Vector Mechanics for Engineers: Statics
Vector Mechanics for Engineers: Statics
12th Edition
ISBN: 9781259977268
Author: Ferdinand P. Beer, E. Russell Johnston Jr., David Mazurek
Publisher: McGraw-Hill Education
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Chapter 7.1, Problem 7.16P

Chapter 7.1, Problem 7.16P, Fig. P7.15 and P7.16 7.16 Knowing that the radius of each pulley is 100 mm and neglecting friction,

Fig. P7.15 and P7.16

7.16 Knowing that the radius of each pulley is 100 mm and neglecting friction, determine the internal forces at (a) point C, (b) point J that is 100 mm to the left of C.

(a)

Expert Solution
Check Mark
To determine

The internal forces exerted at the point C in a frame.

Answer to Problem 7.16P

The internal forces of shearing force is V=540N acting in the upward direction, axial force F=520N acting in the leftside of the frame, and the bending moment acting at that point is M=0.

Explanation of Solution

Sketch the free body diagram for the internal forces acting on the frame and pulley system as shown in the Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 7.1, Problem 7.16P , additional homework tip  1

Write the equation of the axial force exerted at the axial point A of the frame from x direction.

Fx=0Ex=0 (I)

Here, the force exerted on the frame at the point E from x direction in equilibrium condition is Fx.

Write the equation of the moment of couple formed in the bending moment of the frame and pulley system supported at the point E rotated in counterclockwise moment (Refer fig 1).

ME=0FB(l)FB(l1+r)+Ad=0 (II)

Here, the axial force exerted on the pulley at point B is FB, the radius of the each pulley is r, distance between the pulley B on the frame to the point C is l, distance between the point A on the frame to the point D is l1, and total distance of the frame is d.

Write the equation of the axial force exerted at the axial point of the frame from y direction (Refer fig 1).

Fy=0Ey+A=0 (III)

Here, the axial force exerted on the pulley at point E in y direction is Ey.

Sketch the free body diagram for the cable as shown in the Figure 2.

Vector Mechanics for Engineers: Statics, Chapter 7.1, Problem 7.16P , additional homework tip  2

The slope of the cable (Refer fig 2):

BC=CD=200mmBG=DH=120mm

The angle formed in the slope of the cable:

sinα=100mm200mm=15sinα=0.2α=30°

Write the equation of the axial force exerted at the axial point AC of the given free body diagram from x direction.

Fx=0FBcosαF=0 (IV)

Here, the angle between the pulley B to the frame is α and the axial force exerted on the frame and pulley system is F.

Sketch the free body diagram for the cable for the point AC as shown in the Figure 3.

Vector Mechanics for Engineers: Statics, Chapter 7.1, Problem 7.16P , additional homework tip  3

Write the equation of the axial force exerted at the point A of the frame from y direction.

Fy=0V+ABxsinαFB=0 (V)

Here, shearing force acting on the semicircular rod is V

At the pulley B it is resolved into two components Bx and By.

Write the equation of the moment of couple formed in the bending moment supported at the point C rotated in counterclockwise moment.

MC=0Mx1A+(Bxsinα+FB)x2=0 (VI)

Here, the moment of couple exerted at the point C in the frame is represented as MC and moment of couple acting in the bending beam is M.

Conclusion:

Substitute 600N for FB, 100mm for r, 200mm for l, 1000mm for d, and 700mm for l1 in equation (II) to solve for A.

(600N)(200mm)(600N)(700mm+100mm)+A(1000mm)=0(600N)(200mm)(0.001m1mm)(600N)(800mm)(0.001m1mm)+A(1000mm)(0.001m1mm)=0(600N)(0.2m)(600N)(0.8m)+A(1m)=0

Solve the above equation for A.

(120Nm)(480Nm)+A(1m)=0(360Nm)=A(1m)A=360N

Substitute 360N for A in equation (III) to solve for Ey.

Ey+360N=0Ey=360N

Substitute 600N for FB and 30° for α in equation (IV) to solve for F.

FBcosαF=0(600N)cos30°F=0520NF=0F=520N

Substitute 360N for A, 600N for Bx, 600N for FB, and 30° for α in equation (V) to solve for V

V+ABxcosαF=0V+360N(600N)sin30°600N=0V+360N300N600N=0V540N=0V=540N

Substitute 360N for A, 600N for Bx, 600N for FB, 500mm for x1, 200mm for x2,30° for α in equation (VI) to solve for M.

Mx1A+(Bxcoα+FB)x2=0M(500mm)(360N)+(600Nsin30°+600N)(200mm)=0M(500mm)(0.001m1mm)(360N)+(300N+600N)(200mm)(0.001m1mm)=0M(0.500m)(360N)+(900N)(0.200m)=0

The above equation can be written as,

M180Nm+180Nm=0M=0

Therefore, The internal forces of shearing force is V=540N acting in the upward direction, axial force F=520N acting in the leftside of the frame, and the bending moment acting at that point is M=0.

(b)

Expert Solution
Check Mark
To determine

The internal forces exerted at the point J to the left point C in a frame of 100mm.

Answer to Problem 7.16P

The internal forces of shearing force is V=540N acting in the upward direction, axial force F=520N acting in the leftside of the frame, and the bending moment acting at that point is M=54.0Nm rotates in the counterclockwise direction.

Explanation of Solution

Sketch the free body diagram for the cable for the point AJ as shown in the Figure 3.

Vector Mechanics for Engineers: Statics, Chapter 7.1, Problem 7.16P , additional homework tip  4

Write the equation of the axial force exerted at the axial point AJ of the frame from x direction.

Fx=0F+FB=0 (VII)

Here, the force exerted on the frame at the point E from x direction in equilibrium condition is Fx.

Write the equation of the axial force exerted at the axial point of the frame from y direction (Refer fig 4).

Fy=0V+ABxsinαFB=0 (VIII)

Here, the axial force exerted on the pulley at point D is FD.

Write the equation of the moment of couple formed in the bending moment supported at the point J rotated in counterclockwise moment.

MJ=0Mx3A+(Bxsinα+FB)x4=0 (IX)

Here, the moment of couple exerted at the point J in the frame is represented as MJ and moment of couple acting in the bending beam is M.

Conclusion:

Substitute 600N for FB and 30° for α in equation (VII) to solve for F.

F+(600N)cos30°=0F+520N=0F=520N

Substitute 360N for A, 600N for Bx, 600N for FB, and 30° for α in equation (VIII) to solve for V.

V+ABxsinαFB=0V+360N(600N)sin30°600N=0V+360N300N600N=0V540N=0V=540N

Substitute 360N for A, 600N for Bx, 600N for FB, 500mm for x1, 200mm for x2,30° for α in equation (IX) to solve for M.

Mx3A+(Bxsinα+FB)x4=0M(400mm)(360N)+(600Nsin30°+600N)(100mm)=0M(400mm)(0.001m1mm)(360N)+(300N+600N)(100mm)(0.001m1mm)=0M(0.400m)(360N)+(900N)(0.100m)=0

The above equation can be written as,

M144Nm+90Nm=0M=54Nm

Therefore, the internal forces of shearing force is V=540N acting in the upward direction, axial force F=520N acting in the leftside of the frame, and the bending moment acting at that point is M=54.0Nm rotates in the counterclockwise direction.

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Chapter 7 Solutions

Vector Mechanics for Engineers: Statics

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