Vector Mechanics for Engineers: Statics
Vector Mechanics for Engineers: Statics
12th Edition
ISBN: 9781260501735
Author: BEER
Publisher: MCG
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Chapter 5.3, Problem 5.80P

The cross section of a concrete dam is as shown. For a 1-ft-wide dam section, determine (a) the resultant of the reaction forces exerted by the ground on the base AB of the dam, (b) the point of application of the resultant of part a, (c) the resultant of the pressure forces exerted by the water on the face BC of the dam.

Chapter 5.3, Problem 5.80P, The cross section of a concrete dam is as shown. For a 1-ft-wide dam section, determine (a) the

Fig. P5.80

(a)

Expert Solution
Check Mark
To determine

The reaction force exerted by the ground on the base of the concrete dam.

Answer to Problem 5.80P

The resultant reaction forces acts on the base of the dam is H=10.11kips and V=37.8kips acts in the upward direction.

Explanation of Solution

Given that the width of the dam section w is 1ft. The height of the dam at the point C is h=18ft.

The free-body diagram consists of a 1ft thick section of the dam and the triangular section of water above the dam is shown in the Figure 1.

Vector Mechanics for Engineers: Statics, Chapter 5.3, Problem 5.80P , additional homework tip  1

The wide length of the top section of dam is represented as x1, the distance from the base to the center of the dam is x2, the distance from the base to the point C is x3, and the distance from the base to the point D is x4. Other forces acting on the free body are the weight of the dam represented by the weights of its components are W1, W2, and W3, the weight of the water is W4, and the resultant pressure forces exerted on section BD by the water is P.

Write the equation for weight force of the dam.

W=γV (I)

Here, the weight of the dam is W, specific weight of the object is γ, and the volume of the triangular section of the water above the dam is V.

Replace 1/2lwh for V in the equation (I).

W=γ12lwh

Here, the width of the dam section is w, the length of the surface is l, and the height of the dam is h.

Write the equation for the weight of the dam represented by the weights of its components. W1=γC12l1wh1

Here, the weight of the dam by the components of fist section is W1, specific weight of the concrete is γC, the wide length of the top section of dam is represented as l1, and the height of the dam from the ground to cross section of dam is h1.

Substitute 150lb/ft3 for γC, 9ft for l1, 1ft for w, and 15ft for h1.

W1=(150lb/ft3)[12(9ft)(15ft)(1ft)]=10,125lb

Write the equation for the weight of the dam represented in the triangular section.

W2=γC12l2wh2

Here, the weight of the dam by the components of second section is W2, specific weight of the concrete is γC, the wide length of the triangular section of dam is represented as l2, and the height of the dam from the ground is h2.

Substitute 150lb/ft3 for γC, 6ft for l2, 1ft for w, and 18ft for h2.

W2=(150lb/ft3)[(6ft)(18ft)(1ft)]=16,200lb

Write the equation for the weight of the dam represented by the weights of its components.

W3=γC12l3wh3

Here, the weight of the dam by the components of third section is W3, specific weight of the concrete is γC, the wide length of the triangular section of dam is represented as l3, and the height of the dam from the ground is h3.

Substitute 150lb/ft3 for γC, 6ft for l3, 1ft for w, and 18ft for h3.

W3=(150lb/ft3)[12(6ft)(18ft)(1ft)]=8100lb

Write the equation for the weight of the dam represented by the weights of its components.

W4=γ12l4wh4

Here, the weight of the dam by the components of fourth section is W4, specific weight of fresh water is γ, the wide length of the triangular section of dam is represented as l4, and the height of the dam from the ground is h4.

Substitute 62.4lb/ft3 for γ, 6ft for l4, 1ft for w, and 18ft for h4.

W4=(62.4lb/ft3)[12(6ft)(18ft)(1ft)]=3369.6lb

Write the equation of the force pressure exerted by the ground on the base of the dam.

P=12Ap (II)

Here, the reaction force exerted on the dam is P, cross section area of the dam is A, and the pressure of the water is p.

Replace γh for p and hw for A in equation (II).

P=12(hw)(γh) (III)

Write the equilibrium equation for the section of dam acts along x axis (Refer Fig 1).

Fx=0HP=0 (IV)

Here, the reaction force exerted by the ground on the base AB of the dam is H.

Write the equilibrium equation for the section of beam acts along y axis and then calculate the reaction force (Refer Fig 1).

Fy=0VW1W2W3W4=0 (V)

Here, the reaction force exerted by the ground on the base AB of the dam is V.

Conclusion:

Substitute 62.4lb/ft3 for γ, 1ft for w, and 18ft for h in equation (III) and solve for P.

P=12[(18ft)(1ft)][(62.4lb/ft3)(18ft)]=10,108.8lb

Substitute 10,108.8lb for P in equation (IV) and solve for H.

H10,108.8lb=0H=10,108.8lb(1kips1000lb)=10.1088kips10.11kips

Substitute 10,125lb for W1, 16,200lb for W2, 8100lb for W3, and 3369.6lb for W4 in equation (V) and solve for V.

V10,125lb16,200lb8100lb3369.6lb=0V37794.6lb=0V=37794.6lb

Convert the above reaction force value into kips.

V=37,795lb(1kips1000lb)=37.795kips37.8kips

Therefore, the resultant reaction forces acts on the base of the dam is H=10.11kips and V=37.8kips acts in the upward direction.

(b)

Expert Solution
Check Mark
To determine

The point of forces acts on the base AB of the dam from the resultant of part a.

Answer to Problem 5.80P

The point in which the forces acts on the base AB of the dam is x=10.48ft.

Explanation of Solution

The distance from the base of the dam to the point A  is x1=6ft.

The distance from the base of the dam to the mid part is.

x2=(9+3)ft=12ft

The distance from the base of the dam to the point C (Refer fig 1) is.

x3=(15+2)ft=17ft

The distance from the base of the dam to the total path is.

x4=(15+4)ft=19ft

Write the equilibrium equation for the section on the base AB of the dam and calculate the moment labeled at point A (Refer Fig 1).

MA=0xVW1x1W2x2W3x3W4x4+Pl=0 (VI)

Here, the different section of the dam is represented as x1, x2, x3, and x4.

Conclusion:

Substitute 10,125lb for W1, 16,200lb for W2, 8100lb for W3, 3369.6lb for W4, 37794.6lb for V, 6ft for x1, 12ft for x2, 17ft for x3, 10,108.8lb for P, 6ft for l, and 19ft for x4 in equation (VI) and to solve x.

{x(37794.6lb)(10,125lb)(6ft)(16,200lb)(12ft)(8100lb)(17ft)(3369.6lb)(19ft)+(10,108.8lb)(6ft)=0x(37794.6lb)(60750lbft)(194400lbft)(137700lbft)(64022.4lbft)+(60652.8lbft)=0x(37794.6lb)(456872.4lbft)+(60652.8lbft)=0}

Solve the above equation for x.

x(37794.6lb)(396219.6lbft)=0x(37794.6lb)=(396219.6lbft)x=10.48ft

Therefore, the point in which the forces acts on the base AB of the dam is x=10.48ft.

(c)

Expert Solution
Check Mark
To determine

The resultant pressure force exerted by the water on the face BC of the dam.

Answer to Problem 5.80P

The resultant pressure force exerted by the water on the face BC of the dam is R=10.66kips at the angle of 18.43°.

Explanation of Solution

The free body diagram of the water section BCD in the dam as shown in figure 2:

Vector Mechanics for Engineers: Statics, Chapter 5.3, Problem 5.80P , additional homework tip  2

Write the equilibrium equation for the s resultant pressure force exerted by the water on the face BC of the dam (Refer Fig 2).

F=0R=P2+W42 (VII)

Here, the resultant pressure force exerted by the water on the dam is R.

Solve for the angle of resultant force exerted by the water on the dam by using trigonometric relation (Refer fig 2).

tanθ=oppadjθ=tan1(W4P) (VIII)

Conclusion:

Substitute 3369.6lb for W4 and 10,108.8lb for P in equation (VII) and to solve for R.

R=(10,108.8lb)2+(3369.6lb)2=10655.6lb(1kips1000lb)=10.66kips

Substitute 3369.6lb for W4 and 10,108.8lb for P in equation (VIII) and to solve for θ.

θ=tan1(3369.6lb10,108.8lb)=18.43°

Therefore, the resultant pressure force exerted by the water on the face BC of the dam is R=10.66kips at the angle of 18.43°.

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Chapter 5 Solutions

Vector Mechanics for Engineers: Statics

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