VECTOR MECHANICS FOR ENGINEERS W/CON >B
VECTOR MECHANICS FOR ENGINEERS W/CON >B
12th Edition
ISBN: 9781260804638
Author: BEER
Publisher: MCG
bartleby

Concept explainers

bartleby

Videos

Textbook Question
Book Icon
Chapter 17.1, Problem 17.14P

The double pulley shown has a mass of 15 kg and a centroidal radius of gyration of 160 mm. Cylinder A and block B are attached to cords that are wrapped on the pulleys as shown. The coefficient of kinetic friction between block B and the surface is 0.2. Knowing that the system is at rest in the position shown when a constant force P = 200 N is applied to cylinder A, determine (a) the velocity of cylinder A as it strikes the ground, (b) the total distance that block B moves before coming to rest.

Chapter 17.1, Problem 17.14P, The double pulley shown has a mass of 15 kg and a centroidal radius of gyration of 160 mm. Cylinder

Fig. P17.14

(a)

Expert Solution
Check Mark
To determine

Find the velocity of cylinder A as it strikes the ground.

Answer to Problem 17.14P

The velocity of the cylinder A when it strikes the ground is 4.79m/s_.

Explanation of Solution

Given information:

The mass of the cylinder A is mA=5kg.

The mass of the block B is mB=15kg.

The radius of the outer pulley is rA=250mm.

The radius of the inner pulley is rB=150mm.

The centroidal radius of gyration is kC=160mm.

The coefficient of friction between the surface and the block B is μk=0.20.

The constant force applied at cylinder A is P=200N.

Calculation:

Consider the acceleration due to gravity is g=9.81m/s2.

Consider the radius of the outer pulley as rA.

Consider the radius of the inner pulley as rB.

Find the velocity in the outer pulley (vA) using the relation.

vA=rAωCωC=vArA (1)

Here, the angular velocity of the pulley is ωC.

Find the velocity in the inner pulley (vB) using the relation.

vB=rBωC

Substitute vArA for ωC.

vB=rBvArA (2)

Find the distance of the outer pulley (sA) is in contact using the relation.

sA=rAθCθC=sArA

Here, the number of revolutions in the pulley C is θC.

Find the distance of the inner pulley (sB) is in contact using the relation.

sB=rBθC

Substitute sArA for θC.

sB=rBsArA (3)

The initial total kinetic energy at rest is zero.

T1=0

Find the mass moment of inertia in the pulley C (I¯C) using the equation.

I¯C=mCkC2

Here, the mass in the pulley C is mC.

Substitute 15 kg for mC and 160 mm for kC.

I¯C=15×(160mm×1m1,000mm)2=0.384kgm2

Find the total kinetic energy (T2) at the final stage using the relation.

T2=12mAvA2+12mBvB2+12I¯CωC2

Substitute 5 kg for mA, 15 kg for mB, rBvArA for vB, 0.384kgm2 for I¯C, and vArA for ωC.

T2=12×5×vA2+12×15×(rBvArA)2+12×0.384×(vArA)2

Substitute 250 mm for rA and 150 mm for rB.

T2=12×5×vA2+12×15×(150250vA)2+12×0.384×(vA250mm×1m1,000mm)2=2.5vA2+2.7vA2+3.072vA2=8.272vA2

When sA=1m;

Substitute 150 mm for rB, 1 m for sA and 250 mm for rA in Equation (3).

sB=150×1250=0.6m

Show free-body diagram the block B as in Figure 1.

VECTOR MECHANICS FOR ENGINEERS W/CON >B, Chapter 17.1, Problem 17.14P

Resolve the vertical component of forces as follows;

Fy=0NBmBgcos30°=0NB=15×9.81×cos30°=127.44N

Find the frictional force Ff using the relation.

Ff=μkNB

Substitute 0.20 for μk and 127.44 N for NB.

Ff=0.20×127.44=25.487N

Apply the principle of work and energy for the cylinder A, the block B and the double pulley C as follows;

U12=PsA+mAgsAFfsBmBgsBsin30°

Substitute 200 N for P, 1 m for sA, 5 kg for mA, 9.81m/s2 for g, 25.487 N for Ff, 0.6 m for sB, and 15 kg for mB.

U12=(200×1)+(5×9.81×1)(25.487×0.60)(15×9.81×0.60×sin30°)=200+49.0515.292244.145=189.6128J

Write the equation of work and energy for the system using the equation.

T1+U12=T2

Substitute 0 for T1, 189.6128 J for U12, and 8.272vA2 for T2

0+189.6128=8.272vA2vA=4.7877m/s

Therefore, the velocity of the cylinder A when it strikes the ground is 4.79m/s_.

(b)

Expert Solution
Check Mark
To determine

Find the total distance the block B moves before coming to rest.

Answer to Problem 17.14P

The total distance travelled by the block B before coming to rest is 1.936m_.

Explanation of Solution

Given information:

The mass of the cylinder A is mA=5kg.

The mass of the block B is mB=15kg.

The radius of the outer pulley is rA=250mm.

The radius of the inner pulley is rB=150mm.

The centroidal radius of gyration is kC=160mm.

The coefficient of friction between the surface and the block B is μk=0.20.

The constant force applied at cylinder A is P=200N.

Calculation:

Refer part (a) for vA calculation.

Substitute 4.7877m/s for vA and 250 mm for rA in Equation (1).

ωC=4.7877250mm×1m1,000mm=19.1508rad/s

Substitute 150 mm for rB, 4.7877m/s for vA, and 250 mm for rA in Equation (2).

vB=150×4.7877250=2.87262m/s

Find the total kinetic energy (T3) when the cylinder A strikes the ground.

T3=12mBvB2+12I¯CωC2

Substitute 5 kg for mA, 2.87262m/s for vB, 15 kg for mB, 0.384kgm2 for I¯C, and 19.1508rad/s for ωC.

T3=12×15×2.872622+12×0.384×19.15082=61.89+70.4166=132.3066J

At the final position, the system comes at rest.

The kinetic energy at rest is zero.

T4=0

Apply the principle of work and energy for the block B as follows;

U34=FfsBmBgsBsin30°

Here, the additional distance travelled by the block is sB.

Substitute 9.81m/s2 for g, 25.487 N for Ff, and 15 kg for mB.

U34=25.487×sB15×9.81×sBsin30°=99.062sB

Write the equation of work and energy for the system using the equation.

T3+U34=T4

Substitute 132.3066 J for T3, 99.062sB for U34, and 0 for T4

132.306699.062sB=0sB=1.3356m

Find the total distance (dB) travelled by the block B before coming to rest using the relation.

dB=sB+sB

Substitute 0.6 m for sB and 1.3356 m for sB.

dB=0.6+1.3356=1.9356m

Therefore, the total distance travelled by the block B before coming to rest is 1.936m_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!
Students have asked these similar questions
R αι g The system given on the left, consists of three pulleys and the depicted vertical ropes. Given: ri J₁, m1 R = 2r; απ r2, J2, m₂ m1; m2; M3 J1 J2 J3 J3, m3 a) Determine the radii 2 and 3.
B: Solid rotating shaft used in the boat with high speed shown in Figure. The amount of power transmitted at the greatest torque is 224 kW with 130 r.p.m. Used DE-Goodman theory to determine the shaft diameter. Take the shaft material is annealed AISI 1030, the endurance limit of 18.86 kpsi and a factor of safety 1. Which criterion is more conservative? Note: all dimensions in mm. 1 AA Motor 300 Thrust Bearing Sprocket 100 9750 เอ
Q2: The plate material of a pressure vessel is AISI 1050 QT 205 °C. The plate is rolled to a diameter of 1.2 m. The two sides of the plate are connected via a riveted joint as shown below. If the rivet material is G10500 with HB=197 and all rivet sizes M31. Find the required rivet size when the pressure vessel is subjected to an internal pressure of 500 MPa. Take safety factor = 2. 1.2m A B' A Chope olm 10.5 0.23 hope

Chapter 17 Solutions

VECTOR MECHANICS FOR ENGINEERS W/CON >B

Ch. 17.1 - Prob. 17.6PCh. 17.1 - Prob. 17.7PCh. 17.1 - Prob. 17.8PCh. 17.1 - The 10-in.-radius brake drum is attached to a...Ch. 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 Nm couple...Ch. 17.1 - Prob. 17.13PCh. 17.1 - The double pulley shown has a mass of 15 kg and a...Ch. 17.1 - Gear A has a mass of 1 kg and a radius of gyration...Ch. 17.1 - A slender rod of length l and mass m is pivoted...Ch. 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 - An adapted golf device attaches to a wheelchair to...Ch. 17.1 - A 10-kg storm window measuring 900 1500 mm is...Ch. 17.1 - A collar with a mass of 1 kg is rigidly attached...Ch. 17.1 - A collar with a mass of 1 kg is rigidly attached...Ch. 17.1 - Two identical slender rods AB and BC are welded...Ch. 17.1 - Prob. 17.24PCh. 17.1 - A 100-kg solid cylindrical disk, 800 mm in...Ch. 17.1 - Prob. 17.26PCh. 17.1 - Greek engineers had the unenviable task of moving...Ch. 17.1 - A small sphere of mass m and radius r is released...Ch. 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...Ch. 17.1 - Prob. 17.33PCh. 17.1 - A bar of mass m = 5 kg is held as shown between...Ch. 17.1 - The 1.5-kg uniform slender bar AB is connected to...Ch. 17.1 - The motion of the uniform rod AB is guided by...Ch. 17.1 - Prob. 17.37PCh. 17.1 - Prob. 17.38PCh. 17.1 - The ends of a 9-lb rod AB are constrained to move...Ch. 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...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 - The experimental setup shown is used to measure...Ch. 17.1 - Prob. 17.51PCh. 17.2 - The 350-kg flywheel of a small hoisting engine has...Ch. 17.2 - Prob. 17.2IMDCh. 17.2 - Prob. 17.3IMDCh. 17.2 - Prob. 17.52PCh. 17.2 - A bolt located 2 in. from the center of an...Ch. 17.2 - A small grinding wheel is attached to the shaft of...Ch. 17.2 - A uniform 144-lb cube is attached to a uniform...Ch. 17.2 - Prob. 17.56PCh. 17.2 - Prob. 17.57PCh. 17.2 - Prob. 17.58PCh. 17.2 - Prob. 17.59PCh. 17.2 - Each of the double pulleys shown has a centroidal...Ch. 17.2 - Each of the gears A and B has a mass of 675 g and...Ch. 17.2 - Two identical uniform cylinders of mass m and...Ch. 17.2 - Two identical 16-lb uniform cylinders of radius r...Ch. 17.2 - Prob. 17.64PCh. 17.2 - Prob. 17.65PCh. 17.2 - Show that, when a rigid body rotates about a fixed...Ch. 17.2 - Prob. 17.68PCh. 17.2 - A flywheel is rigidly attached to a 1.5-in.-radius...Ch. 17.2 - A wheel of radius r and centroidal radius of...Ch. 17.2 - Prob. 17.71PCh. 17.2 - 17.72 and 17.73The 3-lb carriage C is supported as...Ch. 17.2 - Prob. 17.73PCh. 17.2 - Two uniform cylinders, each of mass m = 6 kg and...Ch. 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 - A bowler projects an 8.5-in.-diameter ball...Ch. 17.2 - Prob. 17.79PCh. 17.2 - A satellite has a total weight (on Earth) of 250...Ch. 17.2 - Two 10-lb disks and a small motor are mounted on a...Ch. 17.2 - Prob. 17.82PCh. 17.2 - Prob. 17.83PCh. 17.2 - Prob. 17.84PCh. 17.2 - Prob. 17.85PCh. 17.2 - Prob. 17.86PCh. 17.2 - The 30-kg uniform disk A and the bar BC are at...Ch. 17.2 - Prob. 17.88PCh. 17.2 - A 1.8-kg collar A and a 0.7-kg collar B can slide...Ch. 17.2 - Prob. 17.90PCh. 17.2 - A small 4-lb collar C can slide freely on a thin...Ch. 17.2 - Rod AB has a weight of 6 lb and is attached to a...Ch. 17.2 - A 3-kg uniform cylinder A can roll without sliding...Ch. 17.2 - The 4-kg cylinder B and the 3-kg wedge A are at...Ch. 17.2 - The 6-lb steel cylinder A of radius r and the...Ch. 17.3 - A uniform slender rod AB of mass m is at rest on a...Ch. 17.3 - Prob. 17.5IMDCh. 17.3 - Prob. 17.6IMDCh. 17.3 - At what height h above its center G should a...Ch. 17.3 - A bullet weighing 0.08 lb is fired with a...Ch. 17.3 - In Prob. 17.97, determine (a) the required...Ch. 17.3 - A 16-lb wooden panel is suspended from a pin...Ch. 17.3 - Prob. 17.100PCh. 17.3 - A 45-g bullet is fired with a velocity of 400 m/s...Ch. 17.3 - A 45-g bullet is fired with a velocity of 400 m/s...Ch. 17.3 - The tire shown has a radius R = 300 mm and a...Ch. 17.3 - Prob. 17.104PCh. 17.3 - A uniform slender rod AB of mass m is at rest on a...Ch. 17.3 - A uniform slender rod AB is at rest on a...Ch. 17.3 - A bullet of mass m is fired with a horizontal...Ch. 17.3 - Determine the height h at which the bullet of...Ch. 17.3 - A uniform slender bar of length L = 200 mm and...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 - You have been hired to design a baseball catcher...Ch. 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 - A uniform slender rod AB of length L = 600 mm is...Ch. 17.3 - Prob. 17.118PCh. 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 - Prob. 17.121PCh. 17.3 - Prob. 17.122PCh. 17.3 - A slender rod AB is released from rest in the...Ch. 17.3 - Prob. 17.124PCh. 17.3 - Block A has a mass m and is attached to a cord...Ch. 17.3 - Prob. 17.126PCh. 17.3 - 17.127 and 17.128Member ABC has a mass of 2.4 kg...Ch. 17.3 - 17.127 and 17.128Member ABC has a mass of 2.4 kg...Ch. 17.3 - Prob. 17.129PCh. 17.3 - Prob. 17.130PCh. 17.3 - A small rubber ball of radius r is thrown against...Ch. 17.3 - Sphere A of mass m and radius r rolls without...Ch. 17.3 - In a game of pool, ball A is rolling without...Ch. 17 - A uniform disk, initially at rest and of constant...Ch. 17 - The 8-in.-radius brake drum is attached to a...Ch. 17 - A uniform slender rod is placed at corner B and is...Ch. 17 - The motion of the slender 250-mm rod AB is guided...Ch. 17 - A baseball attachment that helps people with...Ch. 17 - Disks A and B are made of the same material, are...Ch. 17 - Disks A and B are made of the same material, are...
Knowledge Booster
Background pattern image
Mechanical Engineering
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, mechanical-engineering and related others by exploring similar questions and additional content below.
Similar questions
SEE MORE QUESTIONS
Recommended textbooks for you
Text book image
Elements Of Electromagnetics
Mechanical Engineering
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Oxford University Press
Text book image
Mechanics of Materials (10th Edition)
Mechanical Engineering
ISBN:9780134319650
Author:Russell C. Hibbeler
Publisher:PEARSON
Text book image
Thermodynamics: An Engineering Approach
Mechanical Engineering
ISBN:9781259822674
Author:Yunus A. Cengel Dr., Michael A. Boles
Publisher:McGraw-Hill Education
Text book image
Control Systems Engineering
Mechanical Engineering
ISBN:9781118170519
Author:Norman S. Nise
Publisher:WILEY
Text book image
Mechanics of Materials (MindTap Course List)
Mechanical Engineering
ISBN:9781337093347
Author:Barry J. Goodno, James M. Gere
Publisher:Cengage Learning
Text book image
Engineering Mechanics: Statics
Mechanical Engineering
ISBN:9781118807330
Author:James L. Meriam, L. G. Kraige, J. N. Bolton
Publisher:WILEY
Ch 2 - 2.2.2 Forced Undamped Oscillation; Author: Benjamin Drew;https://www.youtube.com/watch?v=6Tb7Rx-bCWE;License: Standard youtube license