VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS
VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS
12th Edition
ISBN: 9781260265453
Author: BEER
Publisher: MCG
bartleby

Concept explainers

bartleby

Videos

Textbook Question
Book Icon
Chapter 19.2, Problem 19.50P

A small collar of mass 1 kg is rigidly attached to a 3-kg uniform rod of length L = 750 mm. Determine (a) the distance d to maximize the frequency of oscillation when the rod is given a small initial displacement, (b) the corresponding period of oscillation.

Chapter 19.2, Problem 19.50P, A small collar of mass 1 kg is rigidly attached to a 3-kg uniform rod of length L = 750 mm.

Fig. P19.50

(a)

Expert Solution
Check Mark
To determine

The distance d to maximize the frequency of oscillation when the rod is given a small initial displacement.

Answer to Problem 19.50P

The distance d to maximize the frequency of oscillation when the rod is given a small initial displacement is 227mm_.

Explanation of Solution

Given information:

The mass (mC) of the collar is 1 kg.

The mass (mR) of the rod AB is 3 kg.

The length (L) of the rod AB is 750 mm.

The acceleration due to gravity (g) is 9.81m/s2.

Calculation:

Show the free-body-diagram equation as in Figure (1).

VECTOR MECH...,STAT.+DYN.(LL)-W/ACCESS, Chapter 19.2, Problem 19.50P

The external forces in the system are forces due mass of the collar and the rod. The effective force in the system is mca¯t and the effective restoring couple is I¯θ¨.

Take moment about A in the system for external forces.

(MA)external=(mrg×L2sinθ)+(mcg×dsinθ)=(mrL2+mcd)gsinθ

For small oscillation sinθθ.

Take moment about A in the system for effective forces.

(MA)effective=(mr(a¯t)r×L2)(mc(a¯t)c×d)(I¯θ¨)=mrL2(a¯t)rmcd(a¯t)cI¯θ¨

The tangential component of acceleration for the rod (a¯t)r is equal to the product of distance at which the weight of the rod acts and angular acceleration (L2θ¨).

The tangential component of acceleration for the collar (a¯t)c is equal to the product of distance at which the collar is added and angular acceleration (dθ¨).

Thus, express the moment about A due to the effective forces as:

(MA)effective=mrL2(L2θ¨)mcd(dθ¨)I¯θ¨=mr(L2)2θ¨mcd2θ¨I¯θ¨=(mrL24+mcd2+I¯)θ¨

Equate the moment about A in the system for external and effective forces.

(MA)external=(MA)effective(mrL2+mcd)gθ=(mrL24+mcd2+I¯)θ¨θ¨=mrL2+mcdmrL24+mcd2+I¯gθθ¨+(mrL2+mcd)gmrL24+mcd2+I¯θ=0 (1)

Compare the differential Equation (1) with the general differential equation of motion (x¨+ωn2x=0) and express the natural circular frequency of oscillation (ωn):

ωn2=(mrL2+mcd)gmrL24+mcd2+I¯ (2)

Write the expression for moment of inertia of the rod:

I¯=112mrL2

Substitute 1 kg for mc, 3 kg for mr, 750 mm for L, 9.81m/s2 for g, and (1/12)mrL2 for I¯ in Equation (2).

ωn2=(mrL2+mcd)gmrL24+mcd2+I¯=((3kg)(750mm)2+(1kg)d)(9.81m/s2)(3kg)(750mm)24+(1kg)d2+(112(3kg)(750mm)2)=(1.5(750mm×1m1000mm)+d)(9.81)0.75(750mm×1m1000mm)2+d2+(14(750mm×1m1000mm)2)

=(1.5(0.75m)+d)(9.81)0.75(0.75m)2+d2+(14(0.75m)2)=9.81(1.125+d)0.421875+d2+0.140625=9.81(1.125+d)0.5625+d2 (3)

Calculate the value of d to maximize the natural frequency:

Differentiate Equation (3) with respect to d.

ωn2=9.81(1.125+d)0.5625+d2d(ωn2)dd=9.81{(0.5625+d2)(1)(1.125+d)(2d)}(0.5625+d2)2d(ωn2)dd=9.81{0.5625+d22.25d2d2}(0.5625+d2)2d(ωn2)dd=9.81{0.56252.25dd2}(0.5625+d2)2

Equate d(ωn2)dd to zero and solve for d.

d(ωn2)dd=09.81{0.56252.25dd2}(0.5625+d2)2=00.56252.25dd2=0d2+2.25d0.5625=0 (4)

Solve the above quadratic equation:

Express the roots of a quadratic equation:

x=b±b24ac2a

Substitute d for x, 1 for a, 2.25 for b, and -0.5625 for c to find the roots of the Equation (4).

d=(2.25)±(2.25)24(1)(0.5625)2(1)=2.25±5.0625+2.252=2.25±2.7042=2.25+2.7042or2.252.7042

=0.227mor2.4771m=0.227(1,000 mm1 m)or2.4771m(1,000 mm1 m)=227 mm or 2477.1 mm

Therefore, the distance d to maximize the frequency of oscillation when the rod is given a small initial displacement is 227mm_.

(b)

Expert Solution
Check Mark
To determine

The corresponding period (τn) of oscillation.

Answer to Problem 19.50P

The corresponding period (τn) of oscillation is 1.352sec_.

Explanation of Solution

Given information:

The mass (mC) of the collar is 1 kg.

The mass (mR) of the rod AB is 3 kg.

The length (L) of the rod AB is 750 mm.

The acceleration due to gravity (g) is 9.81m/s2.

Calculation:

Calculate the value of maximum natural circular frequency ωn:

Substitute 0.227 m for d in Equation (3)

ωn2=9.81(1.125+d)0.5625+d2ωn2=9.81(1.125+(0.227m))0.5625+(0.227m)2ωn2=13.263120.614029ωn=21.6ωn=4.6476rad/s

Calculate the time period of oscillation (τn) using the relation:

τn=2πωn

Substitute 4.6476rad/s for ωn.

τn=2π4.6476rad/s=1.352s

Therefore, the corresponding period (τn) of oscillation is 1.352sec_.

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
A small collar of mass 1 kg is rigidly attached to a 3-kg uniform rod of length L = 750 mm. Determine (a) the distance d to maximize the frequency of oscillation when the rod is given a small initial displacement, (b) the corresponding period of oscillation.
Α Ο CH B d PROBLEM 19.50 A small collar of mass 1 kg is rigidly attached to a 3-kg uniform rod of length L = 750 mm. Determine (a) the distance d to maximize the frequency of oscillation when the rod is given a small initial displacement, (b) the corresponding period of oscillation.
A 6-lb slender rod is suspended from a steel wire that is known to have a torsional spring constant K=1.5 ft.lb/rad. If the rod is rotated through 180° about the vertical and released, determine (a ) the period of oscillation, (b ) the maximum velocity of end A of the rod.

Chapter 19 Solutions

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

Ch. 19.1 - Prob. 19.11PCh. 19.1 - Prob. 19.12PCh. 19.1 - Prob. 19.13PCh. 19.1 - Prob. 19.14PCh. 19.1 - A 5-kg collar C is released from rest in the...Ch. 19.1 - Prob. 19.16PCh. 19.1 - Prob. 19.17PCh. 19.1 - An 11-lb block is attached to the lower end of a...Ch. 19.1 - Block A has a mass m and is supported by the...Ch. 19.1 - A 13.6-kg block is supported by the spring...Ch. 19.1 - Prob. 19.21PCh. 19.1 - 19.21 and 19.22A 50-kg block is supported by the...Ch. 19.1 - Prob. 19.23PCh. 19.1 - The period of vibration of the system shown is...Ch. 19.1 - Prob. 19.25PCh. 19.1 - Prob. 19.26PCh. 19.1 - From mechanics of materials, it is known that for...Ch. 19.1 - From mechanics of materials it is known that when...Ch. 19.1 - Prob. 19.29PCh. 19.1 - Prob. 19.30PCh. 19.1 - If h = 700 mm and d = 500 mm and each spring has a...Ch. 19.1 - Prob. 19.32PCh. 19.1 - Prob. 19.33PCh. 19.1 - Prob. 19.34PCh. 19.1 - Prob. 19.35PCh. 19.1 - Prob. 19.36PCh. 19.2 - The 9-kg uniform rod AB is attached to springs at...Ch. 19.2 - Prob. 19.38PCh. 19.2 - Prob. 19.39PCh. 19.2 - Prob. 19.40PCh. 19.2 - A 15-lb slender rod AB is riveted to a 12-lb...Ch. 19.2 - A 20-lb uniform cylinder can roll without sliding...Ch. 19.2 - A square plate of mass m is held by eight springs,...Ch. 19.2 - Prob. 19.44PCh. 19.2 - Prob. 19.45PCh. 19.2 - A three-blade wind turbine used for research is...Ch. 19.2 - A connecting rod is supported by a knife-edge at...Ch. 19.2 - A semicircular hole is cut in a uniform square...Ch. 19.2 - A uniform disk of radius r = 250 mm is attached at...Ch. 19.2 - A small collar of mass 1 kg is rigidly attached to...Ch. 19.2 - Prob. 19.51PCh. 19.2 - Prob. 19.52PCh. 19.2 - Prob. 19.53PCh. 19.2 - Prob. 19.54PCh. 19.2 - The 8-kg uniform bar AB is hinged at C and is...Ch. 19.2 - Prob. 19.56PCh. 19.2 - Prob. 19.57PCh. 19.2 - Prob. 19.58PCh. 19.2 - Prob. 19.59PCh. 19.2 - Prob. 19.60PCh. 19.2 - Two uniform rods, each of weight W = 24 lb and...Ch. 19.2 - A homogeneous rod of mass per unit length equal to...Ch. 19.2 - Prob. 19.63PCh. 19.2 - Prob. 19.64PCh. 19.2 - A 60-kg uniform circular plate is welded to two...Ch. 19.2 - Prob. 19.66PCh. 19.2 - Prob. 19.67PCh. 19.2 - The centroidal radius of gyration ky of an...Ch. 19.3 - Two blocks each have a mass 1.5 kg and are...Ch. 19.3 - Prob. 19.70PCh. 19.3 - Prob. 19.71PCh. 19.3 - Prob. 19.72PCh. 19.3 - Prob. 19.73PCh. 19.3 - Prob. 19.74PCh. 19.3 - Prob. 19.75PCh. 19.3 - Prob. 19.76PCh. 19.3 - Prob. 19.77PCh. 19.3 - Blade AB of the experimental wind-turbine...Ch. 19.3 - A 15-lb uniform cylinder can roll without sliding...Ch. 19.3 - Prob. 19.80PCh. 19.3 - Prob. 19.81PCh. 19.3 - Prob. 19.82PCh. 19.3 - Prob. 19.83PCh. 19.3 - Prob. 19.84PCh. 19.3 - A homogeneous rod of weight W and length 2l is...Ch. 19.3 - A 10-lb uniform rod CD is welded at C to a shaft...Ch. 19.3 - Prob. 19.87PCh. 19.3 - Prob. 19.88PCh. 19.3 - Prob. 19.89PCh. 19.3 - Prob. 19.90PCh. 19.3 - Prob. 19.91PCh. 19.3 - Prob. 19.92PCh. 19.3 - Prob. 19.93PCh. 19.3 - A uniform rod of length L is supported by a...Ch. 19.3 - Prob. 19.95PCh. 19.3 - Three collars each have a mass m and are connected...Ch. 19.3 - Prob. 19.97PCh. 19.3 - As a submerged body moves through a fluid, the...Ch. 19.4 - A 4-kg collar can slide on a frictionless...Ch. 19.4 - Prob. 19.100PCh. 19.4 - A collar with mass m that slides on a frictionless...Ch. 19.4 - Prob. 19.102PCh. 19.4 - The 1.2-kg bob of a simple pendulum of length l =...Ch. 19.4 - Prob. 19.104PCh. 19.4 - A precision experiment sits on an optical table...Ch. 19.4 - Prob. 19.106PCh. 19.4 - Prob. 19.107PCh. 19.4 - The crude-oil pumping rig shown is driven at 20...Ch. 19.4 - Prob. 19.109PCh. 19.4 - Prob. 19.110PCh. 19.4 - Prob. 19.111PCh. 19.4 - Rod AB is rigidly attached to the frame of a motor...Ch. 19.4 - Prob. 19.113PCh. 19.4 - Prob. 19.114PCh. 19.4 - A motor of weight 100 lb is supported by four...Ch. 19.4 - Prob. 19.116PCh. 19.4 - Prob. 19.117PCh. 19.4 - Prob. 19.118PCh. 19.4 - Prob. 19.119PCh. 19.4 - One of the tail rotor blades of a helicopter has...Ch. 19.4 - Prob. 19.121PCh. 19.4 - Prob. 19.122PCh. 19.4 - Prob. 19.123PCh. 19.4 - Prob. 19.124PCh. 19.4 - A 60-lb disk is attached with an eccentricity e =...Ch. 19.4 - A small trailer and its load have a total mass of...Ch. 19.5 - Prob. 19.127PCh. 19.5 - Prob. 19.128PCh. 19.5 - Prob. 19.129PCh. 19.5 - Prob. 19.130PCh. 19.5 - Prob. 19.131PCh. 19.5 - Prob. 19.132PCh. 19.5 - Prob. 19.133PCh. 19.5 - Prob. 19.134PCh. 19.5 - Prob. 19.135PCh. 19.5 - Prob. 19.136PCh. 19.5 - Prob. 19.137PCh. 19.5 - Prob. 19.138PCh. 19.5 - A machine element weighing 500 lb is supported by...Ch. 19.5 - Prob. 19.140PCh. 19.5 - Prob. 19.141PCh. 19.5 - Prob. 19.142PCh. 19.5 - Prob. 19.143PCh. 19.5 - A 36-lb motor is bolted to a light horizontal beam...Ch. 19.5 - One of the tail rotor blades of a helicopter has...Ch. 19.5 - Prob. 19.146PCh. 19.5 - Prob. 19.147PCh. 19.5 - Prob. 19.148PCh. 19.5 - Prob. 19.149PCh. 19.5 - Prob. 19.150PCh. 19.5 - The suspension of an automobile can be...Ch. 19.5 - Prob. 19.152PCh. 19.5 - Prob. 19.153PCh. 19.5 - Prob. 19.154PCh. 19.5 - 19.155 and 19.156 Draw the electrical analog of...Ch. 19.5 - Prob. 19.156PCh. 19.5 - 19.157 and 19.158Write the differential equations...Ch. 19.5 - 19.157 and 19.158Write the differential equations...Ch. 19 - An automobile wheel-and-tire assembly of total...Ch. 19 - Prob. 19.160RPCh. 19 - Disks A and B weigh 30 lb and 12 lb, respectively,...Ch. 19 - A small trailer and its load have a total mass of...Ch. 19 - A 0.8-lb ball is connected to a paddle by means of...Ch. 19 - Prob. 19.164RPCh. 19 - A 4-lb uniform rod is supported by a pin at O and...Ch. 19 - Prob. 19.166RPCh. 19 - Prob. 19.167RPCh. 19 - A small ball of mass m attached at the midpoint of...Ch. 19 - Prob. 19.169RPCh. 19 - If either a simple or a compound pendulum is used...
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