Manufacturing Engineering & Technology
7th Edition
ISBN: 9780133128741
Author: Serope Kalpakjian, Steven Schmid
Publisher: Prentice Hall
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Textbook Question
Chapter 14, Problem 1RQ
What is the difference between cold, warm, and hot forging?
Expert Solution & Answer
To determine
What is the difference between cold, warm, and hot forging?
Explanation of Solution
| Cold forging | Warm forging |
Hot forging |
| Cold forging includes impression die forging or true closed die forging having lubricant and circular dies at or around thenormal temperature. | The temperature for warm forging of steel varies from above normal temperature to below the recrystallization temperature. |
Hot forging refers to the plastic deformation of metal at strain rate and a temperature which help in recrystallizingconcurrently with the process of deforming. This way, strain hardening at recrystallizing temperature is evaded. |
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Problem4.
The thin uniform disk of mass m = 1-kg and radius R = 0.1m spins about the bent shaft OG with
the angular speed w2 = 20 rad/s. At the same time, the shaft rotates about the z-axis with the angular
speed 001 = 10 rad/s. The angle between the bent portion of the shaft and the z-axis is ẞ = 35°. The
mass of the shaft is negligible compared to the mass of the disk.
a. Find the angular momentum of the disk with respect to point G, based on the axis
orientation as shown. Include an MVD in your solution.
b. Find the angular momentum of the disk with respect to point O, based on the axis
orientation as shown. (Note: O is NOT the center of fixed-point rotation.)
c. Find the kinetic energy of the assembly.
z
R
R
002
2R
x
Answer: H = -0.046ĵ-0.040 kg-m²/sec
Ho=-0.146-0.015 kg-m²/sec
T 0.518 N-m
=
Problem 3.
The assembly shown consists of a solid sphere of mass m and the uniform slender rod of the same
mass, both of which are welded to the shaft. The assembly is rotating with angular velocity w at a
particular moment. Find the angular momentum with respect to point O, in terms of the axes
shown.
Answer: Ñ。 = ½mc²wcosßsinßĵ + (}{mr²w + 2mb²w + ½ mc²wcos²ß) k
3
m
r
b
2
C
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Only question 2
Chapter 14 Solutions
Manufacturing Engineering & Technology
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