1. New Directions in Cutting Tool Materials and Machining Options
R. Wertheim, ISCAR April 2001 SH

2. Breakdown of World Cutting Tool Materials
Shifting from HSS to Carbide Cutting Tools
Other 3%
PCD,CBN
Ceramics
Cermet 8% 4% 5%
Carbide 45%
HSS 35%

3. Worldwide Consumption of Cutting Tool Materials
1990
1995
2000
53%
50%
48%
46%
45%
35%
HSS
Others
HSS
Others
Others
Carbide & Cermets
Carbide & Cermets
Carbide & Cermets
HSS
12% 6% 5%

4. Uncoated Carbide Grades Composition and Properties
K30
K20
K10
K01
M10
M20
M30
P10
P20
P25
P30
P40
300
250
150
100 75 mT
10.0
10.5
11.0
11.5
12.0
12.5
13.0
13.5
14.0
14.5
15.5
g/cm3
Hot Hardness
Wear Resistance
Toughness
(Magnetic Saturation)
CO-Content
TiC, TaC
Spesific Weight
ISO 513

5. GROUPS OF APPLICATION ® NEW ISO 513 Carbide Grades (Draft 2000)
MAIN GROUPS OF APPLICATION ®
GROUPS OF APPLICATION ®
TOUGH
CUTTING
MATERIALS
IDENT
LETTER
IDENT
COLOR
MATERIALS TO BE
MACHINED
HARD CUTTING
MATERIALS
P01 P P P P P P P P
Steel:
All kinds of steel and
cast steel except stain-
less steel with auste-
nitic structure. 1 2 P
Blue
Stainless Steel:
Stainless austenitic
and austenitic/ferritic
steel and cast steel.
M10 M M M
M40 M M M 1 2 M
Yellow K K K K
K40 K K K
Cast Iron:
Grey cast iron, cast
iron with spherodial
graphite, malleable
cast iron. 1 2 K
Red
NEW ISO 513 Carbide Grades (Draft 2000)

6. NEW ISO 513 Carbide Grades (Draft 2000)
MAIN GROUPS OF APPLICATION ®
GROUPS OF APPLICATION ®
TOUGH
CUTTING
MATERIALS
IDENT
LETTER
IDENT
COLOR
MATERIALS TO BE
MACHINED
HARD CUTTING
MATERIALS
N01 N N N
N30 N N N
Nonferrous Materials:
Aluminum and other
nonferrous metals,
nonferrous materials. 1 2 N
Green A or S
Heavy machining
Materials:
Heat resistant special
alloys based on iron,
nickel and cobalt, tita-
nium and alloys.
A01 A A A
A30 A A A 1 2
Silver
H01 H H H
K40 K K K
Hard Materials:
Hardened steel,
hardened cast iron
materials, chilled cast
iron. 1 2 H
Brown
NEW ISO 513 Carbide Grades (Draft 2000)

7. Uncoated Carbides Substrates for Coating
10 m m
(X 2000)
IC 21,Coarse WC
8% Co
IC 28, Fine WC
with Multi-Carbide (TaC, NbC)
12.5% Co
IC 50M, Fine WC
with Multi-Carbide
(TiC, TaC, NbC)
11% Co

8. Properties of Sub-Micron Carbide Grades
Compared to Cermets & Standard Carbide 19
Standard
ISO 14
Fracture Toughness K1c
Sub-Micron 9
Cermet 4
1200
1300
1400
1500
1600
1700
1800
1900
Hardness HV30

9. Uncoated Carbides Substrate Properties
ISCAR
GRADE
DENSITY
HARDNESS
FRACTURE
TRANSVERSE
gr/cm3
HV 20KG
TOUGHNESS
RUPTURE
K1C
kg/mm
STRENGTH 2
0.5
MPa
(TRS)
PSI X1000
IC 07
14.93
1745
11.3
520
IC 08
14.49
1580
14.8
610
IC 21
14.70
1270
19.5
450
IC 28
14.26
1340
18.0
510
IC 10
14.70
1480
13.9
450
IC 50M
12.45
1480
13.4
360
IC 20
14.96
1640
11.1
350
IC 30N
6.93
1380
10.2
260

10. Cermet Grades

11. Cermet: Composition and Grades
Ceramic Binder Iscar Grade
TiC Ni (1970s)
TiC Ni + Mo or Mo2C IC60T, 80T, 100T
TiCN Ni + Mo or Mo2C (1990s)
TiCN + TaxNbyC Ni + Mo or Mo2C + Co IC30N, 20N
Cermet + PVD TiN Coating IC530N, 520N
(1995)

12. Cermet: Properties and Applications
Higher hardness
Higher hot hardness
Lower friction
Minimal BUE
Better wear resistance
Lower toughness (TRS)
Chipping more likely
Lower modulus of elasticity
APPLICATIONS
Higher cutting speeds
Finish turning
Better surface finish
Small and medium chip loads
Mainly continuous cutting

13. Surface Finish of Various Tool Materials in Turning
Machining Data:
Vc: 250 m/min (820 sfm)
f: 0.30 mm/rev (.012”/rev)
ap: 3.0 mm (.118”)
Workpiece: SAE 1045
Dry, No coolant.
Surface Finish, Rt (µm)
1.00
0.75
0.50
0.25
Cermet
Coated
Carbide
Carbide

14. Coatings and Coated Carbide Grades

15. Wear Pattern of Coated Inserts
Side Relief Angle
Coating
Rake Face
Chip ap a b g +
=90°
Back Rake
Angle
Side Rake
Flank-Face

16. Thermal Conductivity as a Function of Temperature50 40 30 20 10
500
1000
1500 C°
Al2O3
TiN
NbC
TaC
TiC
Temperature w
m°k
Thermal Conductivity

17. PVD and CVD: Pressure - Temperature Zones During Coating
105
104
103
102
101
100
10-1
10-2 P T °C
400
600
800
1000
1200
CVD
MT-CVD
PVD
Plasma

18. Main Features of PVD and CVD Coating
Proces
Chemical Vapo
Deposition - (CVD)
Physical Vapor
Deposition - (PVD)
Temperature
800° ° C
200° - 500°C
Coating Layer
Carbides, Nitrides
Oxides
TiN,
TiCN, TiAlN
Total Layer Thickness mm
2 - 5 mm
Features
Coated on all sides
More oriented coating
Properties
More layer combinations possible
Good coating adherence
Sharp cutting edge
Partial adherence
Less stress between substrate and coating

19. Indexable Inserts-World Market is Moving Towards PVD Coating
Parting-Off , Grooving, Threading, Milling and Drilling Lines
1997
CVD
PVD UC
Cermet
55% 5%
20%
2000
CVD
PVD UC
Cermet
25% 8%
12%
55%
1997
CVD
PVD UC
Cermet
55% 5%
20%
Turning is following the same trend toward PVD coatings

20. Cutting Tool Material Strength with PVD and CVD Coatings
Uncoated
CVD
PVD
CVD-Low Temp.
Coating Thickness
(TRS) mm 15 10 5
Transverse Raptne Strength
(-30%)
(-100-0%)
(-10%)

21. Calculated Stress Distribution in CVD Coatings
0.200 4
0.175
1 Al2O3
2 TiC
3 TiCN
4 TiN
5 Substrate
0.150 3
0.125 1
0.100
0.075 2
Stress (xlo3Kg/mm2)
0.050
0.025 10 20 30 40 50 60 70 80 90
100
0.000 mm
-0.025 5 5
-0.050
Depth Below Surface t

22. General Stress Distribution with PVD and CVD Coatings5 10
Coating
Substrate
Depth (mm)
Compression Stress
Tensile Stress
CVD Coating (5-10 mm)
Coating
Substrate
Compression Stress
Tensile Stress 5 10
Depth (mm)
PVD Coating (2-6 mm)

23. CVD Coated Carbide Grades for Turning in the 1990s
IC 8025 and IC 8048
Improved toughness achieved by a cobalt-enriched
layer of the substrate
3rd Generation
4th Generation
3rd Generation
4th Generation
IC 848
IC 825
IC 8025
IC 8048
TiN
Al2O3

24. Basic CVD and PVD Coating Layers of ISCAR Inserts
COLOR CODE Al O 2 3
TiC
TiCN m
TiN m
IC450 X5000 (5 m)
CVD
IC328 X5000 ( )
PVD
2 m m
10 m
IC 418
IC 450
IC 520M
IC 635
IC 656
IC 220
IC 328
IC 428
IC 418
IC 228
IC 350
IC 428
IC 250
IC 3028
Turn
Mill

25. MT-CVD Coated Structure and Properties of Basic CVD Layers
TiN
Al2O3
TiCN
TiN
Substrate
Substrate: High toughness
TiN: Low friction, resistance to BUE
Al2O3: Heat barrier, low heat conductivity
TiCN: Resistance to flank wear
TiC: High hardness

26. The New Sub-Micron (IC 07) and PVD Coated (IC 507) Grades for Turning
Substrate: 6%Co, Cr2C3,WC
Coating: TiCN+TiN 3±1mm
Applications: High-temp. alloys Stainless steel Hard coating Impact resistance
Micro-structure of IC 07
TiN
TiCN
Micro-structure of IC 20
PVD coated IC 507

27. Sub-Micron Carbide Vs. HSS for Endmills
High Toughness
Low Hardness
Low Rigidity
Low Cutting Speed
Low Heat Resistance
High Toughness
High Hardness
High Rigidity (x 3)
High Cutting Speed (x 4)
High Heat Resistance
Excellent Cutting-Edge Form

28. Standard Grain Vs. Sub-Micron Carbide Grades
Sub-Micron improve hardness & toughness
Standard Substrate
Above 1 micron
Sub-Micron Substrate
Below 1 micron

29. New TiAlN Coating for Improved Machining
Coating TiAIN 2-6m, PVD coating
Properties HV
Excellent hot hardness
Superior oxidation resistance
Low thermal conductivity
Sharp cutting edges
Al-oxide protective layer at high temp
Application
Difficult-to-machine materials
High speed machining
Dry machining
Machining of cast iron
Milling and turning of Ti-alloys
Machining stainless steel

30. TiCN Coating (IC 300) Vs. TiAIN Coating (IC 900) Hardened Tool Steelap b
Tool : Ball-Nose 12mm
Material : (60HRC)
ap : 3 mm
b : 0.2 mm
Speed Vc : 200 m/min
Feed fz : 0.16 mm/tooth
Coolant : Dry
Wear Vb : 0.15 mm
IC 300 = 12 m
IC 900 = 24 m

31. PVD Processes of TiAlN Coatings
Futura - up to 20 layers for indexable inserts
X-Tream - for solid carbide end-mills
TiAlN
TiAlN
TiAlN
TiN
Substrate
Substrate

32. Tool Life of Solid Carbide Coated Sub-Micron EndmillsVB
EC TiCN
ECC TiCN
(300)
ECC TiAIN
(900)
Vc: 60m/min
Hardness Steel (50HRC)
0.025
0.050
0.075
0.1 mm
ECC EC
500
1000
1500
2000
2500
3000
3500
4000 mm
5000
Machining Length L

33. Test Report - HSS Vs. Solid Carbideae ap
Machine: Victor (7.5 KW)
Material : X40CrMoV5.1(1.2344)
ap: 20 mm ; ae : 10 mm
Coolant : Wet
R 87.5
Ø200 R5 10
12.5
49•
HSS
Rougher
ISCAR
Solid Carbide
Tool
Grade
Price net (fl)
Speed Vc (m/min)
Feed Vf (mm/min)
Q (cm3 / min)
Cycle time (sec)
Tool life (pieces)
Mach. costs(fl)
10 x 20 x 4Z
TiCN 70
31.5
120 22
214 55
10.23
EC100B22-3W10
IC900
114.6
125
500
100 58 25
4.09
Savings per product fl. 6,16 (60%)

34. Impact Resistance of PVD and CVD Coated Grades in Interrupted Turning50 60 70 80
100
(165)
(204)
(230)
(265)
(330)
m/min
(sfm)
200
(660)
300
(1000)
400
(1320)
CVD-TiN
(IC520M)
Cutting Speed Vc
500
700
1000
Workpiece: SAE 4140 (980 N/mm2)
Insert : SDMT (433)
f : 0.2 mm/rev (.008 ipr)
ap : 2.5 mm (.10 in)
Dry Cutting
5000
3000
2000
7000
10000
20000
40000
Number of Impacts n
PVD
(IC250, IC328)

35. Improvement of Tool Life with Rib type Rake Face
SEKR
Improved tool life on stainless steel
with -76 type and IC 328
Workpiece
Material
Carbide
Grade
Vc (sfm) Fz
Tool Life TL
Designation
SEKR 1203 AFN-76
SEKR 1203 AFN-42
120
0.1
30’
20’
28’
18’
17-4 PH
IC 328
(400)
0.1
(.004”)
17-4 PH
IC 328 80
0.1
SEKR 1203 AFN-76
50’
(260)
Inconel
IC 328 25
0.1
(205)

36. New TiAlN PVD Coated Grades
IC910 (K10-K25): Milling cast iron
IC950 (P10-P25): Milling carbon steel, alloy steel and stainless steel; High cutting speed and dry machining
IC928 (P20-P50, M20-M40, K15-K40) Alloy steel, Stainless steel
IC908 (P15-P30, M20-M30, K20-K30) High temp alloys, Ni-base, Ti-base
Features
Hardness: HV 3000
Excellent hot hardness
Sharp cutting edges
Superior oxidation resistance
Low thermal conductivity
Al-oxide protective layer at high temp.

37. Comparison of Cutting Speeds Between Popular and New Grades
New grades cut 20% faster or have longer tool life.
MT-CVD
(Al2O3)
PVD( TiAlN)
PVD( TiAlN)
PVD (TiAlN)
CVD
(Al2O3)
PVD
( TiCN)
CVD
(Al2O3)
PVD( TiN)
High Temp.
Alloys &
Stainless Steel
Cast Iron GG
Alloy Steels
Nodular
Cast Iron
GGG

38. Tool Life in Milling SAE 1045 Steel with PVD Coatings (ISO K20 Substrate)
120
100 80
TiAIN
TiCN 60
Lifetime Cutting Distance (m) 40
TiN 20
Uncoated
100
200
300
400
Cutting Speed (m/min)

39. Ceramics and Silicon Nitrides for Machining

40. Features of Ceramic Inserts
High temperature hardness and toughness (hot hardness)
Excellent chemical and thermal stability
Suitable for machining difficult-to-cut materials and hardened steel
High speed turning and milling of cast iron

41. Ceramics :Processing Capabilities
Purchase APT
Press
Extrude
Shape
Reduce to Tungsten Trioxide and/or Tungsten metal Powder
Blend, mix with carbon powder,
Crush and blend
Blend for uniformity and to reduce grain size
Spray dry
Rough machine (turn, cutoff, grind)
Sinter HIP
Finish grind
Similar process cycle for ceramics

42. Cold (CIP) and Hot (HIP) Isostatic Pressing, Inertgas, Ar
P= 1000 kg/cm2(15,000 psi)
High density&homogeneous forming
Minimum deformation during sintering
Capable of producing large workpieces
HIP
Complete elimination of porosities
Improvement of mechanical properties (strength, TRS etc )
High reliability &longer tool life

43. Basic Data for the Physical Properties of Ceramic Grades
IN11
IN22
IN23
IS8
IS80*
Compo- sition
Main
Elements
Density
(g/cm3) HV
Bending Strength (MPa)
Hardness
HRa
Al2O3
Al2O3 -TiC
Si3 N4
4.0
4.3
4.2
3.2
2100
2350
2400
1700
94.2
94.5
94.6
93.6
650
700
750
1000
---
450
550 RT
1200ºC
Fracture Toughness
(MN/m1.5)
K 1C
4.5 5 7
Thermal Conductivity
(cal/cm sec Cº)
Properties of substrate

44. Ceramic Grades: Structure & Chemical Composition
IS8
IS80
IN11
IN22
IN23
Chemical Composition
Al2O3
ZrO2
Al2O3
TiC
Al2O3
TiC
Si3N4
Al2O3
Y2O3
Si3N4
TiN CVD
Coating
Color
Yellow
White
Black
Black
Light
Gray

45. SiN Tool Life in Continuous Turning
Material : FC25, (Gray Cast Iron, HB )
Workpiece : Brake drum
Insert : SNGN120416,
TNGN160416
Cutting conditions
Vc : 400 m/min
f : mm/rev
ap : mm
Coolant : Wet 50
min 30 20
Tool Life
Cutting Speed
200
400 10
600
m/min
TNGN160416
SNGN120416
Dry
Wet

46. Machining Directions New Cutting Tool Materials for High Speed Cutting, Dry Cutting and Hard Cutting

47. Main Factors Influencing High Speed Machining, Hard Cutting & Dry Cutting
HSM: High-speed machining HC: Hard cutting DC: Dry cutting
Insert Clamping
Insert design Geometry
Chipformer
Balancing,Run- out
Security, Safety
Tool Changer
Composition
CBN, Cermets,
Ceramics,
Sub-Micron, Carbides
SiN, PCD
Coatings
PCD, CVD
CVD+PCD
Properties
Hardness
Hot Hardness
Heat Conductivity
Toughness
Clamping
Jigs, Fixtures
Composition
Properties
Geometry
Tool Design
Workpiece
HSM HC DC
Tool Materials
Vc, ƒ,a, Z Coolant-Flushing
Continuous or Interrupted
Machining
Conditions
Machine Tool
Performance
Tool Clamping
Stability, Vibration
Spindle(Hydrostatic
Mechanical)
Bearing, Slides
Control&
Automation
Tool Life
Removal Rate
Surface Quality
Surface Integrity
(Stress, Cracks, etc.)
Forces, Power
Machining Time

48. Hard Cutting with CBN Machining Non-Ferrous Materials, Al-Alloys and Composites with PCD

49. Manufacturing Process
Optimization of the
Manufacturing Process
Metal Forming Casting, Forging, Powder Metallurgy, etc.
Machining Rough Cutting, Non-Conventional, etc.
HSM (HSC) High Speed Machining DC Dry Cutting HC Hard Cutting
Heat Treatment
Finishing Machining and Others
Cutting
Grinding
Coating
Finished Product

50. Ferrous Materials in Harder Stages
for Hard Cutting
White Cast Iron
Hot work tool steel, cold work tool steel
carbon tool steel
Ball bearing steel
Case hardened steel
Heat-treatable
steel
HSS 50 55 60 65 70
Hardness due to carbide
Hardness due to
martensite
Hardness
HRc

51. IN22 Applications & Machining Conditions
Hardened steel and difficult-to-cut material
chilled cast iron, high-speed steel
and high chromium steel ,etc.
Recommended Cutting Conditions
Workpiece
Speed
m/min
Feed
mm/rev
Depth of Cut mm
Chilled Cast
Iron
30-200
High Speed
Steel
Hardened Steel
(>HRc 50)
30-150
Tool Steel
1-3
Coolant
Dry

52. High Speed Machining with
Part: Mold preparation
Material Nr. and Hardness: P20 mold steel HRc
New IC 908 Sub-micron with TiAlN PVD coating
New IC 950 Regular carbide with TiAlN PVD coating
Roughing
CM - D16 - B - C20
CR D160 - QF IC908
150
2 x 4 mm
3000
120 min
Finishing
CM - D16 - B - C20
CRF D160 - QF IC950
200
0.75 x 0.75 mm
4000
630 min
Tool
Insert
Speed mm / min
Width & Depth
Revolutions / min
Tool Life

53. Machining of Bearing Outer Ring with CUT-GRIP
Turning and
under cutting
GHDL +
CBN
Inserts 2 3 1 A A

54. CBN, New Cutting Material for Machining Hardened Steel
GITM 5.00K-2.50
GITM 5.00K-0.40
For HRc
Inserts width 3-8mm
Special

55. Machining Synchronizing Ring with CBN CUT-GRIP Tools
Machining the walls with 2 CBN inserts
(Right-hand and Left-hand)

56. Tool Life in Finish-Turning on Hardened Steel
[ WZL, T.H. Aachen]
1000
100 10 1
Super Precision
High Precision
Finish Turning
Tool material
Workpiece material
PCD
Copper
Brass
CBN
Heat treated steel
54/56 HRc
Austenitic stainless
85 HRb
CBN/Ceramic
Bearing steel
62 HRc
Tool Life (Km)

57. Comparison of Surface Roughness & Cutting Forces
in Finishing Operation [WZL, T.H. Aachen] 10 µm
Surface
Quality Rt
0, 1
0,01
0,001 Fc Ff Fp
1000 N
Cutting forces
Fc, Fƒ, Fp 10 1
0,1
Super Precision
High Precision
Finish Turning
Tool material
PCD
Copper
CBN
Steel
56 HRc
CBN
Bearing steel
62 HRc
Ceramic
Bearing steel
62 HRc
Workpiece material
Feed
0,003 mm / rev
0,003 mm
0,005 mm / rev
0,005 mm
0,02 mm / rev
0,05 mm
0,08 mm / rev
0,40 mm
Depth of cut

58. High Speed Machining H. S. M
Spindle Rotation: 10, ,000 RPM

59. High Speed Machining (HSM)Vs Conventional Machining Speeds
Reinforced Plastic
Conventional Speeds
HSM Range (HSC)
Conventional Speeds
HSM Range (HSC)
Aluminum Alloys
Non-ferrous materials Brass, Bronze, Copper
Cast Iron
Carbide Tools SiN Tools
Steel Alloys Carbon & Tool Steel
Titanium Alloys (Ti6Al 4V, etc.)
Hardened Steel (45) HRc
Nickel Alloys (Inconel, Waspaloy)
Cutting speed , m/min ,000

60. High Performance Cutting
High Speed and Feed

61. Super Finishing Operations with High Speed Milling
Face Milling of Automotive Components
Tool: F90AL-D INT40
Insert: LNCR-1404-PDXR IC 28
High cutting speed
High quality surface finish
Tool with built-in pump
Tool balancing option
Cutting Speed: n= 8000 RPM
Table Feed: Vf = 8000 mm/min
Depth of cut ap= 0.8 mm
Vc= 3925 m/min
LNCR-1404-PDXR

62. Milling Cutter Design for Machining Aluminum at High Cutting Speeds

63. Dry and Wet Cutting

64. Coolant Requirements H. S. M P. C
Dry Machining
High Pressure

65. Infuence of Coolant and Chipformers on Tool Life
WNMG (432) - ## CVD TiCN+TiN

66. Tool Life with PVD Coated Grades Coated Cermet & TiCN Coated
Workpiece: SAE 1045
Vc = 260 m/min
f = 0.18 mm/rev
ap = 2 mm
Without Coolant
WNMZ 06T304(3-1)-LF
Coated Cermet
0.25 (.010)
0.20
0.15
0.10
0.05
Vb mm(inch) 4’
12’
20’
28’
Time 0’ 8’
16’
24’
TNMZ (431)-LF
ISO P20 TiCN Coated

67. Influence of Chipformers on
Wear In Dry Cutting
WNMG (432)-## CVD TiCN+TiN
Material: SS 316L
Hardness: 180HB
Vc= 220m/min
f= 0.25mm/rev
ap= 4mm
Without Coolant.
Flank wear
0.052 Vb
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1 TF
Notch wear
Rigidity: Good PP 4
min 8

68. Effect of Pressurized Air Cooling on Tool Life
Workpiece SAE1045
Emulsion 5%
Pressurized Air cooling
120 μm
100
Flank Wear Width VB 80 60 40 20
TiN
TiCN
TiAIN

69. Flushing Option During Grooving
Chip
Workpiece
Chip
Workpiece
Insert
Insert
Coolant
Coolant
Chip
Chip
Cutting Edge
Cutting Edge
Coolant
Workpiece
Chip
Frontal Flushing
Internal Flushing
(Jet-Cut)
Chip
Insert
Cutting Edge
Top Flushing

70. Wear of Uncoated SELF-GRIP Inserts

71. Machingng of Inconell 718 Breakage  Grooving INCONEL 718
Number of Groove
Machining conditions :
Vc=30 m/min.
f=0.18 mm/rev.
INSERT
 GFN -3 IC20
 GFN -3 IC20-14 atm.
 GFN -3 IC20-14 atm.
 GFN -3M IC20-14 atm
0.25
0.20
0.15
0.10
0.05 1 2 3 4 5 6 7 8 9 10
Wear land VB (mm)
Grooving INCONEL 718
Top
(1 atm)
(14 atm)
JET-CUT
JET-CUT+”M ”
Breakage 25
100   