Vector Mechanics for Engineers: Statics and Dynamics
Vector Mechanics for Engineers: Statics and Dynamics
11th Edition
ISBN: 9780073398242
Author: Ferdinand P. Beer, E. Russell Johnston Jr., David Mazurek, Phillip J. Cornwell, Brian Self
Publisher: McGraw-Hill Education
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Chapter 13.1, Problem 13.30P

A 10-kg block is attached to spring A and connected to spring B by a cord and pulley. The block is held in the position shown with both springs unstretched when the support is removed and the block is released with no initial velocity. Knowing that the constant of each spring is 2 kN/m, determine (a) the velocity of the block after it has moved down 50 mm, (b) the maximum velocity achieved by the block.

Fig. P13.30

Chapter 13.1, Problem 13.30P, A 10-kg block is attached to spring A and connected to spring B by a cord and pulley. The block is

(a)

Expert Solution
Check Mark
To determine

Find the velocity (v) of the block after it has moved down 50mm.

Answer to Problem 13.30P

The velocity (v) of the block after it has moved down 50mm is 0.597m/s_.

Explanation of Solution

Given information:

The mass of the block (m) is 10kg.

The spring constant at A (kA) is 2kN/m.

The spring constant at B (kB) is 2kN/m.

The depth where the spring A moves down (xA) is 50mm or 0.05m.

Assume the acceleration due to gravity (g) is 9.81m/s2.

Calculation:

Show the free body diagram of the block with two spring’s attachment acting as in Figure (1).

Vector Mechanics for Engineers: Statics and Dynamics, Chapter 13.1, Problem 13.30P

Calculate the depth of spring B moves down due to block (xB) using the formula:

xB=12xA

Substitute 0.05m for xA.

xB=12(0.05)=0.025m

Calculate the weight of the block (W) using the relation:

W=mg

Substitute 10kg for m and 9.81m/s2 for g.

W=(10)(9.81)=98.1N

Here, the initial kinetic energy (T1) is zero respectively.

Calculate the final kinetic energy (T2) using the formula:

T2=12mv2

Substitute 10kg for m.

T2=12(10)v2=5v2

Calculate the work done (U12)G due to gravity using the formula:

(U12)G=WxA

Substitute 98.1N for W and 0.05m for xA.

(U12)G=(98.1)0.05=4.905Nm

Calculate the work done (U12)A due to spring A using the formula:

(U12)A=12kAxA2

Substitute 0.05m for xA and 2kN/m for kA.

(U12)A=12(2×103)(0.05)2=2.5Nm

Calculate the work done (U12)B due to spring B using the formula:

(U12)B=12kBxB2

Substitute 0.025m for xB and 2kN/m for kB.

(U12)B=12(2×103)(0.025)2=0.625Nm

Calculate the total work done (U12) using the relation:

(U12)=(U12)G(U12)A(U12)B

Substitute 4.905Nm for (U12)G, 2.5Nm for (U12)A, and 0.625Nm for (U12)B.

(U12)=4.9052.50.625=1.78Nm

Use work and energy principle which states that kinetic energy of the particle at a displaced point can be obtained by adding the initial kinetic energy and the work done on the particle during its displacement.

Find the velocity (v) of the block after it has moved down 50mm:

T1+U12=T2

Substitute 0 for T1, 1.78Nm for U12, and 5v2 for T2.

0+(1.78Nm)=5v2v=1.785v=0.597m/s

Therefore, the velocity (v) of the block after it has moved down 50mm is 0.597m/s_.

(b)

Expert Solution
Check Mark
To determine

Find the maximum velocity (vmax) achieved by the block.

Answer to Problem 13.30P

The maximum velocity (vmax) achieved by the block is 0.620m/s_

Explanation of Solution

Given information:

The mass of the block (m) is 10kg.

The spring constant at A (kA) is 2kN/m.

The spring constant at B (kB) is 2kN/m.

The depth where the spring A moves down (xA) is 50mm or 0.05m.

Assume the acceleration due to gravity (g) is 9.81m/s2.

Calculation:

Assume x be the distance moved down by the 10kg block.

Calculate the work done (U12)G due to gravity using the formula:

(U12)G=Wx

Substitute 98.1N for W.

(U12)G=98.1x

Calculate the work done (U12)A due to spring A using the formula:

(U12)A=12kAx2

Substitute 2kN/m for kA.

(U12)A=12(2×103)x2=1000x2

Calculate the work done (U12)B due to spring B using the formula:

(U12)B=12kB(x2)2

Substitute 2kN/m for kB.

(U12)B=12(2×103)(x2)2=1000(x24)=250x2

Calculate the total work done (U12) using the relation:

(U12)=(U12)G(U12)A(U12)B

Substitute 98.1x for (U12)G, 1000x2 for (U12)A, and 250x2 for (U12)B.

(U12)=98.1x1000x2250x2=98.1x1250x2 (1)

Differentiate the above equation with respect to ‘x’.

dU12dx=0

Substitute 98.1x1250x2 for U12.

ddx(98.1x1250x2)=098.12500x=0x=98.12,500x=0.03924m(39.24mm)

Substitute 0.03924m for x in Equation (1).

(U12)=98.1(0.03924)1000(0.03924)2250(0.03924)2=1.925Nm

Use work and energy principle which states that kinetic energy of the particle at a displaced point can be obtained by adding the initial kinetic energy and the work done on the particle during its displacement.

Find the maximum velocity (vmax) achieved by the block:

T1+U12=T2

Substitute 0 for T1, 1.925Nm for U12, and 5v2 for T2.

0+(1.925Nm)=5v2v=1.9255v=0.620m/s

Therefore, the maximum velocity (vmax) achieved by the block is 0.620m/s_.

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Chapter 13 Solutions

Vector Mechanics for Engineers: Statics and Dynamics

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