ft)j+[(0 ft)i+(0 ft )j+(0 ft)k]×(10 lb)i=(15 lb⋅ft)i+(15 lb⋅ft)j+(0 ft)i+(0 ft )j+(0 ft)k=(15 lb⋅ft)i+(15 lb⋅ft)j$

Substitute $(15 lb⋅ft)j$ for $M1$ , $(−5 lb⋅ft)k$ for $M2$ , $[(4.5 ft)i+(1 ft )j]$ for $r$ and $(10 lb)j$ for $F$ in equation (I) to find moment resultant of system at corner I about point O $(MI)$ .

$MD=(15 lb⋅ft)j+(−5 lb⋅ft)k+([(4.5 ft)i+(1 ft )j]×(10 lb)j)$ (V)

Solve $[(4.5 ft)i+(1 ft )j]×(10 lb)j$ using equation (III).

$[(4.5 ft)i+(1 ft )j]×(10 lb)j=|ijk(4.5 ft)(1 ft )(0 ft)(10 lb)00|=(0 lb⋅f) i−(0 lb⋅ft)j+(0 lb⋅ft−10 lb⋅ft)k(−10 lb⋅ft)k$

Calculate $MD$ by substituting $(−10 lb⋅ft)k$ for $[(4.5 ft)i+(1 ft )j]×(10 lb)j$ $(−20 lb⋅ft)j$ in equation (V).

$MI=(15 lb⋅ft)j−(5 lb⋅ft)k+(−10 lb⋅ft)k=(15 lb⋅ft)j−(15 lb⋅ft)k$

From the above calculations, it is found that system at corner D has force equivalent $F=(10 lb )i$ and moment equivalent $M=(15 lb⋅ft)j+((15 lb⋅ft))k$ at origin.

Therefore, System at corner D is the equivalent force-couple system.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Students have asked these similar questions

4- A horizontal Venturi meter is used to measure the flow rate of water through the piping system of 20 cm I.D, where the diameter of throat in the meter is d₂ = 10 cm. The pressure at inlet is 17.658 N/cm2 gauge and the vacuum pressure of 35 cm Hg at throat. Find the discharge of water. Take Cd = 0.98.

10

6

Answer 2