Vector Mechanics For Engineers
Vector Mechanics For Engineers
12th Edition
ISBN: 9781259977305
Author: BEER, Ferdinand P. (ferdinand Pierre), Johnston, E. Russell (elwood Russell), Cornwell, Phillip J., SELF, Brian P.
Publisher: Mcgraw-hill Education,
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Chapter 17, Problem 17.137RP
To determine

(a)

The impact speed when the hammer hits the test specimen.

Expert Solution
Check Mark

Answer to Problem 17.137RP

The impact speed when the hammer hits the test specimen is 18.2121ft/s.

Explanation of Solution

Given information:

OA=15.25inOH=36.48inMarm=19.5lbsMhammer=71.2lbsIarm=47.1slug.in2=1515.398lb.in2Ihammer=20.9slug.in=2672.4976lb.in2g=32.174ft/s2=386.088in/s2

Initial energy of the system is calculated as follows:

Ei=mAg[OH+OAsin3g]+mhg[OH+OHsin3g]=[19.5[36.48+15.25sin3g]+1.2[36.48+36.48sin3g]]=[898.504+4231.98](386.088)=1980809.748lb.in2/s2

Final energy of the system is calculated as follows:

Ef=mAg[OHOA]+12Iω2=19.5(36.4815.25)386.088+12Iω2=159834.64+12Iω2

Apply the conservation of energy as follows:

Ei=Ef1980809.748=159834.6407+12(101475.08)ω2ω=5.990834rad/s

The impact speed when the hammer hits the test specimen is calculated as follows:

V=ω(OH)V=5.990834×36.48V=218.5458in/sV=18.2121ft/s

Thus, the impact speed when the hammer hits the test specimen is 18.2121ft/s.

Conclusion:

The impact speed when the hammer hits the test specimen is 18.2121ft/s.

To determine

(b)

Find the force on the pin O

Expert Solution
Check Mark

Answer to Problem 17.137RP

Force at the point O before impact is 268.87lb.

Explanation of Solution

Moment of inertia about “O” is calculated as follows:

Io=[Iarm+Ma(OA)2]+[Ihammer+Mh(OH)2]Io=[1515.398+(19.5)(15.25)2]+[672.4376+71.2(36.48)2]Io=101475.0808lb.in2

Free body diagram of the system is shown below:

Vector Mechanics For Engineers, Chapter 17, Problem 17.137RP

Applying newtons second law in rotation as follows:

mAg×15.25cosθ+mHg×36.48cosθ=Ioα19.5×15.25cos39°+71.2×36.48cos39°=101475.080812×αα=0.266rad/s2

Center of gravity of whole system is calculated as follows:

r=mHr1+mAr2mH+mAr=71.2×36.48+19.5×15.2571.2+19.5r=31.915in

Apply Newton’s second law of motion before impact in horizontal direction as follows:

RH=(mH+mA)rαRH=(71.232.2+19.532.2)×31.91512×0.266RH=2lb

Apply Newton’s second law of motion before impact in vertical direction as follows:

RV=(mH+mA)r×ω2RV=(71.232.2+19.532.2)×31.91512×(5.990834)2RV=268.86lb

Force at the point O before impact is calculated as follows:

R=RH2+RV2R=(2)2+(268.86)2R=268.87lb

Thus, Force at the point O before impact is 268.87lb.

To determine

(c)

The amount of energy that test specimen absorb.

Expert Solution
Check Mark

Answer to Problem 17.137RP

Amount of energy that test specimen absorb is 1978089.57lb.in2/s2.

Explanation of Solution

Initial energy of the system is

Ei=mAg[OH+OAsin39°]+mhg[OH+OHsin39°]=[19.5[36.48+15.25sin39°]+71.2[36.48+36.48sin39°]]=[898.504+4231.98](386.088)=1980809.748lb.in2/s2

Final energy of the system is calculated as follows:

Ef=mAg[OAsin70°]+mhg[OHsin70°]Ef=[19.5[15.25sin70°]+71.2[36.48sin70°]]Ef=(279.44+2440.735)Ef=2720.175lb.in2/s2

Amount of energy that test specimen absorb is calculated as follows:

E=EiEfE=1980809.7482720.175E=1978089.57lb.in2/s2

Thus, amount of energy that test specimen absorb is 1978089.57lb.in2/s2.

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Chapter 17 Solutions

Vector Mechanics For Engineers

Ch. 17.1 - Prob. 17.6PCh. 17.1 - Prob. 17.7PCh. 17.1 - Prob. 17.8PCh. 17.1 - Prob. 17.9PCh. 17.1 - Prob. 17.10PCh. 17.1 - Each of the gears A and B has a mass of 10 kg and...Ch. 17.1 - Solve Prob. 17.11, assuming that the 6 N m couple...Ch. 17.1 - The gear train shown consists of four gears of the...Ch. 17.1 - Prob. 17.14PCh. 17.1 - Prob. 17.15PCh. 17.1 - Prob. 17.16PCh. 17.1 - The 15-kg rear hatch of a vehicle opens as shown...Ch. 17.1 - A slender 9-lb rod can rotate in a vertical plane...Ch. 17.1 - Prob. 17.19PCh. 17.1 - Prob. 17.20PCh. 17.1 - A collar with a mass of 1 kg is rigidly attached...Ch. 17.1 - Prob. 17.22PCh. 17.1 - Prob. 17.23PCh. 17.1 - The 30-kg turbine disk has a centroidal radius of...Ch. 17.1 - A 100-kg solid cylindrical disk, 800 mm in...Ch. 17.1 - Prob. 17.26PCh. 17.1 - Prob. 17.27PCh. 17.1 - Prob. 17.28PCh. 17.1 - Prob. 17.29PCh. 17.1 - A half-cylinder with mass m and radius r is...Ch. 17.1 - Prob. 17.31PCh. 17.1 - Two uniform cylinders, each of weight W=14 lb and...Ch. 17.1 - Two uniform cylinders, each of weight W=14 lb and...Ch. 17.1 - A bar of mass m=5 kg is held as shown between four...Ch. 17.1 - The 1.5-kg uniform slender bar AB is connected to...Ch. 17.1 - Prob. 17.36PCh. 17.1 - A 5-m-long ladder has a mass of 15 kg and is...Ch. 17.1 - Prob. 17.38PCh. 17.1 - Prob. 17.39PCh. 17.1 - The mechanism shown is one of two identical...Ch. 17.1 - The mechanism shown is one of two identical...Ch. 17.1 - Each of the two rods shown is of length L=1 m and...Ch. 17.1 - The 4-kg rod AB is attached to a collar of...Ch. 17.1 - If in Prob. 17.43 the angular velocity of the...Ch. 17.1 - The uniform rods AB and BC are of mass 3 kg and 8...Ch. 17.1 - The uniform rods AB and BC weigh 2.4 kg and 4 kg,...Ch. 17.1 - The 80-mm-radius gear shown has a mass of 5 kg and...Ch. 17.1 - Prob. 17.48PCh. 17.1 - Three shafts and four gears are used to form a...Ch. 17.1 - Prob. 17.50PCh. 17.1 - The drive belt on a vintage sander transmits 12 hp...Ch. 17.2 - Slender bar A is rigidly connected to a massless...Ch. 17.2 - A 1-m-long uniform slender bar AB has an angular...Ch. 17.2 - The 350-kg flywheel of a small hoisting engine has...Ch. 17.2 - A sphere of radius r and mass m is placed on a...Ch. 17.2 - Prob. 17.F3PCh. 17.2 - Prob. 17.52PCh. 17.2 - Prob. 17.53PCh. 17.2 - Prob. 17.54PCh. 17.2 - Prob. 17.55PCh. 17.2 - Prob. 17.56PCh. 17.2 - A disk of constant thickness, initially at rest,...Ch. 17.2 - Prob. 17.58PCh. 17.2 - A cylinder of radius r and weight W with an...Ch. 17.2 - Each of the double pulleys shown has a centroidal...Ch. 17.2 - Prob. 17.61PCh. 17.2 - Prob. 17.62PCh. 17.2 - Prob. 17.63PCh. 17.2 - A tape moves over the two drums shown. Drum A...Ch. 17.2 - Prob. 17.65PCh. 17.2 - Prob. 17.66PCh. 17.2 - Prob. 17.67PCh. 17.2 - Consider a rigid body initially at rest and...Ch. 17.2 - Prob. 17.69PCh. 17.2 - Prob. 17.70PCh. 17.2 - Prob. 17.71PCh. 17.2 - Prob. 17.72PCh. 17.2 - Prob. 17.73PCh. 17.2 - Prob. 17.74PCh. 17.2 - Prob. 17.75PCh. 17.2 - Prob. 17.76PCh. 17.2 - A sphere of radius r and mass m is projected along...Ch. 17.2 - Prob. 17.78PCh. 17.2 - Prob. 17.79PCh. 17.2 - Prob. 17.80PCh. 17.2 - Two 10-lb disks and a small motor are mounted on a...Ch. 17.2 - Prob. 17.82PCh. 17.2 - A 1.6-kg tube AB can slide freely on rod DE, which...Ch. 17.2 - In the helicopter shown, a vertical tail propeller...Ch. 17.2 - Prob. 17.85PCh. 17.2 - The 4-kg uniform disk B is attached to the shaft...Ch. 17.2 - Prob. 17.87PCh. 17.2 - Prob. 17.88PCh. 17.2 - Prob. 17.89PCh. 17.2 - Prob. 17.90PCh. 17.2 - Prob. 17.91PCh. 17.2 - Prob. 17.92PCh. 17.2 - Prob. 17.93PCh. 17.2 - Prob. 17.94PCh. 17.2 - Prob. 17.95PCh. 17.3 - A uniform slender rod AB ofmass m is at rest on a...Ch. 17.3 - Prob. 17.F5PCh. 17.3 - Prob. 17.F6PCh. 17.3 - Prob. 17.96PCh. 17.3 - A bullet weighing 0.08 lb is fired with a...Ch. 17.3 - Prob. 17.98PCh. 17.3 - Prob. 17.99PCh. 17.3 - Prob. 17.100PCh. 17.3 - Prob. 17.101PCh. 17.3 - A 45-g bullet is fired with a velocity of 400 m/s...Ch. 17.3 - Prob. 17.103PCh. 17.3 - Prob. 17.104PCh. 17.3 - A uniform slender rod AB of mass m is at rest on a...Ch. 17.3 - Prob. 17.106PCh. 17.3 - Prob. 17.107PCh. 17.3 - Prob. 17.108PCh. 17.3 - Determine the height h at which the bullet of...Ch. 17.3 - A uniform slender bar of length L=200 mm and mass...Ch. 17.3 - A uniform slender rod of length L is dropped onto...Ch. 17.3 - A uniform slender rod AB has a mass m, a length L,...Ch. 17.3 - Prob. 17.113PCh. 17.3 - The trapeze/lanyard air drop (t/LAD) launch is a...Ch. 17.3 - The uniform rectangular block shown is moving...Ch. 17.3 - The 40-kg gymnast drops from her maximum height of...Ch. 17.3 - Prob. 17.117PCh. 17.3 - A uniformly loaded square crate is released from...Ch. 17.3 - A 1-oz bullet is fired with a horizontal velocity...Ch. 17.3 - For the beam of Prob. 17.119, determine the...Ch. 17.3 - The plank CDEhas a mass of 15 kg and rests on a...Ch. 17.3 - Prob. 17.122PCh. 17.3 - A slender rod AB is released from rest in the...Ch. 17.3 - A slender rod AB is released from rest in the...Ch. 17.3 - Prob. 17.125PCh. 17.3 - A 2-kg solid sphere of radius r=40 mm is dropped...Ch. 17.3 - Member ABC has a mass of 2.4 kg and is attached to...Ch. 17.3 - Member ABC has a mass of 2.4 kg and is attached to...Ch. 17.3 - Sphere A of mass mA=2 kg and radius r=40 mm rolls...Ch. 17.3 - A large 3-lb sphere with a radius r=3 in. is...Ch. 17.3 - Prob. 17.131PCh. 17.3 - Sphere A of mass m and radius r rolls without...Ch. 17.3 - Prob. 17.133PCh. 17.3 - Prob. 17.134PCh. 17 - A uniform disk, initially at rest and of constant...Ch. 17 - Prob. 17.136RPCh. 17 - Prob. 17.137RPCh. 17 - You are asked to analyze a catcher for a small...Ch. 17 - A uniform slender rod is placed at corner B and is...Ch. 17 - Prob. 17.140RPCh. 17 - Prob. 17.141RPCh. 17 - Prob. 17.142RPCh. 17 - Prob. 17.143RPCh. 17 - A square block of mass m is falling with a...Ch. 17 - Prob. 17.145RPCh. 17 - A 1.8-lb javelin DE impacts a 10-lb slender rod...
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moment of inertia; Author: NCERT OFFICIAL;https://www.youtube.com/watch?v=A4KhJYrt4-s;License: Standard YouTube License, CC-BY