1. Cutting Tool Technology
EBB440
Applied Metallurgy
Cutting Tool Technology

2. Cutting Tool Technology
Two principal aspects:
Tool material
Tool geometry

3. Three Modes of Tool Failure
Fracture failure
Cutting force becomes excessive and/or dynamic, leading to brittle fracture.
•Temperature failure
Cutting temperature is too high for the tool material.
•Gradual wear
Gradual wearing of the cutting tool.

4. Preferred Mode of Tool Failure: Gradual Wear
Fracture and temperature failures are premature failures.
• Gradual wear is preferred because it leads to the longest possible use of the tool.
• Gradual wear occurs at two locations on a tool:
Crater wear –occurs on top rake face.
Flank wear –occurs on flank (side of tool).

5. Tool Wear
Crater wear – concave section on rake face, formed by action of chip sliding against surface.
Flank wear – results from rubbing between newly generated surface & flank face adjacent to cutting edge.
Notch wear – original work surface is harder & more abrasive than internal material.
Nose radius wear – occurs on nose radius leading to end of cutting edge.

6. Diagram of worn cutting tool, showing the principal
locations and types of wear that occur

7. (b) flank wear on a cemented carbide tool
Crater wear, and
(b) flank wear on a cemented carbide tool

8. Tool wear as a function of cutting time
Tool wear as a function of cutting time. Flank wear (FW) is used here as the measure of tool wear. Crater wear follows a similar growth curve

9. Wear Mechanism Abrasion – hard particles in work material.
Adhesion – between chip & rake face.
Diffusion – at tool-chip boundary.
Chemical reactions – oxidation on rake face.
Plastic deformation – at cutting edge.

10. Tool Life Tool life – length of cutting time that tool can be used.
Tool life criteria – Taylor equation, but in practice, more convenient to use visual inspection, changes in sound emitted, runs fingernail across cutting edge, chips becomes ribbony, stringy & difficult to dispose of.

11. Taylor Tool Life Equation
This relationship is credited to F. W. Taylor (~1900).
vT n = C
where v = cutting speed; T = tool life; and n and C are parameters that depend on feed, depth of cut, work material, tooling material, and the tool life criterion used.
n = the slope of the plot
C = the intercept on the speed axis

12. Tool Materials
Three modes tool failure to identify the important properties that a tool material should possess:
Toughness - to avoid fracture failure.
Hot hardness - ability to retain hardness at high
temperatures.
Wear resistance - hardness is the most.
important property to resist abrasive wear.

13. High Speed Steel (HSS)
Highly alloyed tool steel capable of maintaining hardness at elevated temperatures better than high carbon and low alloy steels.
• One of the most important cutting tool materials.
• Especially suited to applications involving complicated tool geometries, such as drills, taps, milling cutters, and broaches.
• Two basic types (AISI)
Tungsten-type, designated T- grades
Molybdenum-type, designated M-grades

14. Cast Cobalt Alloys
Consist of cobalt (40-50%), chromium (25-35%) and tungsten (15-20%).
High hardness than HSS.
Better wear resistance compared to HSS but not as good as cemented carbide.
Toughness is better than carbides but not as good as HSS.
Capable of heavy roughing cuts a speeds greater than HSS and feeds greater than carbides.
Applicable for work materials : both steel and nonsteels, nonmetallic materials such as plastic and graphite.

15. Cemented Carbides
Class of hard tool material based on tungsten carbide (WC) using powder metallurgy techniques with cobalt (Co) as the binder.
• Two basic types:
Non-steel cutting grades - only WC-Co.
Steel cutting grades - TiC and TaC added to WC-Co.

16. Cermets
Combinations of TiC, TiN, and titanium carbonitride (TiCN), with nickel and/or molybdenum as binders.
• Some chemistries are more complex.
• Applications: high speed finishing and semifinishing of steels, stainless steels, and cast irons.
Higher speeds and lower feeds than steel-cutting carbide grades.
Better finish achieved, often eliminating need for grinding.

17. Coated Carbides
Cemented carbide insert coated with one or more thin layers of wear resistant materials, such as TiC, TiN, and/or Al2O3.
• Coating applied by chemical vapor deposition or physical vapor deposition.
• Coating thickness = µm.
• Applications: cast irons and steels in turning and milling operations.
• Best applied at high speeds where dynamic force and thermal shock are minimal.

18. Ceramics
Primarily fine-grained Al2O3, pressed and sintered at high pressures and temperatures into insert form with no binder.
• Applications: high speed turning of cast iron and steel.
• Not recommended for heavy interrupted cuts (e.g. rough milling) due to low toughness.
• Al2O3 also widely used as an abrasive in grinding.

19. Synthetic Diamonds
Sintered polycrystalline diamond (SPD) - fabricated by sintering very fine-grained diamond crystals under high temperatures and pressures into desired shape with little or no binder.
• Usually applied as coating (0.5 mm thick) on WC-Co Insert.
•Applications: high speed machining of nonferrous metals and abrasive nonmetals such as fiberglass, graphite, and wood.
Not for steel cutting

20. Cubic Boron Nitride • Hardest material.
• Fabrication into cutting tool inserts same as SPD: coatings on WC-Co inserts.
• Applications: machining steel and nickel-based alloys.
• SPD and cBN tools are expensive.

21. Tool Geometry Two categories: • Single point tools
- Used for turning, boring, shaping, and planing.
•Multiple cutting edge tools
- Used for drilling, reaming, tapping, milling,
broaching, and sawing.

22. convention that defines the seven elements
Single- Point Tool Geometry
Seven elements of single-point tool geometry; and (b) the tool signature
convention that defines the seven elements

23. Tool Geometry
Single-point tool geometry : back rake angle, side rake angle, end relief angle, side relief angle, end cutting edge angle, side cutting edge angle, & nose radius.
Chip breakers : groove-type designed into tool itself, & obstruction-type designed as an additional device on rake face.

24. Tool Geometry
Effect of Tool Material & Geometry : HSS - +ve rake angle, hard material - -ve or small +ve angle. This tend to load tool more in compression & less in shear. Relief angle is as small as possible to give support for cutting edge.
Cutting tool insert – economical & adaptable to many different types of operations.

25. Common insert shapes: (a) round, (b) square, (c) rhombus with two 80 ° point angles, (d) hexagon with three 80° point angles, (e) triangle (equilateral), (f) rhombus with two 55 ° point angles, (g) rhombus with two 35 ° point angles. Also shown are typical features of the geometry.

26. Cutting Fluids
Any liquid or gas applied directly to machining operation
to improve cutting performance.
Two main problems addressed by cutting fluids:
Heat generation at shear zone and friction zone.
Friction at the tool-chip and tool-work interfaces.
• Other benefits:
Wash away chips (e.g., grinding and milling).
Reduce temperature of workpart for easier handling.
Improve dimensional stability of workpart.
Protect new surface from corrosion.

27. Benefits of Using Cutting Fluids
Wash away chips (e.g., grinding and milling)
Reduce temperature of workpart for easier handling
Improve dimensional stability of workpart
Protect new surface from corrosion
Improved tool life
Improved surface finish
Reduced forces and power for cutting
Reduced workpiece distortion due to temperature

28. Cutting Fluid Functions
• Cutting fluids can be classified according to function:
Coolants - designed to reduce effects of heat in machining.
Lubricants - designed to reduce tool-chip and tool-work friction.

29. Coolants • Water used as base in coolant-type cutting fluids.
• Most effective at high cutting speeds where heat generation and high temperatures are problems.
• Most effective on tool materials that are most susceptible to temperature failures (e.g., HSS).

30. Lubricants • Usually oil-based fluids.
• Most effective at lower cutting speeds.
• Also reduces temperature in the operation.

31. Chemical Formulation of Cutting Fluids
• There are four category of cutting fulids according to chemical formulation :
Cutting oils – oil derived from petroleum, animal,
marine or vegetable origin.
Emulsified oils – oils droplets suspended in water
Semichemical fluids – hybrid class between
chemical fluids and emulsified oils.
Chemical fluids – chemicals in water solution