CLASS POWERPOINT - 150102e - LATHES.pdf

Full Transcript

MACHINIST PROGRAM - FIRST PERIOD

LATHES
150102e
 OBJECTIVES
1. DESCRIBE SAFETY PRECAUTIONS WHEN USING A LATHE
2. DESCRIBE THE TYPES, SIZE AND RATED CAPACITY OF
LATHES
3. DESCRIBE THE MAJOR PARTS OF A LATHE AND THEIR
FUNCTION
4. DESCRIBE WORKHOLDING DEVICES USED ON A LATHE
5. DESCRIBE TOOL POSTS AND CUTTING TOOL HOLDERS
OBJECTIVE 1
SAFETY PRECAUTIONS
SAFETY
WHAT ARE SOME GOOD SAFETY PRINCIPLES
TO FOLLOW WHEN USING A LATHE?

Wear appropriate CSA-certified safety glasses.
Make sure entanglement hazards are removed (e.g. loose
clothing, jewellery, etc.). Tie back and confine long hair.
Keep the floor free from obstructions, or slip hazards.
Make sure the lathe has a start/stop button within easy
reach of the operator.

LATHES
SAFETY
Centre-drill work deeply enough to provide support for the
piece while it is turning.
Secure and clamp the piece being worked.
Use a lifting device to handle heavy chucks or work. Refer
to Materials Handling for additional information.
Inspect chucks for wear or damage. Flying pieces can be very
dangerous.
REMOVE CHUCK WRENCH IMMEDIATELY AFTER
ADJUSTING CHUCK.
Remove all tools, measuring instruments and other objects
from saddle or lathe bed before starting machine.

LATHES
SAFETY
Keep all lathe cutting tools sharp.
Ensure that the chip and coolant shields are in place.
Shut off the power supply to the motor before mounting or
removing accessories.
Stop lathe before taking measurements of any kind.
Use a vacuum, brush or rake to remove cuttings only after
the lathe has stopped moving.
Keep working surface clean of scrap, tools and materials.
Keep floor around lathe clean and free of oil and grease.

LATHES
SAFETY

APPROPRIATE CHIP CONTROL
IS A SAFETY REQUIREMENT.

LATHES
OBJECTIVE 2
IDENTIFICATION:
TYPES
SIZES
RATED CAPACITY
LATHES
 SIZING
THREE MAIN METHODS OF SIZING A LATHE:

THE SWING….THE GREATEST DIAMETER
WORKPIECE THAT CAN BE TURNED WITHOUT
HITTING THE WAYS.

DISTANCE BETWEEN CENTERS…. THE LONGEST
WORK THAT COULD BE SUPPORTED BETWEEN
CENTERS ON A LATHE.

LENGTH OF BED…..BASICALLY THE DISTANCE
FROM ONE END OF THE LATHE TO THE OTHER.

LATHES
 COMMON SIZING

Swing (Diameter) Length Between
Size Power
over Bed Centres
in mm in mm Hp kW
1 + +
Small 10 250 30 750 /4 0.2
Medium 20 500 60 to 72 1500 to 1800 5 to 15 3.7 to 11.2
Large 48 1200 240 6000 20 to 60 15 to 45

LATHES
TYPES –
ENGINE LATHE

LATHES
TYPES –
TURRET LATHE

LATHES
TYPES –
AUTOMATIC LATHE
(AUTOMATIC SCREW MACHINE)

LATHES
TYPES –
TRACER LATHE

TRACER LATHE - VIDEO

LATHES
TYPES –
CNC LATHE

PRODUCTION WORK

MORE AND MORE COMMON

CHEAPER AND EASIER TO
PROGRAM

USED FOR ONE OFFS AS
WELL
REQUIRES MORE SKILL
(PROGRAMMING AND
SETUP)

TURNING AND THREADING ON A CNC - VIDEO

LATHES
 OBJECTIVE 3
DESCRIBE THE MAJOR PARTS OF A LATHE
AND THEIR FUNCTION
The Lathe Bed

Rack Gear

Figure 7 - Bed of a lathe.
Flat side allows for
thermal Expansion

Figure 8 - Inverted prism ways.
The Headstock

Figure 9 - Headstock.
Headstock Gears
 Headstock

The headstock of the lathe is attached to the left side of
the bed and houses the spindle, bearings, gears and
belts that drive the spindle.

Levers that control speed and feed selections are
located on the headstock.

The working end of the spindle is called the spindle
nose.

Spindle are manufactured with a Morse Taper in the
bore to permit the mounting of 60 degree Centers
Lathe Components

SPINDLE NOSE TYPES
 Types of spindle noses

Threaded spindle noses
Taper and Key (type L)
Camlock (Type D1)
Figure 10 - Threaded spindle nose.
Figure 11 - Taper and key spindle nose.
D – Style Camlock Spindle Nose

Figure 12 - Cam lock spindle nose.
Lathe Components

Head Stock End or Back
Gear Set
Figure 13 - Back gears.
Lathe Components

The End Gear is a component of the Quick Change Gearbox
Lathe Components

QUICK CHANGE GEARBOX
AND FEED REVERSE LEVER
Feed Reverse
Lever( Used
to reverse the
rotation of the
feed rod and
lead screw

Quick
Change
Gearbox
 Quick Change gear box

The quick-change gear box allows quick and easy
changing of the feed rates.

It allows for the selections of inch and metric threads.

The gears in the quick change gear box provide power to
the lead screw and the feed rod.

The Quick-change gearbox is timed to the spindle
rotation for accurate Feeds and screw thread pitches
Lathe Parts

Lead Screw and Feed Rod
Lead Screw, Feed Rod and Rack

The Lead Screw transmits power to the carriage
for threading. (Often made with 4 TPI, Metric
Lathes would be 6 mm pitch)

The Feed Rod transmits power to the carriage
for longitudinal and cross feeding operations
such as turning, facing and boring.

Feed System Protection : Shear pins and slip clutches
prevent damage from sudden shock or overload.
Thread Chasing Dial

Figure 15 - Lead screw, feed rod and rack.
Half-Nut Engagement Chart
Lathe Components

Lathe Carriage Parts
Figure 16 - Carriage.
Carriage Lock

Carriage lock

Used to face work
pieces in an effort to
eliminate convex or
concave Faces.

Locking the carriage
is very important
when facing large
diameter work
pieces.

Figure 16 - Carriage.
 Carriage
Made up of three main parts of the Carriage include:

Saddle… H shaped casting mounted directly on the ways and moving
longitudinal or parallel to the axis of the spindle.

Cross-slide…sits on top of the saddle and moves at right angles to the axis
of the spindle.

Apron…hangs down in front of the saddle and houses the drive gears,
levers, other devises that control the movements of the carriage.
Note
Lathes are available with
Direct reading Dials and
Indirect Reading Dials.

Direct: All graduations on the
dial are based upon the
amount of material removal
on the work piece. (.001 =.001
off the work piece.

Indirect : The material
removal relates to the
graduated dial reading (.001
on the dial equals.002 off the
diameter. )

Figure 17 - Cross-feed handwheel and graduated dial.
 Compound Rest
Note
The Reading on the
graduated dial on the
compound is actual
value (.001 =.001
movement or an
Indirect dial when
used for diameter
reduction)

Figure 18 - Compound rest.
 Compound Rest

The compound rest can rotate 360 degrees and is made to extend
shoulders or for cutting short steep tapers.

It is used for cutting external and internal tapers.

It is quick and easy to set up and can be dialed in to cut a very
accurate Short taper.
Lathe Apron Assembly

Often called the half nut
lever. Used for threading

Figure 19 - Apron.
 Apron

Controls on the Apron include:
The split-nut lever…closes the split-nut on the lead screw when threading.
Automatic feed lever…engages the power feed for the carriage and cross-
slide.
Feed change lever…selects whether the carriage or cross-slide moves
under power when the automatic feed lever is engaged.
Carriage hand wheel… connected to a pinion gear which is in turn
connected to a rack. Provides longitudinal movement of the carriage
Apron Controls
Lathe Components

Lathe Tailstock
Figure 20 - Tailstock.
 Tailstock
The Tailstock consists of an upper and lower casting , which allows the
tailstock to modify the axis of the lathe for long taper machining.

Tailstock misalignment is corrected by aligning the the upper casting to the
lathe axis.

The spindle bore is manufactured with a Morse taper, (5/8 TPF), and holds
tools such as drills, reamers revolving dead centers etc.
The Tailstock can be used to assist in producing long low
taper angle tapers
Lathe Components

Starting Clutch
Figure 21 - Starting clutch lever.
Clutch Mechanism

Lathe starting clutches can be either:

Electronic

Mechanical
 OBJECTIVE 4
EXPLAIN WORKHOLDING DEVICES USED ON
THE LATHE
 Work Holding Devices

Important features of work holding
devices:

They must hold the work securely

They must hold the work accurately

They must be convenient and quick to use.
Lathe Components

DEAD AND LIVE CENTERS
The solid dead center is A half center allows space
made of hardened steel or for a facing tool
carbide and is considered
the more accurate than the
revolving dead center.
Figure 24 - Solid dead centres. Pg. 17
Figure 27 - Drive plate.
Headstock Center Rotates with the spindle , mounted within
the spindle ( Morse Taper)

Solid Centers that
are mounted in the
Headstock are called
“Live Centers”

Solid Centers that
are mounted in the
tailstock are called
“Dead Centers”

Figure 23 - Live centre in headstock spindle.
 (Drive Plate)

(Dead Center)

Requires the use of high
(Live –Dead center)
pressure lubricant on this
Dead Center (Non-Rotating)
Never part off a workpiece being turned between centers.

Figure 22 - Workpiece held between centres.
Parting tools

Correct

Incorrect
Important : Never part
a workpiece running
between centers
Bearing Centers

Figure 25 - Rotating dead centre.
Bearing Center
Long Nosed Center
Face Drive Center
Face driving center
Bell Center
Lathe Drive Dogs
companion equipment to the Dead and Live Center

Figure 26 - Lathe dogs.
 Chucks

Four main types of chucks
Four jaw independent chuck
Collet chuck
Magnetic chuck
Three jaw universal chuck

Note: Chucks are sized by the diameter of their body
Chucks are sized by the outside diameter of the chuck
body. An 8 inch would have an outside diameter of 8
inches. Figure 28 - Three jaw universal chuck.
Figure 29 - Scroll plate inside three jaw chuck.
Figure 30 - Number on jaw and slot.
Figure 31 - Inside jaws.
Component Mounting in 3 Jaw external grip

Figure 32 - Outside jaws.
Soft Jaws
 3 Jaw Universal Chuck

All three jaws move at once.

A scroll plate on the inside of the chuck engage the teeth on the
back of the jaw.

The Jaws are made as a matching set.

The jaws must be installed in the proper order.
The independent jaw movement of the four jaw
chuck allows the workpiece to be dialed in until it
runs perfectly true.
Figure 33 - Four jaw independent chuck.
 4 Jaw Independent Chuck

All four jaws move independently.
The work piece can be centered more
accurately than in the 3 jaw.
The jaws are reversible.
The 4 jaw supplies more holding power
than the 3 jaw.
Collets are used on stock that has a good finish such as
cold rolled and T&G. They are generally rated for higher
RPM than other chucks.
Figure 37 - Collet chuck.
Magnetic chucks are used for holding flat
magnetic work that cannot be held any
other way. They should only be used for
light cuts only.
Figure 38 - Magnetic chuck.
 Faceplates
Face plates are used to hold work that would be
difficult or impossible to hold in a chuck.

They have T-Slots that enable the work to be
clamped to the surface of the plate.

Counter weights are required when machining
off center work.
Faceplates
 Mandrels

Mandrels are used to grip a workpiece by the bore to permit the
outside diameter to be machined.

There are five types of mandrels:
Solid mandrels
Expansion mandrels
Gang mandrels
Threaded mandrels
Taper shank mandrels
Mandel Types

Expansion Mandrel

Solid Mandrel

Specialty
Tapered Drive - Solid Mandrels

The solid mandrel has a taper per foot of 0.006 - 0.008.

Comes in standard fractional sizes. Identified by stamp
on the large end.

It is used to turn parts such as bushings and pulleys
where the OD must run true to the ID.

Always turn towards the large diameter.
Figure 39 - Solid mandrel.
Expansion Mandrels

The taper on the mandrel
matches the taper on the
sleeve. Part must be pressed on
the arbor.

Figure 40 - Expansion mandrel
 Morse Taper

Used when multiple parts are being machined.

Figure 41 - Gang mandrel.
The part to be machined must have a matching internal
thread. Cannot be machined with reverse spindle
rotation.

Figure 42 - Threaded mandrel.
 OBJECTIVE 5
DESCRIBE LATHE TOOL HOLDING DEVICES
Figure 57 - Square quick change tool-post.
Figure 58 - Multi-position quick change tool post.
END