THERMODYNAMICS-SI ED. EBOOK >I<
THERMODYNAMICS-SI ED. EBOOK >I<
9th Edition
ISBN: 9781307573022
Author: CENGEL
Publisher: MCG/CREATE
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Chapter 2.8, Problem 32P

A ski lift has a one-way length of 1 km and a vertical rise of 200 m. The chairs are spaced 20 m apart, and each chair can seat three people. The lift is operating at a steady speed of 10 km/h. Neglecting friction and air drag and assuming that the average mass of each loaded chair is 250 kg, determine the power required to operate this ski lift. Also estimate the power required to accelerate this ski lift in 5 s to its operating speed when it is first turned on.

Expert Solution & Answer
Check Mark
To determine

The power required to operate the ski lift.

The power required to accelerate the ski lift in 5 s to its operating speed.

Answer to Problem 32P

The power required to operate the ski lift is 68.1kW_.

The power required to accelerate the ski lift in 5 s to its operating speed is 43.7kW_.

Explanation of Solution

Calculate the load of the lift at any given time.

m=N(w) (I)

Here, number of chairs at any given time is N and weight of each chair is w.

Calculate the work required to raise the mass by 200 m.

Wg=mg(z2z1) (II)

Here, acceleration due to gravity is g and difference between the elevation of ski lift is z2z1.

Write the equation of change in time.

Δt=DV (III)

Here, distance is D and velocity is V.

Calculate the power needed.

W˙g=Wgt2t1 (IV)

Calculate the acceleration of the ski lift.

a=ΔVΔt=V2V1t2t1 (V)

Here, change in velocity is ΔV, initial and final time is t1 and t2 respectively.

During the acceleration, calculate the power needed.

W˙a=12m(V22V12)t2t1 (VI)

Here, the initial and final velocity of a ski lift are V1 and V2 respectively.

Calculate the vertical distance travelled during the acceleration.

z2z1=hh=12at2sinα (VII)

Here, time to accelerate the ski lift to its operating speed is t and angle to raise the ski lift is α.

Calculate the power needed to acceleate the ski lift in 5 s.

W˙g=mg(h)t2t1 (VIII)

Calculate the total power required to accelerate the ski lift.

W˙total=W˙a+W˙g (IX)

Conclusion:

Since the lift is 1 km long and chairs are spaced 20 m apart, calculate the number of chairs at any given time.

N=1km20m=1km×1000(m1km)20m=50chairs

Substitute 50 chairs for N and 250 kg/chair for w in Equation (I).

m=(50chairs)(250kg/chair)=12,500kg

Substitute 12,500 kg for m, 9.81m/s2 for g, and 200 m for z2z1 in Equation (II).

Wg=(12,500kg)(9.81m/s2)(200m)=(12,500kg)(9.81m/s2)(200m)(1kJ1000kgm2/s2)=24,525kJ

Substitute 1 km for D and 10 km/h for V in Equation (III).

Δt=1km10km/h=0.1h×3600s1h=360s

Substitute 360 s for Δt and 24,525 kJ for Wg in Equation (IV).

W˙g=24,525kJ360s=68.1kW

Thus, the power required to operate the ski lift is 68.1kW_.

Convert the unit of velocity from km/h to m/s.

V=10kmh=10kmh×1000m1km×1h3600s=2.778m/s

Substitute 0 for V1, 2.778 m/s for V2, 0 for t1, and 5 s for t2 in Equation (V).

a=2.778m/s05s0=0.556m/s2

Substitute 0 for t1, 5 s for t2, 0 for V1, 12,500 kg for m, and 2.778 m/s for V2 in Equation (VI).

W˙a=12(12,500kg)((2.778m/s)2(0))5s0=12(12,500kg)(2.778m/s)25s(1kJ/kg1000m2/s2)×1kW1kJ/s=9.6kW

Calculate the value of sinα.

sinα=200m1km=200m1km×1000m1km=0.2

Substitute 0.556m/s2 for a, 5 s for t, and 0.2 for sinα in Equation (VII).

h=12(0.556m/s2)(5s)20.2=1.39m

Substitute 1.39 m for h, 5 s for t2, 0 for t1, 9.81m/s2 for g, and 12,500 kg for m in Equation (VIII).

W˙g=(12,500kg)9.81m/s2(1.39m)5s0=(12,500kg)9.81m/s2(1.39m)5s(1kJ1000kgm2/s2)×1kW1kJ/s=34.08kW34.1kW

Substitute 34.1 kW for W˙g and 9.6 kW for W˙a in Equation (IX).

W˙total=9.6kW+34.1kW=43.7kW

Thus, the power required to accelerate the ski lift in 5 s to its operating speed is 43.7kW_.

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Chapter 2 Solutions

THERMODYNAMICS-SI ED. EBOOK >I<

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