Machining Processes PDF

Summary

This document is a presentation on machining processes, focusing on turning and boring. It explains the principles and operations involved in turning cylindrical and conical surfaces using a lathe. Diagrams illustrate the process and various types of turning and boring are discussed.

Full Transcript

Machining Processes

Turning and Boring Processes

Dr.-Ing. Amr Nounou
Introduction
Turning is the
process of machining
external cylindrical
and conical surfaces.

It is usually
performed on a
machine tool called a
lathe.

Relatively simple
work and tool
movements are
involved in turning a
Schematic of a standard engine lathe performing a turning
cylindrical surface. operation, with the cutting tool shown in inset.
(Courtesy J T. Black)

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 2
Introduction
The workpiece is rotated
and
the single-point cutting tool
is fed longitudinally into the
workpiece
and
then travels parallel to the
axis of workpiece rotation,
reducing the diameter by the
depth of cut (DOC). Basics of the turning process normally done on a lathe.
The dashed arrows indicate the feed motion of the tool
relative to the work.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 3
Introduction
The tool feeds at a rate,
fr, cutting at a speed, V,
in units of surface feet
per minute (sfpm),
which is used to
determine the revolutions
per minute (rpm) of the
workpiece.

Basics of the turning process normally done on a lathe.
The dashed arrows indicate the feed motion of the tool
relative to the work.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 4
Introduction
Basic turning machines can rotate the
work and feed the tool longitudinally
for turning and can perform other
operations by feeding transversely.

Depending on what direction the tool
is fed and on what portion of the
rotating workpiece is being machined,
the operations have different names.

The dashed arrows indicate the tool
feed motion relative to the workpiece.

(Courtesy J T. Black)

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 5
Introduction
If the tool is fed at an angle to the
axis of rotation, an external conical
surface results.
This is called taper turning.

If the tool is fed to the axis of
rotation, using a tool that is wider
than the depth of the cut, the
operation is called facing,
and
a flat surface is produced on the
end of the cylinder.
(Courtesy J T. Black)

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 6
Introduction
By using a tool having a specific form or
shape and feeding it radially or inward
against the work, external cylindrical,
conical, and irregular surfaces of limited
length can also be turned.

The shape of the resulting surface is (Courtesy J T. Black)

determined by the shape and size of the
cutting tool.

Such machining is called form turning.

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 7
Introduction
If the tool is fed all the way
to the axis of the workpiece,
it will be cut in two.
This is called parting or
cutoff, and a simple, thin
tool is used.

A similar tool is used for
necking or partial cutoff.

(Courtesy J T. Black)

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 8
Introduction
Boring is a variation of turning.

Essentially, boring is internal turning.

Boring can use single-point cutting tools to
produce internal cylindrical or conical surfaces.

It does not create the hole but, rather,
machines or opens the hole up to a specific
size.

Boring can be done on most machine tools
that can do turning. (Courtesy J T. Black)

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 9
Introduction

Other operations, such as
threading and knurling,
can be done on machines
used for turning.

(Courtesy J T. Black)

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 10
Introduction

In addition, drilling can be
done on the rotation axis of
the work.

(Courtesy J T. Black)

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 11
Fundamentals of Turning, Boring, and Facing Turning
Turning constitutes the majority of lathe work.

If good finish and accurate size are desired, one or more roughing cuts are usually
followed by one or more finishing cuts.

In roughing cuts, large depths of cut are used.

Finishing cuts are light, usually being less than 0.015 in. in depth, with the feed as fine
as necessary to give the desired finish.

In most cases, one finishing cut is all that is required.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 12
Fundamentals of Turning,
Boring, and Facing Turning

To determine the inputs to the machines, the
depth of cut, cutting speed, and feed rate
must be selected.

The desired cutting speed establishes the
necessary rpm (Ns) of the rotating workpiece.
The feed fr is given in inches per revolution
(ipr).
The depth of cut is d, where

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 13
Fundamentals of Turning, Boring,
and Facing Turning
The inputs to the turning process are
determined as follows;
Based on the material being machined and the
cutting tool material being used, the engineer
selects the cutting speed, V, in feet per minute,
the feed (fr), and the depth of cut.

The rpm value for the machine tool can be
determined by calculating Ns, (using the larger
diameter), where the factor of 12 is used to
convert feet to inches.

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 14
Fundamentals of Turning,
Boring, and Facing Turning
The length of cut is the distance traveled
parallel to the axis L plus some allowance
or overrun A to allow the tool to enter
and/or exit the cut.

The cutting time is

where A is overrun allowance and fr is the
selected feed in inches per revolution

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 15
Fundamentals of Turning, Boring, and Facing Turning
The metal removal rate (MRR) is

An approximate equation that assumes that the depth of cut d is small compared to the uncut diameter D1.

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 16
Fundamentals of Turning, Boring, and Facing Turning

Basic movement of boring, facing, and cutoff in a lathe, where cutting is performed by one-
single-point cutting tool at a time and the tool can be fed in any direction.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 17
Fundamentals of Turning, Boring, and
Facing Turning
Boring

Boring always involves the enlarging of an existing hole, which
may have been made by drilling or may be the result of a core in
a casting.

Holes may be bored straight, tapered, with threads, or to
irregular contours.

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 18
Fundamentals of Turning, Boring, and Facing Turning

Boring
As before V and fr are selected. For a cut of length L, the cutting
time is

where

for D1, the diameter of bore, and A, the overrun allowance.

The metal removal rate is
where D2 is the original hole diameter;

(omitting allowance term), where d is the depth of cut.

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 19
Fundamentals of Turning, Boring,
and Facing Turning
Facing

Facing is the producing of a flat surface as the
result of the tool being fed across the end of the
rotating workpiece.

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 20
Fundamentals of Turning, Boring, and
Facing Turning
Facing

The cutting speed should be determined from the largest diameter of
the surface to be faced.

In facing, the tool feeds perpendicular to the axis of the rotating
workpiece. Because the rpm is constant, the cutting speed is
continually decreasing as the axis is approached.

The length of cut L is D1/2 or (D1 – D2)/2 for a tube.

where d is the depth of cut and L = D1/2 is the length of cut.

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 21
Fundamentals of Turning, Boring, and
Facing Turning
Parting
Parting is the operation by which one section of a workpiece is
disconnected from the remainder by means of a cutoff tool.

The tool should be set exactly at the height of the axis of rotation,
be kept sharp, have proper clearance angles, and be fed into the
workpiece at a proper and uniform feed rate.

The tool is fed (plunged) perpendicular to the rotational axis, as it
was in facing.

The length of cut for solid bars is D1/2. For tubes,

In cutoff operations, the width of the tool is d in inches, the width of
the cutoff operation. The equations for Tm and MRR are then
basically the same as for facing.

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 22
Fundamentals of Turning, Boring, and Facing Turning
Drilling

Drilling can be done on lathes with the drill mounted in the tailstock quill of engine lathes or the
turret on turret lathes and fed against a rotating workpiece.

Coolants should be used where required.

In drilling deep holes, the drill should be withdrawn occasionally to clear chips from the hole and to
aid in getting coolant to the cutting edges. This is called peck drilling.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 23
Lathe Design and Terminology

Knowing the terminology of a machine tool is fundamental to understanding;

- how it performs the basic operations,

- how the workholding devices are interchanged,

- and how the cutting tools are mounted and interfaced to the work.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 24
Lathe Design and Terminology

Lathes are machine tools designed primarily to do turning, facing, and boring.

Very little turning is done on other types of machine tools, and none can do it with equal
ability.

Lathes also can do drilling.

Consequently, the lathe is probably the most common machine tool, along with milling
machines.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 25
Lathe Design and
Terminology
Lathe Design

The essential components of an
engine lathe are

the bed, headstock assembly
(which includes the spindle),
tailstock assembly,

carriage assembly, quick-change
gearbox, and the leadscrew and
feed rod. Schematic of an engine lathe, a versatile machine tool that is easy
to set up and operate and is intended for short-run jobs.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 26
Lathe Design and Terminology
Lathe Design – the bed

The bed is the base and backbone of a lathe.

Two sets of parallel, longitudinal ways, inner and
outer, are contained on the bed.

Any inaccuracy in them usually means that the
accuracy of the entire lathe is destroyed. Schematic of an engine lathe, a versatile machine tool
that is easy to set up and operate and is intended for
short-run jobs.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 27
Lathe Design and
Terminology
Lathe Design – the headstock

The headstock, mounted in a fixed position on
the inner ways, provides powered means to
rotate the work at various rpm values.

Essentially, it consists of a hollow spindle,
mounted in accurate bearings, and a set of
transmission gears through which the spindle
can be rotated at a number of speeds.

The spindle protrudes from the gearbox and Schematic of an engine lathe, a versatile machine tool
contains means for mounting various types of that is easy to set up and operate and is intended for
workholding devices (chucks, face and dog short-run jobs.
plates, collets).

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 28
Lathe Design and Terminology
Lathe Design – the tailstock

The tailstock assembly consists, essentially, of
three parts.

A lower casting fits on the inner ways of the bed,
can slide longitudinally, and can be clamped in
any desired location.

An upper casting fits on the lower one and can be
moved transversely upon it, on some type of
keyed ways, to permit aligning the tailstock and
headstock spindles (for turning tapers).
Schematic of an engine lathe, a versatile machine tool
that is easy to set up and operate and is intended for
The third major component of the assembly is the short-run jobs.
tailstock quill which is a hollow steel cylinder.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 29
Lathe Design and Terminology
Lathe Design – the carriage assembly

The carriage assembly, together with the apron,
provides the means for mounting and moving
cutting tools.

The carriage, a relatively flat H-shaped casting,
rides on the outer set of ways on the bed.

The cross slide is mounted on the carriage and can
be moved by means of a feed screw that is
controlled by a small handwheel and a graduated
dial. The cutting tools for lathe work are held in the tool
post on the compound rest, which can translate and
swivel.
(Courtesy J T. Black)

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 30
Lathe Design and Terminology
Lathe Design

On most lathes, the tool post is mounted on a
compound rest.

The compound rest can rotate and translate with
respect to the cross slide, permitting further
positioning of the tool with respect to the work.

The apron, attached to the front of the carriage,
has the controls for providing manual and powered
motion for the carriage and powered motion for the
cross slide.

The cutting tools for lathe work are held in the tool
The carriage is moved parallel to the ways by post on the compound rest, which can translate and
turning a handwheel on the front of the apron. swivel.
(Courtesy J T. Black)

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 31
Lathe Design and Terminology
Size Designation of Lathes

The size of a lathe is designated by two dimensions.

The first is known as the swing. This is the maximum diameter of work that can be
rotated on a lathe.

The second size dimension is the maximum distance between centers.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 32
Lathe Design and Terminology
Types of Lathes

Lathes used in manufacturing can be classified as speed, engine, toolroom, turret,
automatics, tracer, and numerical control turning centers.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 33
Lathe Design and Terminology
Types of Lathes – Engine lathes

Engine lathes are the type most frequently used in
manufacturing.

They are heavy-duty machine tools with all the
components described previously and have power
drive for all tool movements except on the
compound rest.

Although engine lathes are versatile and very
useful, the time required for changing and setting
tools and for making measurements on the
workpiece is often a large percentage of the cycle
time. Schematic of an engine lathe, a versatile machine
tool that is easy to set up and operate and is
Turret lathes, and other types of semiautomatic intended for short-run jobs.
and automatic lathes have been highly developed
and are widely used in manufacturing as another
means to improve cutting productivity.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 34
Lathe Design and Terminology
Types of Lathes – Turret Lathes

Basically, a longitudinally feedable,
hexagon turret replaces the tailstock.

The turret, on which six tools can be
mounted, can be rotated to bring each
tool into operating position, and the
entire unit can be translated parallel to
the ways to provide feed for the tools.
Turret lathe

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 35
Lathe Design and Terminology
Types of Lathes – Turret Lathes

The square turret on the cross slide
can be rotated manually about a
vertical axis to bring each of the four
tools into operating position.

On most machines, the turret can be
moved transversely, either manually or
by power, by means of the cross slide,
and longitudinally through power or
manual operation of the carriage.
Turret lathe
In most cases, a fixed tool holder also
is added to the back end of the cross
slide; this often carries a parting tool.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 36
Lathe Design and Terminology
Types of Lathes – Turret Lathes

Through these basic features of a turret lathe, a number of tools can be set up on the
machine and then quickly be brought successively into working position.

In this way, a complete part can be machined without the necessity for further adjusting,
changing tools, or making measurements.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 37
Cutting Tools
for Lathes
Lathe Cutting Tools

Because tool materials are
expensive, it is desirable
to use as little as possible.

At the same time, it is
essential that the cutting
tool be supported in a
strong, rigid manner to
minimize deflection and
possible vibration.

Consequently, lathe tools
are supported in various
Common types of forged tool holders:
types of heavy, forged (a) right-hand turning, (b) facing, (c) grooving cutoff,
steel tool holders. (d) boring, (e) threading.
(Courtesy of Armstrong Industrial Hand Tools)

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 38
Cutting Tools for Lathes
Lathe Cutting Tools

Typical insert shapes, available cutting edges per insert, and insert holders for throwaway insert cutting tools.
(Adapted from Turning Handbook of High Efficiency Metal Cutting, Courtesy Armstong Industrial Hand Tools)

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 39
Cutting Tools for Lathes
Lathe Cutting Tools

When lathes are incorporated into lean
manufacturing cells where many different
operations are performed, the time required
for changing and setting tools may constitute
as much as 50% of the total cycle time.

Quick-change tool holders can reduce the
manual tool-changing time.
The individual tools, preset in their holders,
can be interchanged in the special tool post
in a few seconds.

With some systems, a second tool may be
set in the tool post while a cut is being made
with the first tool and can then be brought Quick-change tool post and accompanying tool holders.
into proper position by rotating the post. (Courtesy of Armstong Industrial Hand Tools)

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 40
Cutting Tools for Lathes
Turret-Lathe Tools

Turret-lathe tooling setup for producing part shown. Numbers in circles indicate the sequence of the
operations from 1 to 9. The letters A through F refer to the surfaces being machined. Operation 3 is
a combined operation. The roll turner is turning surface F, while tool 3 on the square post is turning
surface B. The first operation stops the stock at the right length. The last operation cuts the finished
bar off and puts a chamfer on the bar, which will next be advanced to the stock stop.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 41
Workholding in Lathes
Workholding Devices for Lathes

Five methods are commonly used for supporting workpieces in lathes:
1.Held between centers.
2.Held in a chuck.
3.Held in a collet.
4.Mounted on a faceplate.
5.Mounted on the carriage.

In the first four of these methods, the workpiece is rotated during machining.

In the fifth method, which is not used extensively, the tool rotates while the workpiece is
fed into the tool.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 42
Workholding in Lathes
Workholding Devices for
Lathes

Lathe Centers

Workpieces that are relatively long
with respect to their diameters are
usually held
between centers.

Two lathe centers are used, one in
the spindle hole and the other in the
hole in the tailstock quill.

Before a workpiece can be mounted
between lathe centers, a center hole Work being turned between centers in a lathe, showing the
must be drilled in each end. use of a carriage (dog) and catch plate (dog plate).

(Courtesy of South Bend Lathe)

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 43
Workholding in
Lathes
Workholding Devices for
Lathes

Lathe Centers

Because the work and the center of
the headstock end rotate together,
no lubricant is needed in the center
hole at this end.

The center in the tailstock quill does
not rotate; adequate lubrication
must be provided.

Live centers are often used in the Work being turned between centers in a lathe, showing the use of a
tailstock to overcome these carriage (dog) and catch plate (dog plate).
problems.
(Courtesy of South Bend Lathe)

Turning and Boring Processes Adapted from the source: DeGarmo's Materials
and Processes in Manufacturing, SI Version, 12th
Edition, Global Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 44
Workholding in Lathes
Workholding Devices for
Lathes

Lathe Chucks

Lathe chucks are used
to support a wider variety of
workpiece shapes
and
to permit more operations to be
performed (than held between
centers).

Two basic types of chucks are used,
three-jaw and four-jaw.

The jaws on chucks for lathes (four-jaw independent or three-jaw self-
centering) can be removed and reversed.

Turning and Boring Processes Source: DeGarmo's Materials and Processes in
Manufacturing, SI Version, 12th Edition, Global
Edition, Wiley, 2017.
Dr.-Ing. Amr Nounou - Winter 2024-2025 45
Enhance your German terminology …

English term German term
Turning Drehen
Diameter Durchmesser
Length Länge
Speed Geschwindigkeit

Turning and Boring Processes

Dr.-Ing. Amr Nounou - Winter 2024-2025 46
 Thank you for your attention...
Turning and Boring Processes

Dr.-Ing. Amr Nounou - Winter 2024-2025 47