VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS
VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS
12th Edition
ISBN: 9781260265453
Author: BEER
Publisher: MCG
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Textbook Question
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Chapter 12.1, Problem 12.52P

A curve in a speed track has a radius of 1000 ft and a rated speed of 120 mi/h. (See Sample Prob. 12.7 for the definition of rated speed.) Knowing that a racing car starts skidding on the curve when traveling at a speed of 180 mi/h, determine (a) the banking angle θ, (b) the coefficient of static friction between the tires and the track under the prevailing conditions, (c) the minimum speed at which the same car could negotiate the curve.

Fig. P12.52

Chapter 12.1, Problem 12.52P, A curve in a speed track has a radius of 1000 ft and a rated speed of 120 mi/h. (See Sample Prob.

(a)

Expert Solution
Check Mark
To determine

Find the banking angle θ.

Answer to Problem 12.52P

The banking angle θ is 43.9°_.

Explanation of Solution

Given information:

The radius (ρ) of the track is 1,000 ft.

The rated speed (vR) is 120 mi/h.

The frictional force (F0) at rated speed is 0.

The speed (v) at prevailing condition is 180 mi/h.

Calculation:

Write the general equation weight (W).

W=mg

Here, m is the mass and g is the acceleration due to gravity.

Write the general equation of acceleration (a) in curved path.

a=v2ρ

Here, v is the speed and ρ is the radius of curved path.

Sketch the free body diagram and kinetic diagram of the racing car as shown in Figure (1).

VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS, Chapter 12.1, Problem 12.52P

Refer Figure (1):

Consider the racing car moves at rated speed.

Find the banking angle θ.

Apply Newton’s law of equation along x-axis.

ΣFx=maxF0+Wsinθ=macosθF0=macosθWsinθ

Substitute 0 for F0, vR2ρ for a, and mg for W.

0=m(vR2ρ)cosθ(mg)sinθmgsinθ=mvR2ρcosθsinθcosθ=vR2ρgtanθ=vR2ρg

Substitute 120 mi/h for vR, 32.2ft/s2 for g, and 1,000 ft for ρ.

tanθ=(120mi/h×5,280ft1mi×1h3,600s)2(1,000)(32.2)tanθ=0.96199θ=43.9°

Thus, the banking angle θ.is 43.9°_.

(b)

Expert Solution
Check Mark
To determine

Find the coefficient of static friction between the tires and the track under the prevailing conditions.

Answer to Problem 12.52P

The coefficient of static friction between the tires and the track under the prevailing conditions is 0.390_.

Explanation of Solution

Calculation:

Refer Figure (1):

Consider the racing car moves in prevailing condition.

Apply Newton’s law of equation along y-axis.

ΣFx=maxF+Wsinθ=macosθF=macosθWsinθ

Substitute v2ρ for a and mg for W.

F=m(v2ρ)cosθ(mg)sinθ (1)

Apply Newton’s law of equation along y-axis.

ΣFy=mayNWcosθ=masinθN=masinθ+Wcosθ

Substitute v2ρ for a and mg for W.

N=m(v2ρ)sinθ+(mg)cosθ (2)

Find the coefficient of static friction (μs) between the tires and the track under the prevailing conditions.

Write the general equation of normal force(N).

F=μsNμs=FN (3)

Substitute Equation (1) and (2) in Equation (3).

μs=m(v2ρ)cosθ(mg)sinθm(v2ρ)sinθ+(mg)cosθ=m(v2cosθρgsinθ)m(v2sinθ+ρgcosθ)=v2cosθρgsinθv2sinθ+ρgcosθ

Substitute 180 mi/h for v, 43.9° for θ, 32.2ft/s2 for g, and 1,000 ft for ρ.

μs=(180mi/h×5,280ft1mi×1h3,600s)2cos43.9°(1,000)(32.2)sin43.9°(180mi/h×5,280ft1mi×1h3,600s)2sin43.9°+(1000)(32.2)cos43.9°=27.89199×10371.52908×103=0.390

Thus, the coefficient of static friction between the tires and the track under the prevailing conditions is 0.390_.

(c)

Expert Solution
Check Mark
To determine

Find the minimum speed at which the same car could negotiate that curve.

Answer to Problem 12.52P

The minimum speed at which the same car could negotiate that curve is 78.8mi/h_.

Explanation of Solution

Calculation:

Write the general equation of normal force (N) in minimum speed.

F=μsNμs=FN (3)

Substitute Equation (1) and (2) in Equation (3).

μs=m(v2ρ)cosθ(mg)sinθm(v2ρ)sinθ+(mg)cosθμs=m(v2cosθρgsinθ)m(v2sinθ+ρgcosθ)μs(v2sinθ+ρgcosθ)=(v2cosθρgsinθ)v2μssinθ+ρgμscosθ=ρgsinθv2cosθ

v2μssinθ+v2cosθ=ρgsinθρgμscosθv2(μssinθ+cosθ)=ρg(sinθμscosθ)v2=ρg(sinθμscosθ)μssinθ+cosθ

Substitute 0.390 for μs, 43.9° for θ, 32.2ft/s2 for g, and 1,000 ft for ρ.

v2=(1,000)(32.2)(sin43.9°0.390cos43.9°)0.390sin43.9°+cos43.9°v=13,278.858010.990977v=115.757ft/s×1mi5,280ft×3,600s1hv=78.8mi/h

Thus, the minimum speed at which the same car could negotiate that curve is 78.8mi/h_.

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Chapter 12 Solutions

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

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The two blocks shown are originally at rest....Ch. 12.1 - The two blocks shown are originally at rest....Ch. 12.1 - Prob. 12.15PCh. 12.1 - Prob. 12.16PCh. 12.1 - A 5000-lb truck is being used to lift a 1000-lb...Ch. 12.1 - Block A has a mass of 40 kg, and block B has a...Ch. 12.1 - Block A has a mass of 40 kg, and block B has a...Ch. 12.1 - The flat-bed trailer carries two 1500-kg beams...Ch. 12.1 - Prob. 12.21PCh. 12.1 - To unload a bound stack of plywood from a truck,...Ch. 12.1 - To transport a series of bundles of shingles A to...Ch. 12.1 - An airplane has a mass of 25 Mg and its engines...Ch. 12.1 - Determine the maximum theoretical speed that a...Ch. 12.1 - A constant force P is applied to a piston and rod...Ch. 12.1 - A spring AB of constant k is attached to a support...Ch. 12.1 - Block A has a mass of 10 kg, and blocks B and C...Ch. 12.1 - Prob. 12.29PCh. 12.1 - Prob. 12.30PCh. 12.1 - A 10-lb block B rests as shown on a 20-lb bracket...Ch. 12.1 - Knowing that k = 0.30, determine the acceleration...Ch. 12.1 - 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