CLASS POWERPOINT - 150102g - LATHE OPERATIONS.pdf

Transcript

MACHINIST PROGRAM - FIRST PERIOD

LATHE OPERATIONS
150102g
 OBJECTIVES
1. SET–UP THE CUTTING TOOLS TO PERFORM PARALLEL TURNING AND BORING OPERATIONS
2. OPERATE TO TURN TO A SHOULDER (SHOP TRAINING)
3. DEMONSTRATE CENTER DRILLING, DRILLING AND REAMING OPERATIONS. (SHOP TRAINING)
4. DEMONSTRATE SET–UP AND CUTTING A TAPER ON A LATHE (SHOP TRAINING)
5. DEMONSTRATE KNURLING, GROOVING, PARTING OFF, FORMING, AND PROFILING ON THE
LATHE (SHOP TRAINING)
6. DEMONSTRATE THE USE OF TAPS, DIES, AND SINGLE POINT THREADING TOOLS
7. DEMONSTRATE SET-UPS FOR DIFFERENT OPERATIONS ON A LATHE (SHOP TRAINING)
 OBJECTIVE 1
PARALLEL TURNING AND BORING
OPERATIONS
Parallel Turning operations
 Verifying Parallel Turning Accuracy

Verifying that the lathe you are operating
turns parallel to the axis (with the tailstock
center in place) is very important.
Take two trial cuts
(or one long cut):

-if the diameter is the same on both ends, the
tailstock is aligned

-if the diameter is smaller at the tailstock,
move the tailstock away from you by half the
difference

-if the diameter is larger at the tailstock, move
tailstock towards you by half the difference

If diameter is smaller by 0.004” at the
tailstock, move tailstock away from you by Figure 3 - Taking a trial cut at each end.

0.002”
Parallel Test Bar:

-mount between centers

-mount dial indicator on cross-slide

-check if dial moves as you move carriage
along the workpiece.

-dial does not change – good

-otherwise adjust until bar is parallel to axis.

Figure 4 - Using a parallel test bar.
Figure 5 - Adjusting the tailstock.
 Adjusting the Tailstock

The tailstock is adjusted by moving the upper casting
away from or towards the operator.
If the work is large at the tailstock end it has to move
towards the operator.
If the work is small at the tailstock end it has to move
away from the operator.
Example:
If the workpiece is 0.004 larger at the tailstock, adjust
towards you by ½ that distance, or 0.002
 CUTTING
ACCURACY
Tool Height Adjustments

Always lock the carriage when performing heavy
facing operations.
Tool Height Verification

Methods:
1. Turn tool towards the
tailstock bearing center
and adjusting the height to
match the center point.

2. Use a spring steel rule.
Bring the tool gently
against the rule on the work
piece radius and confirm
that it is vertical
Tool Height Centering Device
 Roughing and Finishing
When roughing the feed rate
should be as high as the machine
and the tooling can handle.
Feed rate is usually about 0.010” to
0.030” per revolution.
Leave about 0.030” for each
finishing cut.(2x tool nose radius)
Feed rate for finishing depends on
the finish required on the part.
Figure 10 - Roughing and finishing cuts.
ACCURATE DIAMETERS

1. Rough to.100 larger than finished diameter

2. Reduce feed for the required finish

3. Take a.050” cut , do not turn the cross slide dial at
the end of the cut, just return to the beginning.

4. Measure the work piece.

5. Take your final cut compensating for the measured
diameter and the final diameter.
Trial Cut Diameter Verification
 Know your Cross Slide

If you move a cross-feed dial 0.100” and 0.100”
is removed from the diameter of the work you
have a direct reading dial.

If you move the cross-feed dial 0.100 and 0.200
is removed from the work you have an indirect
reading dial.

On most lathes each graduation on the cross-
feed dial represents 0.001 inches or 0.02 mm.
Cross Slide Backlash

Backlash on a lathe is
created by the clearance
between the cross-slide
screw and the nut.

When setting the depth of cut,
if you overshoot your mark,
reverse the dial up one full
revolution, and reset the
graduated dial
Verification of a Direct or Indirect Dial

Figure 7 - Graduated dial.
Using a dial to Verify the Graduated Dial
Reading Verses Movement

Figure 8 - Use a dial indicator to see if the dial is direct or indirect.
Figure 9 - Depth of cut for a direct dial.
 INTERNAL
CUTTING
OPERATIONS
Internal Cutting - Boring

Boring is the process of machining an internal
feature using a single point tool

Boring enlarges an existing hole and makes it
run true to the axis of the work piece.

For best results keep the boring bar as short as
possible.
For the best result, the Boring Bar should be as
large as possible or 2/3 the hole diameter.
Figure 11 - Boring, as opposed to turning.
Figure 12 - Mounting a boring bar with the least possible overhang.
The Boring Operation
TURNING TO A
SHOULDER
Figure 13 - Face and shoulder.
Figure 16 - Setting the depth of cut with the compound rest.
Using a vernier to establish a shoulder length

Figure 18 - Positioning the cutting tool with a vernier caliper.
Important to Select the Appropriate
tool for Shoulder Turning

Figure 19 - Turn down the diameter ahead of the shoulder.
Shoulder Turning Measuring Method

Figure 21 - Measuring the location of the roughed shoulder.
The Importance of Fillets and Work Piece Strength.

Figure 22 - Using a filleting tool.
Note: Shoulder Machining Techniques

Figure 17 - Shoulder types.
 CENTER DRILLING,
DRILLING, AND
REAMING OPERATIONS
 Centre Drilling

The proper depth of a centre drill is 2/3 of the way up
the tapered portion of the centre drill.

* Remember to Peck Drill
 Center Drill Breakage

Speed too slow

Feed too high

Centers not in line

Running in reverse
Drilling
DRILLING

When using HSS drills the chip should be
dicoloured.
Drilling Operations

For all drilling operations, a calculation of the RPM is crucial to
the longevity of the machine tools.

Break long chips by performing a peck drilling.

Pull the drill out of the hole fully after 4 times its diameter.
Reaming
Machine Reaming

Figure 27 - Reaming in a lathe.
Reaming

Reaming Machining Conditions
1/2 the speed, 2 X the feed
Material Allowance
Under 1/2 inches leave 1/64th
Over 1/2 inches leave 1/32nd.
 GROOVING, PARTING,
KNURLING, THREADING
OPERATIONS
Grooving Operations
Parting and Grooving
Figure 34 - Shapes of grooving tools.
Grooving Process
Tool set as short as can be but still cut the groove
required.
Speed = ½ of normal Turning speed.
Use Power feed with a goal to get the chip to curl and pop
out of the groove when possible.
Use plenty of cutting oil or coolant.
If chatter is occurring, increase the feed rate.
Parting Operations
Setting Appropriate Tool Overhang

Figure 35 - Setting up a parting tool with as little overhang as possible.
Warning!!

Never Part a work piece off when it
is between centers.
Knurling Operations
Knurling
Knurling process

Select the coarseness of the Knurl.
Clamp the knurling tool in the tool post securely and at 90 degrees
to the surface.
Run the lathe at 200 RPM or less.
Set the feed Rate to the fastest that the manual lathe will go.

Put a significant pressure on the tool against the work piece.
Motion the tool back and forth on the work piece , then engage the
feed.
Reverse the work piece rotation at the end of the knurl and return to
the start position.
Knurling on the Lathe
Displacement Type Knurling

Process:
1. Align tool rollers

2. Center the Rollers

3. RPM 100

4. Feed Rate.030 Rev.

5. Press hard onto the
Work , and engage
feed

6. Use cutting oil
Knurling Operations –
Cut Type

https://youtu.be/Oq1vXbL0zH0
Threading
Threading Operations

Performing Threading Operations
Threading Setup and Pitch Verification

The thread center gauge is The screw thread Pitch
used to align the threading Gauge is used to verify the
tool to the work piece axis. correct pitch is being cut.
 Grinding 60˚ HSS Threading
Tool

Use thread center gauge for checking the angle.
Use an aluminum oxide wheel.
Grind so tool point is close to the left hand side
of the tool bit.
Don’t over heat the tool.
Use a honing stone to put a small radius on the
point.
Center height is critical especially when
cutting tapered threads such as pipe threads.
 Methods of Threading
on a lathe
Half angle threading
The thread is cut using the compound rest
set at 29.5 degrees.

Depth is calculated using the formula
In Feed = 0.750 X Pitch

RPM is about 1/4 the normal turning speed
when using HSS tooling
Figure 38 - Setting the compound rest to 29 1/2 degrees.
 Threading on a lathe

Plunge cutting
Thread is cut using the cross-slide.

Thread depth is calculated using the formula
Depth = 0.6495 X Pitch

Thread depth is used as a reference, thread fit is
measured on the pitch diameter.
 TAPPING AND DIE
CUTTING OPERATIONS
Tapping in the Lathe
Tapping in the Lathe
Using the Spindle face to guide a Die so it remains parallel to
the axis of the machine

Figure 45 - Using the front of the tailstock spindle to guide the die stock.
Using a modified Die Head to thread an external Thread

Figure 46 - Using an adapter.
STEADY REST AND
FOLLOWER REST
SET UP
Steady Rest - Micro Motion

Micro Motion is caused by
incorrect setting of the steady
Rest.

The work piece will walk
away from the Lathe jaws
causing a dangerous
situation.
Steady Rest Setting tool

This simple
device allows the
operator to dial in
the jaws of a
steady rest to very
close tolerances –
preventing Micro
Motion
Follower Rest Considerations

Too much pressure on the work piece may
cause it to walk out of the jaws.

Too little pressure will not sufficiently
support the work piece under tool pressure
causing vibration and inconsistent
diameters.
Figure 50 - Follower rest.
Follower Rests

The follower rest bolts on
and travels with the saddle.

Set up
Contact - must only lightly
touch the surface.
CUTTING TAPERED
PARTS
 Cutting Tapers With The
Compound Rest

Set up
Compounds are swiveled to a Centerline angle

Example: If the included angle is 60˚ then the
compound is set to 30˚

For accurate angle( less than 1 degree accuracy),
calculate the angle using Trig, then use a dial
indicator to inspect the angle.
Figure 31 - Cutting a taper with the compound rest.
Figure 30 - Compound rest.
Figure 29 - Cutting a taper.
 Tailstock Offset

Rarely used/only if taper attachment is not
available.
Tapers can be cut over the working length of the
machine.
Disadvantages… must misalign tailstock and re-
align after the taper has been cut.
Centers don’t sit properly.
Can’t cut internal tapers.
Offset is limited. Work must be turned between
centers.
Figure 32 - Offsetting the tailstock to cut a tapered section.
 Taper Calculations – Tail Stock
Method

TO = (D - d) if the whole shaft is tapered.
2

TO = (D - d) X OL if part of the shaft is parallel.
2 TL
Plain Taper Attachment
 Telescoping Taper Attachment

Figure 1 - Telescoping taper attachment.
 Figure 2 - Telescoping taper attachment
 Figure 3 - Setting the guide bar.
 Setting the Taper Attachment

Figure 4 - Test for accuracy.
Bluing a Taper for Fit

Figure 5 - Check the taper with a taper gauge.
 FINISHING
OPERATIONS
Polishing in the Lathe
Hand Polishing In The Lathe

1. Choose Finer grit Emery
clothe.

2. Never hold Emery with one
hand.

3. Emory polishing is usually
held to.001” or less diameter
reduction.
Belt Sanding Attachment
Filing on the Lathe

Filing Tips

Always hold the file handle with
the left hand to keep away from
the rotating chuck.

Never file more than.001 inches
due to causing the work piece
from becoming out of round.

Use a lathe file or single cut file.
Tool Post Grinders
Tool Post Grinder

Tool Post Grinding hints.

Removal is.001 to.002 per
rotation of the work

Ensure at the point of contact
between the lathe and the grinding
wheel are turning in opposite
directions.

Speed: 200 RPM
Feed : set to ½ the wheel width
per revolution
 LATHE
MAINTENANCE
Lathe Maintenance

The engine lathe is a
precision machine tool
and must be treated with
great care....
END