Metal Forming Processes PDF

Summary

This document provides a general overview of metal forming processes, focusing on rolling operations, and different process categories and types of rolling.

Full Transcript

ROLLING

BULK FORGING
DEFORMATION
METAL FORMING

EXTRUSION
WIRE & BAR
DRAWING

BENDING
DEEP OR CUP
DRAWING
SHEET METAL
WORKING SHEARING

MISCELLANEOUS
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 BULK DEFORMATION PROCESSES
Bulk deformation processes are those where the
thicknesses or cross sections are reduced or
shapes are significantly changed.
Since the volume of the material remains
constant, changes in one dimension require
proportionate changes in others.
Thus the enveloping surface area changes
significantly, usually increasing as the product
lengthens or the shape becomes more complex.
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 BULK DEFORMATION PROCESSES

Starting geometry of the raw material may be:
– cylindrical bars and billets

– rectangular billets and slabs

– or any of the above similar shapes

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 (1) ROLLING
Rolling is a deformation process in which the
thickness of the work is reduced by compressive
forces exerted by two opposing rolls.
Rolling operations reduce the thickness or
change the cross section of a material through
compressive forces exerted by rolls.

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(1) ROLLING

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(1) ROLLING

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 (1) ROLLING
Rotating rolls perform two main functions:
– Pull the work into the gap between them by friction
between workpart and rolls
– Simultaneously squeeze the work to reduce its cross
section

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 (1) ROLLING
Most rolling processes are very capital intensive,
requiring massive pieces of equipment, called rolling
mills, to perform them.
Most rolling is carried out by hot working, called hot
rolling, owing to the large amount of deformation
required.
Hot-rolled metal is generally free of residual
stresses, and its properties are isotropic.
Disadvantages of hot rolling are that the product
cannot be held to close tolerances, and the surface
has a characteristic oxide scale.
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 (1) ROLLING
Rolling is often the first process that is used to
convert material into a finished wrought product
(Products such as; sheet, rod, bar, tube, plate and
wire that are produced by rolling and extrusion
mills as well as forging).
Thick starting stock can be rolled into blooms,
billets, or slabs, or these shapes can be obtained
directly from continuous casting.

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 (1) ROLLING
A slab is a rectangular solid where the width is
greater than twice the thickness (25cm x 4 cm or
more). Or 50 – 150mm thick and width ½ to 1.5
meters
Slabs can be further rolled to produce plate,
sheet, and strip.
A bloom has a square or rectangular cross
section, with a thickness greater than 15 cm and
a width no greater than twice the thickness. (150
–300mm.)
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 (1) ROLLING
A billet is usually smaller than a bloom and has a
square or circular cross section (4cm x 4 cm or
more).
Billets are usually produced by some form of
deformation process, such as rolling or extrusion.
Plates have thickness greater than 6 mm while
sheet and strip range from 6 mm to 0.1 mm.

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 (1) ROLLING

SLAB BLOOM BILLET

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 (1.1) SHAPE ROLLING
In shape rolling, the work is deformed into a
contoured cross section.
Products made by shape rolling include
construction shapes such as I-beams, L-beams,
and U-channels; rails for railroad tracks; and
round and square bars and rods.
The process is accomplished by passing the work
through rolls that have the reverse of the desired
shape.
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(1.1) SHAPE ROLLING

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(1.1) SHAPE ROLLING

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 (1.2) Thread Rolling
Bulk deformation process used to form threads
on cylindrical parts by rolling them between two
dies
Important commercial process for mass
producing bolts and screws
Performed by cold working in thread rolling
machines
Advantages over thread cutting (machining):
– Higher production rates
– Better material utilization
– Stronger threads and better fatigue resistance due to work
hardening
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(1.2) Thread Rolling

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 (1.3) Ring Rolling
Ring rolling is a deformation process in which a
thick-walled ring of smaller diameter is rolled
into a thin-walled ring of larger diameter.
As the thick-walled ring is compressed, the
deformed material elongates, causing the
diameter of the ring to be enlarged.
Ring rolling is usually performed as a hot-working
process for large rings and as a cold-working
process for smaller rings.

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(1.3) Ring Rolling

Reducing the ring
thickness results
in an increase in
its diameter.

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 (1.4) Roll Piercing
Roll Piercing is a specialized hot working process
for making seamless thick-walled tubes.
It utilizes two opposing rolls, and hence it is
grouped with the rolling processes.

Mandrel

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(1) ROLLING MILLS CONFIGURATIONS
Various rolling mill configurations are available to
deal with the variety of applications and
technical problems in the rolling process.
– Two-high – two opposing rolls
– Three-high – work passes through rolls in both
directions
– Four-high – backing rolls support smaller work rolls
– Cluster mill – multiple backing rolls on smaller rolls
– Tandem rolling mill – sequence of two-high mills

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(1.a) Two-High Rolling Mill

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(1.b) Three-High Rolling Mill

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(1.c) Four-High Rolling Mill

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(1.d) Cluster Mill

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(1.e) Tandem Rolling Mill

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 FLAT ROLLING ANALYSIS
In flat rolling, the work is squeezed between two
rolls so that its thickness is reduced by an
amount called the DRAFT:

(1)

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 FLAT ROLLING ANALYSIS
Conservation of matter is preserved, so the
volume of metal exiting the rolls equals the
volume entering

(2)

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 FLAT ROLLING ANALYSIS
Similarly, before and after volume rates of
material flow must be the same, so the before
and after velocities can be related

(3)

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 FLAT ROLLING ANALYSIS
The rolls contact the work along an arc defined
by the angle Ɵ.
Each roll has radius R , and its rotational speed
gives it a surface velocity vr.
This velocity is greater than the entering speed
of the work vo and less than its exiting speed vf.
Since the metal flow is continuous, there is a
gradual change in velocity of the work between
the rolls.
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 FLAT ROLLING ANALYSIS
However, there is one point along the arc where
work velocity equals roll velocity.
This is called the no-slip point, also known as the
neutral point.
On either side of this point, slipping and friction
occur between roll and work.

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 FLAT ROLLING ANALYSIS
The amount of slip between the rolls and the
work can be measured by means of the
FORWARD SLIP, a term used in rolling that is
defined as
(4)

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 FLAT ROLLING ANALYSIS
There is a limit to the maximum possible draft
that can be accomplished in flat rolling with a
given coefficient of friction, defined by:

dmax = µ2 R (5)

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 FLAT ROLLING ANALYSIS
The roll force F required to maintain separation
between the two rolls is given by:

F =σ w L (6)

σ = average flow stress, N/mm2
w L = roll-work contact area, mm2
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 FLAT ROLLING ANALYSIS
Contact length can be approximated by

(7)

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 FLAT ROLLING ANALYSIS
Torque for each roll is

(8)

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 FLAT ROLLING ANALYSIS
The power required to drive each roll is

P = 2πNT (9)

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 FLAT ROLLING NUMERICAL 1
A 40 mm thick plate is to be reduced to 30 mm in
one pass in a rolling operation. Entrance speed =
16 m/min. Roll radius = 300 mm, and rotational
speed = 18.5 m/min. Determine: (a) the
minimum required coefficient of friction that
would make this rolling operation possible, (b)
exit velocity under the assumption that the plate
widens by 2% during the operation, and (c)
forward slip.
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 FLAT ROLLING NUMERICAL 1
to = 40 mm
tf = 30 mm.
vo = 16 m/min.
R = 300 mm
rotational speed = 18.5 m/min.
plate widens by 2% during the operation

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FLAT ROLLING NUMERICAL 1

(5)

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FLAT ROLLING NUMERICAL 1

(3)

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FLAT ROLLING NUMERICAL 1

(4)

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 FLAT ROLLING NUMERICAL 2
A 2.0 in thick slab is 10.0 in wide and 12.0 ft
long. Thickness is to be reduced in three steps in
a hot rolling operation. Each step will reduce the
slab to 25% of its previous thickness. It is
expected that for this metal and reduction, the
slab will widen by 3% in each step. If the entry
speed of the slab in the first step is 40 ft/min,
and roll speed is the same for the three steps,
determine: (a) length and (b) exit velocity of the
slab after the final reduction.
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 FLAT ROLLING NUMERICAL 2
to = 2 in
wo = 10 in.
Lo = 12 ft.
Each step will reduce the slab to 25% of its
previous thickness
widen by 3% in each step
vo = 40 ft/min (same for the three steps)

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FLAT ROLLING NUMERICAL 2

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FLAT ROLLING NUMERICAL 2

(2)

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 FLAT ROLLING NUMERICAL 2
(b) Given that entry speed is the same at all three
steps
(3)

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FLAT ROLLING NUMERICAL 2

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FLAT ROLLING NUMERICAL 2

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 FLAT ROLLING NUMERICAL 3
A series of cold rolling operations are to be used
to reduce the thickness of a plate from 50 mm
down to 25 mm in a reversing two-high mill. Roll
diameter = 700 mm and coefficient of friction
between rolls and work = 0.15. The specification
is that the draft is to be equal on each pass.
Determine: (a) minimum number of passes
required, and (b) draft for each pass?

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 FLAT ROLLING NUMERICAL 3
to = 50 mm
tf = 25 mm.
R = 700/2 mm = 350 mm
µ = 0.15
draft is to be equal on each pass.

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FLAT ROLLING NUMERICAL 3

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