Tool angle
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Mar 26, 2016
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About This Presentation
cutting angle
Slide Content
An introduction to Cutting Tools with
special reference to SPCT
by
Jatinder Garg
Associate Professor
Baba Hira Singh Bhattal Institute of Engineering & Technology
Lehragaga (Sangrur)
special reference to SPCT
by
Jatinder Garg
Associate Professor
Baba Hira Singh Bhattal Institute of Engineering & Technology
Lehragaga (Sangrur)
Machining Process
•Cast, formed and shaped products may need
further machining operations to give them the
desired final shape, after removal of extra material
in the form of chips.
•Machining processes remove material from a work
piece by
•CUTTING ( As in case of machine tools like lathe, shaper etc)
•ABRASIVE ( As in case of a grinding wheel)
•NON TRADITIONAL ( Processes such as EDM, ECM Etc.)
•Cast, formed and shaped products may need
further machining operations to give them the
desired final shape, after removal of extra material
in the form of chips.
•Machining processes remove material from a work
piece by
•CUTTING ( As in case of machine tools like lathe, shaper etc)
•ABRASIVE ( As in case of a grinding wheel)
•NON TRADITIONAL ( Processes such as EDM, ECM Etc.)
3
Metal Cutting Processes
Metal Cutting Processes
4
Turning
•High proportion of work machined in shop
turned on lathe
•Turning tool set to given depth of cut, fed parallel to
axis of work (reduces diameter of work)
•Chip forms and slides along cutting tool's upper surface
created by side rake
Turning
•High proportion of work machined in shop
turned on lathe
•Turning tool set to given depth of cut, fed parallel to
axis of work (reduces diameter of work)
•Chip forms and slides along cutting tool's upper surface
created by side rake
5
Planing or Shaping
•Workpiece moved back and forth under
cutting tool
•Fed sideways a set amount at end of each table
reversal
Planing or Shaping
•Workpiece moved back and forth under
cutting tool
•Fed sideways a set amount at end of each table
reversal
6
Plain Milling
•Multi-tooth tool having several equally spaced cutting
edges around periphery
•Each tooth considered single-point cutting tool (must have
proper rake and clearance angles)
•Workpiece held in vise or fastened to table
•Fed into horizontal revolving cutter
•Each tooth makes successive cuts
•Produces smooth, flat, or profiled surface depending on
shape of cutter
Plain Milling
•Multi-tooth tool having several equally spaced cutting
edges around periphery
•Each tooth considered single-point cutting tool (must have
proper rake and clearance angles)
•Workpiece held in vise or fastened to table
•Fed into horizontal revolving cutter
•Each tooth makes successive cuts
•Produces smooth, flat, or profiled surface depending on
shape of cutter
7
Inserted Blade Face Mill
•Consists of body that holds several equally spaced
inserts
•Cutting action occurs at lower corner of insert
•Corners chamfered to give strength
Inserted Blade Face Mill
•Consists of body that holds several equally spaced
inserts
•Cutting action occurs at lower corner of insert
•Corners chamfered to give strength
8
End Milling
•Multi-fluted cutters held vertically in vertical
milling machine spindle or attachment
•Used primarily for cutting slots or grooves
•Workpiece held in vise and fed into revolving
cutter
•End milling
•Cutting done by periphery of teeth
End Milling
•Multi-fluted cutters held vertically in vertical
milling machine spindle or attachment
•Used primarily for cutting slots or grooves
•Workpiece held in vise and fed into revolving
cutter
•End milling
•Cutting done by periphery of teeth
9
Drilling
•Multi-edge cutting tool that cuts
on the point
•Drill's cutting edges (lips)
provided with lip clearance to
permit point to penetrate work
piece as drill revolves
Drilling
•Multi-edge cutting tool that cuts
on the point
•Drill's cutting edges (lips)
provided with lip clearance to
permit point to penetrate work
piece as drill revolves
10
What is a Cutting Tool
•A cutting tool is any tool that is used to remove
metal from the work piece by means of shear
deformation.
•It is one of most important components in
machining process
•It must be made of a material harder than the
material which is to be cut, and the tool must be
able to withstand the heat generated in the metal
cutting process.
•Two basic types
•Single point
•Multiple point
What is a Cutting Tool
•A cutting tool is any tool that is used to remove
metal from the work piece by means of shear
deformation.
•It is one of most important components in
machining process
•It must be made of a material harder than the
material which is to be cut, and the tool must be
able to withstand the heat generated in the metal
cutting process.
•Two basic types
•Single point
•Multiple point
Single Point Cutting Tool
Multi Point Cutting Tool
13
Cutting-Tool Materials
•Cutting tool bits generally made
•High-speed steel
•Cast alloys
•Cemented carbides
•Ceramics
•Cermets
•Cubic Boron Nitride
•Polycrystalline Diamond
Cutting-Tool Materials
•Cutting tool bits generally made
•High-speed steel
•Cast alloys
•Cemented carbides
•Ceramics
•Cermets
•Cubic Boron Nitride
•Polycrystalline Diamond
14
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 at elevated temp.
•It is also sometimes referred to as hot hardness or
hot strength
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 at elevated temp.
•It is also sometimes referred to as hot hardness or
hot strength
15
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.
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.
Single Point Cutting Tool
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Single Point Cutting Tool
Single Point Cutting Tool
Know the Single Point Cutting
Tool
•Shank: Main body of tool, it is part of
tool which is gripped in tool holder
•Face: Top surface of tool b/w shank
and point of tool. Chips flow along this
surface
•Flank: Portion tool which faces the work. It is surface adjacent to &
below the cutting edge when tool lies in a horizontal position.
•Point: Wedge shaped portion where face & flank of tool meet.
•Base: Bearing surface of tool on which it is held in a tool holder.
•Nose radius: Cutting tip, which carries a sharp cutting point. Nose
provided with radius to enable greater strength, increase tool life &
surface life.
Typical Value : 0.4 mm – 1.6 mm
Tool
•Shank: Main body of tool, it is part of
tool which is gripped in tool holder
•Face: Top surface of tool b/w shank
and point of tool. Chips flow along this
surface
•Flank: Portion tool which faces the work. It is surface adjacent to &
below the cutting edge when tool lies in a horizontal position.
•Point: Wedge shaped portion where face & flank of tool meet.
•Base: Bearing surface of tool on which it is held in a tool holder.
•Nose radius: Cutting tip, which carries a sharp cutting point. Nose
provided with radius to enable greater strength, increase tool life &
surface life.
Typical Value : 0.4 mm – 1.6 mm
22
SPC Tool
Geometry
SIDE RELIEF
SIDE CLEARANCE
SPC Tool
Geometry
SIDE RELIEF
SIDE CLEARANCE
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The most significant terms in the geometry of a
cutting tool angles are:
•Relief or clearance angle
•Side relief
•End relief
•Rake angle
•Back Rake angle
•Side Rake angle
•Cutting edge angle
•Side Cutting edge angle
•End Cutting edge angl
•Nose Radius
Nomenclature of Single Point Lathe Tool
The most significant terms in the geometry of a
cutting tool angles are:
•Relief or clearance angle
•Side relief
•End relief
•Rake angle
•Back Rake angle
•Side Rake angle
•Cutting edge angle
•Side Cutting edge angle
•End Cutting edge angl
•Nose Radius
Nomenclature of Single Point Lathe Tool
24
Cutting-Tool Terms
Relief or Clearance angle:
•Ground on the end and side faces of a tool to
prevent it from rubbing on the work piece.
•To enable only the cutting edge to touch the work
piece.
Side Relief angle:
•Angle ground directly
below the cutting edge
on the flank of the tool
End Relief angle:
•Angle ground from the
nose of the tool
Cutting-Tool Terms
Relief or Clearance angle:
•Ground on the end and side faces of a tool to
prevent it from rubbing on the work piece.
•To enable only the cutting edge to touch the work
piece.
Side Relief angle:
•Angle ground directly
below the cutting edge
on the flank of the tool
End Relief angle:
•Angle ground from the
nose of the tool
25
Cutting-Tool Terms
Cutting edge angle
•Ground on a tool so that it can be mounted in the correct
position for various machining operations.
Side Cutting edge angle
•Allows flank of the tool to
approach the work piece first
•Spreads the material over a
greater distance on the cutting
edge, thereby thinning out the
chip.
•Approximately 15
0
End Cutting edge angle
•Allows the cutting tool to
machine close to the work piece
during turning operations
•Usually 20 – 30
0
Cutting-Tool Terms
Cutting edge angle
•Ground on a tool so that it can be mounted in the correct
position for various machining operations.
Side Cutting edge angle
•Allows flank of the tool to
approach the work piece first
•Spreads the material over a
greater distance on the cutting
edge, thereby thinning out the
chip.
•Approximately 15
0
End Cutting edge angle
•Allows the cutting tool to
machine close to the work piece
during turning operations
•Usually 20 – 30
0
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Rake angle:
•Ground on a tool to provide a smooth flow of the chip over the
tool so as to move it away from the work piece
Cutting-Tool Terms
Back Rake angle
•Ground on the face of the tool
•Influences the angle at which
chip leaves the nose of the tool
•Generally 8 - 10
0
Side Rake angle
•Ground on the tool face away
from the cutting edge
•Influences the angle at which
the chip leaves the work piece
•A lathe tool has 14
0
side rake.
Rake angle:
•Ground on a tool to provide a smooth flow of the chip over the
tool so as to move it away from the work piece
Cutting-Tool Terms
Back Rake angle
•Ground on the face of the tool
•Influences the angle at which
chip leaves the nose of the tool
•Generally 8 - 10
0
Side Rake angle
•Ground on the tool face away
from the cutting edge
•Influences the angle at which
the chip leaves the work piece
•A lathe tool has 14
0
side rake.
27
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
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
28
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
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
Rake Angles
•Small to medium rake angles cause:
•high compression
•high tool forces
•high friction
•result = Thick—highly deformed—hot chips
•Small to medium rake angles cause:
•high compression
•high tool forces
•high friction
•result = Thick—highly deformed—hot chips
Negative Rake Tools
•Typical tool materials which utilize negative rakes are:
•Carbide
•Diamonds
•Ceramics
•These materials tend to be much more brittle than HSS
but they hold superior hardness at high temperatures.
The negative rake angles transfer the cutting forces to
the tool which help to provide added support to the
cutting edge.
•Typical tool materials which utilize negative rakes are:
•Carbide
•Diamonds
•Ceramics
•These materials tend to be much more brittle than HSS
but they hold superior hardness at high temperatures.
The negative rake angles transfer the cutting forces to
the tool which help to provide added support to the
cutting edge.
31
Cutting-Tool Terms
Functions:
•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
Nose Radius:
•Rounded tip on the point of the tool
Cutting-Tool Terms
Functions:
•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
Nose Radius:
•Rounded tip on the point of the tool
Tool Angle Application
•Factors to consider for tool angles
•The hardness of the metal
•Type of cutting operation
•Material and shape of the cutting tool
•The strength of the cutting edge
•Factors to consider for tool angles
•The hardness of the metal
•Type of cutting operation
•Material and shape of the cutting tool
•The strength of the cutting edge
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