VECTOR MECH...,STAT.+DYNA.(LL)-W/ACCESS
VECTOR MECH...,STAT.+DYNA.(LL)-W/ACCESS
11th Edition
ISBN: 9781259633133
Author: BEER
Publisher: MCG
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Textbook Question
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Chapter 14.3, Problem 14.100P

A rocket weighs 2600 lb, including 2200 lb of fuel, which is consumed at the rate of 25 lb/s and ejected with a relative velocity of 13,000 ft/s. Knowing that the rocket is fired vertically from the ground, determine (a) its acceleration as it is fired, (b) its acceleration as the last particle of fuel is being consumed, (c) the altitude at which all the fuel has been consumed, (d) the velocity of the rocket at that time.

(a)

Expert Solution
Check Mark
To determine

The acceleration of the rocket as it is fired.

Answer to Problem 14.100P

The acceleration of the rocket as it is fired is a=92.8ft/s2_.

Explanation of Solution

Given information:

The fuel consumed rate is dmdt=25lb/s.

The relative velocity is u=13,000ft/s.

The gross weight of the rocket is W0=2,600lb.

The weight of the fuel is Wfuel=2,200lb.

Calculation:

Consider the acceleration due to gravity g=32.2ft/s2.

Calculate the thrust force (P) acting to the rocket as shown below.

P=udmdt

Substitute 13,000ft/s for u and 25lb/s for dmdt.

P=13,000ft/s×25lb/s32.2ft/s2=10,093lb

Calculate the mass (m) as shown below.

m=W0g

Substitute 2,600lb for W0 and 32.2ft/s2 for g.

m=2,60032.2=80.745lbs2/ft×1slugs1lbs2/ft=80.745slugs

Calculate the acceleration (a) using the relation as shown below.

F=maPmg=ma (1)

Substitute 10,093lb for P, 80.745lbs2/ft for m, and 32.2ft/s2 for g in Equation (1).

10,09380.745×32.2=80.745a7,493=80.745aa=92.8ft/s2

Hence, acceleration of the rocket as it is fired is a=92.8ft/s2_.

(b)

Expert Solution
Check Mark
To determine

The acceleration of the rocket as the last particle of fuel is being consumed.

Answer to Problem 14.100P

The acceleration of the rocket as the last particle of the fuel is being consumed is a=780ft/s2_.

Explanation of Solution

Given information:

The fuel consumed rate is dmdt=25lb/s.

The relative velocity is u=13,000ft/s.

The gross weight of the rocket is W0=2,600lb.

The weight of the fuel is Wfuel=2,200lb.

Calculation:

Refer to part (a).

The thrust force P=10,093lb.

Calculate the weight of the rocket (W) after the fuel is being consumed as shown below.

W=W0Wfuel

Substitute 2,600lb for W0 and 2,200lb for Wfuel.

W=2,6002,200=400lb

Calculate the mass (m) as shown below.

m=Wg

Substitute 400lb for W and 32.2ft/s2 for g.

m=40032.2=12.422lbs2/ft×1slugs1lbs2/ft=12.422slugs

Calculate the acceleration (a) using the relation as shown below.

Substitute 10,093lb for P, 12.422lbs2/ft for m, and 32.2ft/s2 for g.

10,09312.422×32.2=12.422a9,693=12.422aa=780ft/s2

Hence, acceleration of the rocket as the last particle of the fuel is being consumed is a=780ft/s2_.

(c)

Expert Solution
Check Mark
To determine

The altitude at which all the fuel has been consumed

Answer to Problem 14.100P

The altitude of the rocket is h=119.3mi_.

Explanation of Solution

Given information:

The fuel consumed rate is q=dmdt=25lb/s.

The relative velocity is u=13,000ft/s.

The gross weight of the rocket is W0=2,600lb.

The weight of the fuel is Wfuel=2,200lb.

Calculation:

Consider the weight of the fuel as Wfuel=m=2,200lb.

Calculate the time (t) as shown below.

dmdt=25dt=125dm

Integrate both sides of the Equation.

0tdt=1250mdmt=125m

Substitute 2,200lb for m.

t=2,20025=88s

Refer to sample problem 14.8 in the Text book,

Calculate the velocity (v) using the relation as shown below.

v=ulnm0m0qtgt=ulnm0qtm0gt (2)

Consider dydt=v.

Substitute dydt for v in Equation (2).

dydt=ulnm0qtm0gt

Calculate the altitude (h) as shown below.

Integrate both sides of the Equation with respect to t.

h=0hdy=0tvdt

Substitute ulnm0qtm0gt for v.

h=0t(ulnm0qtm0gt)dt=u0tlnm0qtm0dt0tgtdt=u0tlnm0qtm0dt12gt2 (3)

Consider z=m0qtm0 (4)

Differentiate both sides of the Equation (4) as shown below.

dz=qm0dtdt=m0qdz

Substitute z for m0qtm0 and m0qdz for dt and apply the limits in Equation (3).

h=u0tlnz(m0qdz)12gt2=m0uqz0zlnzdz12gt2=m0uq[(zlnzz)]z0z12gt2

Substitute m0qtm0 for z and apply the limits as shown below.

h=m0uq[(m0qtm0lnm0qtm0m0qtm0)]0t12gt2=m0uq[(m0qtm0lnm0qtm0m0qtm0)(m0m0lnm0m0m0m0)]12gt2=m0uq[(m0qtm0(lnm0qtm01))+1]12gt2=m0uq[(1qtm0)(lnm0qtm01)+1]12gt2

=m0uq(lnm0qtm01+1)ut(lnm0qtm01)12gt2=u(t(m0qt)lnm0m0qt)12gt2 (5)

Calculate the altitude (h) as shown below.

Substitute 13,000ft/s for u, 2,600lb for m0, 25lb/s for q, 88s for t, and 32.2ft/s2 for g in Equation (5).

h=13,000(88(2,6002588)ln2,6002,60025×88)12×32.2×882=13,000(8816ln6.5)124,678.4=629,987ft×1mi5,280ft=119.3mi

Hence, the altitude of the rocket is h=119.3mi_.

(d)

Expert Solution
Check Mark
To determine

The velocity of the rocket.

Answer to Problem 14.100P

The velocity of the rocket is v=14,660mi/h_.

Explanation of Solution

Given information:

The fuel consumed rate is q=dmdt=25lb/s.

The relative velocity is u=13,000ft/s.

The gross weight of the rocket is W0=2,600lb.

The weight of the fuel is Wfuel=2,200lb.

Calculation:

Calculate the velocity (v) using the relation as shown below.

v=ulnm0m0qtgt=ulnm0qtm0gt (2)

Substitute 13,000ft/s for u, 2,600lb for m0, 25lb/s for q, 88s for t, and 32.2ft/s2 for g in Equation (2).

v=13,000ln2,60025×882,60032.2×88=13,000ln2,6002,60025×882,833.6=21,500ft/s×1mi5,280ft×3,600s1h=14,659mi/h

14,660mi/h

Therefore, the velocity of the rocket is v=14,660mi/h_.

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Chapter 14 Solutions

VECTOR MECH...,STAT.+DYNA.(LL)-W/ACCESS

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