Cutting Tools and Cutting materials
Cutting Tools
• One of most important components in machining process
• Performance will determine efficiency of operation
• Two basic types (excluding abrasives)
– Single point and multiple point
• Must have rake and clearance angles ground or formed on them
Cutting-Tool Materials
• Toolbits generally made of seven materials – High-speed steel
– Cast alloys (such as stellite)
– Cemented carbides
– Ceramics
– Cermets
– Cubic Boron Nitride
– Polycrystalline Diamond
Cutting Tool Properties
• Hardness – Cutting tool material must be 1 1/2 times harder
than the material it is being used to machine.
• Capable of maintaining a red hardness during machining operation – Red hardness: ability of cutting tool to maintain
sharp cutting edge
– Also referred to as hot hardness or hot strength
Cutting Tool Properties
• Wear Resistance – Able to maintain sharpened edge throughout
the cutting operation
– Same as abrasive resistance
• Shock Resistance – Able to take the cutting loads and forces
• Shape and Configuration – Must be available for use in different sizes and
shapes.
High-Speed Steel
• May contain combinations of tungsten, chromium, vanadium, molybdenum, cobalt
• Can take heavy cuts, withstand shock and maintain sharp cutting edge under red heat
• Generally two types (general purpose)
– Molybdenum-base (Group M)
– Tungsten-base (Group T)
• Cobalt added if more red hardness desired
Cast Alloy
• Usually contain 25% to 35% chromium, 4% to 25% tungsten and 1% to 3% carbon – Remainder cobalt
• Qualities – High hardness
– High resistance to wear
– Excellent red-hardness
• Operate 2 ½ times speed of high-speed steel
• Weaker and more brittle than high-speed steel
Carbide Cutting Tools
• First used in Germany during WW II as substitute for diamonds
• Various types of cemented (sintered) carbides developed to suit different materials and machining operations – Good wear resistance – Operate at speeds ranging 150 to 1200 sf/min
• Can machine metals at speeds that cause cutting edge to become red hot without loosing harness
Manufacture of Cemented
Carbides
• Products of powder metallurgy process
– Tantalum, titanium, niobium
• Operations
– Blending
– Compaction
– Presintering
– Sintering
Types of Carbide Lathe Cutting Tools
• Blazed-tip type – Cemented-carbide tips brazed to steel shanks – Wide variety of styles and sizes
• Indexable insert type – Throwaway inserts – Wide variety of shapes: triangular, square,
diamond, and round • Triangular: has three cutting edges
– Inserts held mechanically in special holder
Tool
Geometry
Copyright © The McGraw-Hill Companies, Inc.
Permission required for reproduction or display.
SIDE RELIEF
SIDE CLEARANCE
Terms adopted
by ASME
Cutting-Tool Terms
Copyright © The McGraw-Hill Companies, Inc.
Permission required for reproduction or display.
• Front, End, Relief (Clearance)
– Allows end of cutting tool to enter work
• Side Relief (Side)
– Permits side of tool to advance into work
Cutting-Tool Terms
• Side Cutting Edge Angle – Angle cutting edge meets work
• Positive
• Negative - protects point at start and end of cut
• Nose Radius – Strengthens finishing point of tool
– Improves surface finish on work
– Should be twice amount of feed per revolution • Too large – chatter; too small – weakens point
Side Rake
• Large as possible to allow chips to escape
• Amount determined – Type and grade of cutting tool – Type of material being cut – Feed per revolution
• Angle of keenness – Formed by side rake and side
clearance
Copyright © The McGraw-Hill Companies, Inc.
Permission required for reproduction or display.
Back Rake
• Angle formed between top face of tool and top of tool shank – Positive
• Top face slopes downward away from point
– Negative • Top face slopes upward
away from point
– Neutral
Copyright © The McGraw-Hill Companies, Inc.
Permission required for reproduction or display.
Cutting Speeds and Feeds
• Important factors that influence speeds,
feeds, and depth of cut
– Type and hardness of work material
– Grade and shape of cutting tool
– Rigidity of cutting tool
– Rigidity of work and machine
– Power rating of machine
Lathe is one of the oldest important machine tools in the metal working industry. A lathe operates on the principle of a rotating work piece and a fixed cutting tool. A rope wound round the work with its own end attached to a flexible branch of tree and other end being pulled by man caused job to rotate intermittently. With its further development a strip of wood called “lath” was used to support the rope and that is how the machine came to be known as “lathe”.
The cutting tool is feed into the workpiece, which rotates about its own axis, causing the workpiece to be formed to the desired shape. Lathe machine is also known as “the mother/father of the entire tool family”.
The Lathe Machine is one of the oldest and most
important machine tools. As early as 1569, wood lathes
were in use in France. The lathe machine was adapted to
metal cutting in England during the Industrial Revolution.
Lathe machine also called “Engine Lathe” because the
first type of lathe was driven by a steam engine.
Henry Maudsley was born on an
isolated farm near Gigghleswick in
North Yorkshire and educated at
University Collage London. He was
an outstandingly brilliant medical
student, collecting ten Gold Medals
and graduating with an M.D. degree
in 1857.
• This term ‘engine’ is associated with the lathe owing to the fact that early lathes were driven by steam engine. It is also called centre lathe. The most common form of lathe, motor driven and comes in large variety of sizes and shapes.
Engine lathes are classified according to the various designs of headstock and methods of transmitting power to the machine.
1. Belt Driven Lathe
2. Motor Driven Lathe
3. Gear Head Lathe
The power to the engine lathe spindle may be given with the help of a belt drive from an overhead line shaft but most modern machines have a captive motor with either a cone pulley driven or an geared headstock arrangement.
• A bench top model usually of low power used to make precision machine small work pieces.
• It is used for small w/p having a maximum swing of 250 mm at the face plate. Practically it consists of all the parts of engine lathe or speed lathe.
• A lathe that has the ability to follow a template
to copy a shape or contour.
A tool room lathe having features similar to an engine lathe is much more accurately built and has a wide range of spindle speeds ranging from a very low to a quite high speed up to 2500 rpm.
This lathe is mainly used for precision work on a tools, dies, gauges, and in machining work where accuracy is needed.
This lathe machine is costlier than an engine lathe of the same size.
• A lathe in which the work piece is automatically fed and removed without use of an operator. It requires very less attention after the setup has been made and the machine loaded.
• Turret lathe is the adaptation of the engine lathe where the tail stock is replaced by a turret slide(cylindrical or hexagonal). Tool post of the engine lathe is replaced by a square cross slide which can hold four tools.
It has heavier construction and provides wider range of speeds.
The saddle carrying the turret head moves along the whole length of the bed. Much longer jobs can be machined.
Turret head directly mounted on the saddle. The front tool post can carry 4 tools and rear tool post may have 1 or 2 tools. Turret may have4 to 6 tools.
More than one tool may be set to operate simultaneously. There is no lead screw.
A highly automated lathe, where both cutting, loading, tool
changing, and part unloading are automatically controlled by
computer coding.
E.g. CNC Lathe M/C.(Computer Numerical Control Machine)
• This is heavy rugged casting
made to support the working
parts of lathe and also guide
and align major parts of
lathe.
• Made to support working
parts of lathe.
• On top section are machined
ways.
• Guide and align major parts
of lathe.
• The headstock houses
the main spindle,speed
change mechanism, and
change gears.
• The headstock is
required to be made as
robust as possible due to
the cutting forces
involved,which can distort
a lightly built housing.
• Induce harmonic
vibrations that will
transfer through the
work piece, reducing the
quality of the finished
work piece.
• Contains number of different-size gears.
• Provides feed rod and lead-screw with various speeds for turning and thread-cutting operations
TOP VIEW
The arrangement which are employed in feed gear boxes to obtain multispindle speeds and different rates of feeds are:
I. Sliding Gear Mechanism
II. Sliding Clutch Mechanism
III. Gear Cone And Tumbler Gear Mechanism
IV. Sliding Key Mechanism
V. Combination of any two or more of the above
• Usually two or three levers must be moved to obtain the desired combination within a given range.
• Used to move cutting tool along lathe bed.
• Consists of three main parts-
i. Saddle
ii. Cross-slide
iii. Apron
Movement of entire carriage assembly along the bed provides feed for the tool parallel to the lathe axis.
The compound rest can be swivelled on the cross slide in the horizontal plane about vertical axis.
To the front of the carriage is attached the apron. It is fastened to the saddle and hangs over the front of the bed.
The apron houses the automatic feed mechanism for longitudinal and cross feeds and the split nut for thread cutting.
• Mounted on top of saddle. • Provides manual or automatic cross movement for cutting tool.
• Fastened to saddle.
• Houses gears and
mechanism required to
move carriage or cross-
slide automatically.
• Locking-off lever inside
apron prevents engaging
split-nut lever and
automatic feed lever at
same time.
• Apron hand wheel
turned manually to move
carriage along lathe bed
• Upper and lower tailstock castings.
• Adjusted for taper or parallel turning by two screws set in base.
• Tailstock clamp locks tailstock in any position along bed of lathe.
• Tailstock spindle has internal taper to receive dead center.
• Provides support for right-hand end of work.
In tail stock jobs of different lengths are provided with quill which can be moved in and out by means of a screw and then locked in position.
The movement of the quill is parallel to the lathe axis.
The quill has a tapered bore into which is fitted a hardened centre which locates and holds the w/p when turning between centre.
This bore may also be used for supporting tools for operations like drilling and reaming.
•Engages clutch that provides automatic feed to
carriage.
• Feed-change lever can be set for longitudinal
feed or for cross-feed.
• In neutral position, permits split-nut lever to
be engaged for thread cutting.
• Carriage moved automatically when split-nut
lever engaged
•Distance carriage will travel in one revolution of
spindle.
• Depends on speed of feed rod or lead screw.
• Controlled by change gears in quick-change
gearbox.
• Obtains drive from headstock spindle through end
gear train.
• Chart mounted on front of quick-change gearbox
indicates various feeds.
(a) and (b) Schematic illustrations of a draw-in-type collets. (c) A push-out type collet. (d) Workholding of a part on a face plate.
- Forholding cylindrical stock centered. - For facing/center drilling etc.
- This is independent chuck generally has four jaws , which are adjusted individually on the chuck face by means of adjusting screws.
-Collet chuck is used to hold small work pieces.
-Thin jobs can be held by means of magnetic chucks.
Don’t touch cutter or chips while
machine is running.
Make sure work is clamped tightly in
chuck or collet.
Be careful to stay clear of chuck jaws.
All lathe operators must be constantly aware of the safety.
Handle sharp cutters, centres, and drills with care.
Remove chuck keys and wrenches before operating.
Always wear protective eye protection.
Always stop the lathe before making adjustments.
Know where the emergency stop is before operating the
lathe.
Correct dress is important, remove rings and watches.
Do not change spindle speeds until the lathe comes to a
complete stop.
Lathes are highly accurate machine tools
designed to operate around the clock if
properly operated and maintained. Lathes must
be lubricated and checked for adjustment
before operation. Improper lubrication or loose
nuts and bolts can cause excessive wear and
dangerous operating conditions.
Drilling machine
Introduction
• Drilling is a metal cutting process carried out by a rotating cutting tool to make circular holes in solid materials.
• Tool which makes hole is called as drill bit or twist drill.
Drilling machine
• A power operated machine tool which holds the drill in its spindle rotating at high speeds and when actuated move linearly against the work piece produces a hole.
Types of drilling machine.
• Portable drilling machine
• Bench drilling machine
• Radial drilling machine
• Pillar drilling machine
• Gang drilling machine
• Multiple drilling machine
Portable drilling machine
Bench drilling machine
• These are light duty machines used in small workshops.
• Also called Sensitive drilling machines because of its accurate and well balanced spindle.
• Holes of diameter 1 mm to 15 mm.
Bench drilling machine
parts
• Vertical main column
• Base
• Moving drill head
• Work table
• Electric motor
• Variable speed gear box and spindle feed mechanism.
working
• Work piece with the exact location marked on it with the centre punch is clamped rigidly on the work table.
• spindle axis and center punch indentation are in same line.
• Machine is started and drill bit is lowered by rotating feed handle.
• Drill bit touches the work and starts removing material.
Bench drilling machine
Radial drilling machine
• These are heavy duty and versatile drilling machine used to perform drilling operate on large and heavy work piece.
• Holes up to 7.5 cm.
Radial drilling machine
parts
• Heavy base
• Vertical column
• Horizontal arm
• Drilling head
working
• Work piece is marked for exact location and mounted on the work table.
• Drill bit is then located by moving the radial arm and drill to the marked location.
• By starting drill spindle motor holes are drilled.
Drilling machine operation
• Reaming
• Boring
• Counter boring
• Counter sinking
• Spot facing
• Tapping
Reaming
• It is a process of smoothing the surface of drilled holes with a tool.
• Tool is called as reamer.
• Initially a hole is drilled slightly smaller in size.
• Drill is replaced by reamer.
• Speed is reduced to half that of the drilling.
Reaming
Boring
• It is process carried on a drilling machine to increase the size of an already drilled hole.
• Initially a hole is drilled to the nearest size and using a boring tool the size of the hole is increased.
Counter boring
• This process involves increasing the size of a hole at only one end.
• Cutting tool will have a small cylindrical portion called pilot.
• Cutting speed = two-thirds of the drilling speed for the same hole.
Counter sinking
• This is an operation of making the end of a hole into a conical shape.
• Cutting speed = half of the cutting speed of drilling for same hole.
Spot facing
• It is a finishing operation to produce flat round surface usually around a drilled hole, for proper seating of bolt head or nut.
• It is done using a special spot facing tool.
Tapping
• Process of cutting internal threads with a thread tool called as tap.
• Tap is a fluted threaded tool used for cutting internal thread
• Cutting speed is very slow.
Specification of a radial drilling machine
• Power capacity eg: 1.5 hp for drilling motor and 0.5 hp for elevating motor.
• The range of speed of spindle eg: 50 to 2800 rpm.
• Length of arm on which drill head can traverse. eg: 600 mm.
• Vertical movement of the arm eg: 500 mm.
• Angular swing of arm eg: 360˚
Boring Machine
• In machining, boring is the process of enlarging a hole that has already been drilled (or cast), by means of a single-point cutting tool (or of a boring head containing several such tools), for example as in boring a cannon barrel. Boring is used to achieve greater accuracy of the diameter of a hole, and can be used to cut a tapered hole.
Boring machine
TYPES OF BORING
• There are various types of boring. The boring bar may be supported on both ends (which only works if the existing hole is a through hole), or it may be supported at one end. Lineboring (line boring, line-boring) implies the former. Backboring (back boring, back-boring) is the process of reaching through an existing hole and then boring on the "back" side of the workpiece (relative to the machine headstock).
• The two types of the boring machine, each of which has several varieties, are the horizontal boring and drilling machine, and the vertical boring and turning mill.
HORIZONTAL BORING MACHINE
VERTICAL BORING MACHINE
JIG BORING MACHINE
Floor Type Horizontal Boring Machine
Vertical boring machine
METHODS OF LOCATING HOLES IN JIG BORING M/CS
• Lead Screw Method
• Mechanical and electrical gauging
• Optical Measuring Method
Jigs and
Fixtures
Definitions
• Jig: A device that holds
the work and locates
the path of the tool.
• Fixture: A device fixed
to the worktable of a
machine and locates
the work in an exact
position relative to the
cutting tool.
Superior Jig
Flexible Fixturing Systems
What are Jigs and Fixtures
• Anything used to hold a work piece in a desired location – Locate parts for
precision
– Repeating process on a series of parts
– Holding parts for machining, painting, assembly
Two main
types of jigs: • For machining purposes
– Locates the component, holds it firmly in place, and guides the cutting tool.
• For assembly purposes
– Locates separate component parts and holds them rigidly in their correct positions while they are being connected.
North
weste
rn T
ools
Drill jig terms
• Open jig (also called plate jig or drill template)
– The simplest type of drill jig
– Consists of a plate with holes to guide the drills, and may have locating pins that locate the workpiece on the jig
Drill jig terms
• Drill bushings
– Precision tools that
guide cutting tools
such as drill and
reamers into
precise locations in
a workpiece.
Accurate Bushing Co.
Drill jig components
• Jig body
– Holds the various parts of a jig assembly.
• Cap screws and dowel pins
– Hold fabricated parts together
Drill jig components
• Locating devices
– Pins, pads, and recesses used to locate
the workpiece on the jig.
Drill jig components
• Clamping devices
Drill jig components
• Locking pins
– Inserted to lock or
hold the work piece
securely to the jig
plate while
subsequent holes
are being drilled.
Uses of Jig and fixture
• Reduce cost of production. • Increase the production. • To assure high accuracy of parts • Provide for interchangeability • Enable heavy and complex parts to machine • Reduced quality control expenses. • Increased versatility of machine tool. • Less skilled labour. • Saving labour. • Partially automates the machine tools • Use improve the safety, accidents low
Elements of Jig and fixture
• Sufficiently rigid bodies (plate, box or frame structure
• Locating elements.
• Clamping elements.
• Tool guiding elements.
• Elements for positioning or fastening the jig or fixture.
Dimensioning Jig Drawings
Designing jigs
• Jigs can also be
designed as per
requirement of the
workpiece for
holding and other
machining
operations.
Northwestern Tools
Type of Fixtures Milling fixtures
Fixture components
Fixture design
considerations
Sequence in laying
out a fixture
Standard Parts Co.
Fixture components
• Fixture base
– Fixture components and the workpiece are
usually located on a base, which is
securely fastened to the milling machine
table.
Standard Parts Co.
Fixture components
• Clamps
– Clamps counteract forces from the feed of
the table and rotation of the cutter.
American Drill Bushing Co.
Fixture components
• Set blocks
– Cutter set blocks are mounted on the
fixture to properly position the milling cutter
in relation to the workpiece.
Basic Categories of Jigs
• Clamps
• Chucks
• Vises
• Bushings
• Modular Fixtures
Clamps
Chucks
Vises
Bushings
Modular Fixturing
Application
Resources
• Catalogs
• Websites
• Journal Articles
Jigs and Fixtures
V-location
• In V-location, work pieces having circular or semicircular profile are located by means of a Vee block. The block should be used accurately so that the variation in the work piece size are not detrimental to location.
• Vee can be used for both locating and clamping purpose for this two Vee can be used, one fixed other sliding one. Fixed Vee is used for locating and sliding one for clamping.
• The sliding Vee block may be actuated by means of a hand operated screw.
Bush location
• Shaft type work pieces can be easily locate in a hardened steel bushes. The bushes can be plain or flanged type. A flange straighten the bush and also prevent it from being driven into the jig body if it is left unlocked.
Design principles of location purpose
The following principles should be followed while locating surfaces.
1.At least one datum or reference surface should be established at the first opportunity.
2. For ease of cleaning, locating surfaces should be as small as possible.
3. The locating surfaces should not hold swarf and thereby misalign the workpiece
4.Locating surfaces should be raised above surrounding surfaces of the jigs or fixture.
5. Sharp corners in the locating surfaces must be avoided.
6. Adjustable type of locaters should be used for the location on rough surfaces.
7. Locating pins should be easily accessible and visible to the operator.
8. To avoid distortion of the work, it should be supported as shown in fig.