VECTOR MECH. FOR EGR: STATS & DYNAM (LL
VECTOR MECH. FOR EGR: STATS & DYNAM (LL
12th Edition
ISBN: 9781260663778
Author: BEER
Publisher: MCG
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Chapter 14.3, Problem 14.99P

Determine the distance traveled by the spacecraft of Prob. 14.97 during the rocket engine firing, knowing that its initial speed was 7500 ft/s and the duration of the firing was 60 s.

14.97 The weight of a spacecraft, including fuel, is 11,600 lb when the rocket engines are fired to increase its velocity by 360 ft/s. Knowing that 1000 lb of fuel is consumed, determine the relative velocity of the fuel ejected.

Fig. P14.97 and P14.98

Chapter 14.3, Problem 14.99P, Determine the distance traveled by the spacecraft of Prob. 14.97 during the rocket engine firing,

Expert Solution & Answer
Check Mark
To determine

Find the distance travelled by the spacecraft.

Answer to Problem 14.99P

The distance travelled by the spacecraft is s=87.2mi_.

Explanation of Solution

Given information:

The initial speed of the spacecraft is v0=7,500ft/s.

The duration of firing is t=60s.

The change in velocity is vv0=360ft/s.

The gross weight of the spacecraft is W0=11,600lb.

The fuel consumed rate is W=1,000lb.

Calculation:

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

P=udmdt=uq

Calculate the mass (m) as shown below.

m=m0qt (1)

Calculate the acceleration (a) as shown below.

a=Pm

Substitute uq for F.

a=uqm

Substitute m0qt for m.

a=uqm0qt

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

v=v0+0tadt

Substitute uqm0qt for a.

v=v0+0t(uqm0qt)dt=v0+u0tqm0qtdt=v0+quq(ln(m0qt))0t=v0u(ln(m0qt)lnm0)

=v0ulnm0qtm0 (2)

Calculate the displacement (s) as shown below.

Integrate both sides of the Equation (2) as shown below.

s=s0+v0tu0t(lnm0qtm0)dt (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 dz and apply the limits in Equation (3).

s=s0+v0tu0tlnz(m0qdz)=s0+v0t+um0qz0z1lnzdz=s0+v0t+um0q×(zlnzz)z0z1

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

s=s0+v0t+um0q×(m0qtm0lnm0qtm0m0qtm0)0t=s0+v0t+um0q×(m0qtm0lnm0qtm0m0qtm0m0m0lnm0m0+m0m0)=s0+v0t+um0q(m0qtm0lnm0qtm0m0qtm0+1)=s0+v0t+um0q(m0qtm0(lnm0qtm01)+1)

=s0+v0t+um0q((1qtm0)(lnm0qtm01)+1)=s0+v0t+um0q(lnm0qtm0qtm0lnm0qtm01+qtm0+1)=s0+v0t+um0qlnm0qtm0utlnm0qtm0+ut=s0+v0t+(ut+(um0qut)lnm0qtm0)

=s0+v0t+u(t(m0qt)lnm0m0qt) (5)

Calculate the velocity (v) as shown below.

vv0=360

Substitute 7,500ft/s for v0.

v7,500=360v=7,860ft/s

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

Calculate the gross mass of the spacecraft (m0) as shown below.

m0=W0g

Substitute 11,600lb for W0 and 32.2ft/s2 for g.

m0=11,60032.2=360.25lb

Consider that the mass of the fuel mfuel=Wfuelg=qt.

Substitute 1,000lb for Wfuel, 32.2ft/s2 for g and 60s for t.

q×60=1,00032.2q=0.5176lb/s

Calculate the mass (m) as shown below.

Substitute 360.25lb for m0, 0.5176lb/s for q and 60s for t in Equation (1).

m=360.250.5176×60=329.19lb

Consider the initial displacement s0=0.

Calculate the relative velocity (u) as shown below.

Substitute 7,860ft/s for v, 7,860ft/s for v0, 329.19lb for m0qt, and 360.25lb for m0 in Equation (2).

7,860=7,500uln329.19360.25360=uln360.25329.19u=3,992.7u3,993ft/s

Calculate distance travelled by the spacecraft (s) as shown below.

Substitute 0 for s0, 7,500ft/s for v0, 3,993ft/s for u, 329.19lb for m0qt, 0.5176lb/s for q, 60s for t, and 360.25lb for m0 in Equation (2).

s=0+7,500×60+3,993×(60(360.250.517660)ln360.25329.19)=450×103+3,993×(6057.344)=450×103+10.6×103=460.6×103ft×1mi5,280ft

=87.2mi

Therefore, the distance travelled by the spacecraft is s=87.2mi_.

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Chapter 14 Solutions

VECTOR MECH. FOR EGR: STATS & DYNAM (LL

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