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- 1. OPEN DEFENCE STUDY OF THE EFFECT OF DEEP CRYOGENIC TREATMENT ON TOOL STEELS BY C.L.GOGTE 27 TH JANUARY 2009 SUPERVISORS: 1.DR.R.K.PARETKAR 2.DR.D.R.PESHWE DEPARTMENT OF METALLURGICAL AND MATERIALS ENGINEERING, VISVESVARAYA NATIONAL INSTITUTE OF TECHNOLOGY, NAGPUR
- 6. TEMP 0 C TIME HRS HARDENING (AUSTENITIZATION) TRIPLE TEMPERING CONVENTIONAL HEAT TREATMENT WITH SUBZERO COOLING OF HIGH SPEED STEELS SUBZERO COOLING TO -80 0 C TO -120 0 C, DEPENDING UPON COMPOSITION
- 7. CRYOGENIC TREATMENT (CT) A BRIEF INTRODUCTION CRYOGENIC TEMPERATURES < SUBZERO TEMPERATURES (~ -100 0 C) (M f ) USING DRY ICE LIQUID NITROGEN (LN 2 ) UPTO -196 0 C OR Ar OR He etc FIRST EXPERIMENTATION RESULTS ON TOOL STEELS AND OTHER METALLIC MATERIALS PRESENTED BY BARRON IN 1982 OUTCOME IMPROVED WEAR RESISTANCE
- 8. Influence of varied CT on the wear behavior. Concluded about existence of critical time duration for achieving best wear resistance for D2 steel through CT. Nature of precipitation of carbides during CT explained. D2 Das 45 et al, 2009 Quantification of property improvements and correlation with microstructural changes after CT. Differential contraction between matrix and the primary carbides was observed during CT. Change in the dislocation density during CT proved. M2 Kelkar 44 et al, 2007 Study of variation of tempering temperature during CT and its effect. The wear resistance was found to increase with increasing tempering temperature. M2 Leskovsek 43 et al, 2005 Investigation of fatigue life of weldments due to CT. Improvement in the fatigue life was observed. 304L Johan Singh 42 et al, 2004 Microstructural studies of changes before and after CT. Concluded that CT can facilitate formation of carbon clustering and increase the carbide density at the defects, which leads to precipitation of fine carbides during tempering after CT. M2 J.Y.Huang 41 et al, 2003 Investigations in to the effect of CT on microstructure, mechanical properties and dimensional stability. Highest fracture toughness and hardness were achieved, when retained austenite was totally transformed in to martensite. Shape distortion was observed after CT due to stresses. Precipitation of rod like fine carbides was detected after CT. M2 V.Leskovsek 40 et al, 2002 Study of CT effect by both field tests and laboratory tests. Field tests confirmed improvement in tool life and cost reduction by 50%, Laboratory tests confirmed wear resistance improvement by CT after conventional treatment M2, H13 Molinari 39 et al, 2001 Study of the structural change responsible for the improvement in the wear resistance due to CT . Concluded formation of η carbide during CT D2 F.Meng 38 et al, 1994 Validation of the effect of CT on different varieties of alloy steels. M2, and D2 Barron 14 R.F, 1982 OBJEFCTIVES AND CONCLUSIONS MATERIAL AISI RESEARCH BY
- 9. THE PROCESS 1. IMMEDIATELY AFTER HARDENING FOLLOWED BY MULTIPLE LOW TEMPERATURE TEMPERING OR 2. AFTER CONVENTIONAL HARDENING AND TEMPERING FOLLOWED BY MULTIPLE LOW TEMPERATURE TEMPERING. CRYOGENIC TREATMENT -
- 10. THIS ROUTE WAS FOLLOWED IN THIS WORK AS HSS M2 AND T42 ARE VERY SENSETIVE TO LOW TEMPERATURES. COMMERCIALLY, THIS ROUTE IS MORE PREFERRED. HARDENING 1230 0 C (1503K) TEMPERING 560 0 C (833K) CRYOGENIC TREATMENT AT –185 0 C (88K) LOW TEMPERATURE TEMPERING 150 0 C (423K) TIME HRS TEMPERATURE DEG C
- 11. AISI M2 AND AISI T42 HIGH SPEED STEELS PILOT EXPERIMENTATION 10.0 3.2 3.6 9.5 4.0 1.27 T42 NIL 1.8 5.0 6.4 4.2 O.9 M2 Co V Mo W Cr C ELEMENTS WT % TOOL STEEL AISI
- 12. CONVENTIONAL T42 500X T42 WITH CT FOR 24 HRS SOAKING PERIOD 500 X OPTICAL MICROSCOPY
- 13. PILOT RESULTS FOR AISI M2 -185/24 -185/8 -185/4 -185/2 -185/1 -140 -80 CON
- 14. PILOT RESULTS FOR AISI T42 -185/24 -185/8 -185/4 -80 -140 -185/1 -185/2 CON
- 15. PILOT RESULTS EFFECT OF CT ON HARDNESS 1 63.8 3 64.4 H 1 64.2 2 64.6 G 1 64.4 2 64.4 F 2 64 3 64.2 E 2 64.2 2 64 D 2 64 2 64 C 2 63.8 2 64 B - - 2 64.2 A RANGE (MAX – MIN) AFTER TREATMENT AND TEMPERING, AVERAGE BULK HARDNESS R c RANGE (MAX – MIN) CONVENTIONAL AVERAGE BULK HARDNESS R c SAMPLE IDENTIFICATION
- 18. C CONVENTIONAL T42 AND ELEMENTAL MAPPING VC V Fe W A B C
- 19. (V,W)C EDS - COARSE CARBIDE Counts 0.00 1.00 2.00 3.00 4.00 5.00 6.00 7.00 8.00 9.00 10.00 keV 001 0 150 300 450 600 750 900 1050 1200 1350 1500 V Mo W
- 20. EDS - MATRIX 0.00 1.00 2.00 3.00 4.00 5.00 6.00 7.00 8.00 9.00 10.00 keV 0 300 600 900 1200 1500 1800 2100 2400 Counts C V Cr Fe Co Mo W V W Fe Cr W
- 21. W2C EDS - FINE CARBIDE 0.00 1.00 2.00 3.00 4.00 5.00 6.00 7.00 8.00 9.00 10.00 keV 0 300 600 900 1200 1500 1800 2100 2400 Counts C V V Fe Fe Co Mo W W W Cr
- 22. MICROSTRUCTURAL CHANGES SHAPE SIZE DISTRIBUTION CON + CT + TEMPER (8 HRS)
- 23. CONVENTIONAL AFTER CT AFTER TRIPLE TEMPER CRACK ELIMINATION CON + CT + TEMPER (8 HRS)
- 24. CONVENTIONAL AFTER CT AFTER TRIPLE TEMPER CON + CT + TEMPER (16 HRS)
- 25. CON + CT + TEMPER (24 HRS) CONVENTIONAL AFTER TEMPERING
- 26. 24 HOURS SOAKING PERIOD
- 27. VOIDS AROUND CARBIDES 24 HOURS SOAKING PERIOD
- 28. AREA FRACTION ANALYSIS INCREASE IN AREA FRACTION OF CARBIDES VALIDATES EARLIER RESEARCH
- 29. SIZE ANALYSIS THE CLUSTERS OF FINE CARBIDES ARE MISTAKEN FOR A SINGLE PARTICLE OF BIGGER SIZE. INCREASE IN THE SIZE OF THE PARTICLES IS AN INDICATION OF COARSENING OF THE PARTICLES
- 30. NUMBER OF PARTICLES AT DIFFERENT STAGES PRECIPITATION OF CARBIDES OCCURS FROM THE MATRIX, DURING HIGHER SOAKING PERIODS PAST RESEARCH SUPPORTS PRIMARY COARSE CARBIDES NOT AFFECTED (24 HOURS) PRECIPITATION OF ONLY CARBIDES
- 31. THE SAMPLES WITH CT AND AFTER TEMPERING SHOW MORE UNIFORM WEIGHT LOSS DURING WEAR
- 32. ε = 1 FOR CONTROL SAMPLE ε = 1.38 FOR 8 HOURS ε = O.957 FOR 16 HOURS ε = 0.8820 FOR 24 HOURS ε = W0 / W W0 – WT LOSS OF CONTROL SAMPLE W – WT LOSS OF OTHER SAMPLE
- 33. TEM INVESTIGATIONS ONLY PARTICLES LESS THAN 1 MICRON ANALYZED EDS (MATRIX) CONVENTIONAL T42 1 MICRON LATH MARTENSITE 01.80 02.90 MoK 02.00 06.10 W L 10.90 10.80 CoK 79.50 75.10 FeK 04.80 04.20 CrK 01.10 00.90 V K Atomic % Weight % Elem QUANTIFICATION
- 34. VC0.88 535 nm 785 nm 714 nm 500 nm CONVENTIONAL T42 12.50 14.40 MoK 20.10 44.10 W L 00.90 00.60 CoK 07.80 05.20 FeK 04.90 03.00 CrK 53.70 32.70 V K Atomic % Weight % Elem CARBIDE VC QUANTIFICATION EDS – AT 785 nm PARTICLE
- 35. (R2)2 / (R1)2 = 18.0625 ≈ ( 4 1 1) (R3)2 / (R1)2 = 14.0625 ≈ ( 3 2 1 ) R1 = 2 mm R2 = 8.5 mm R3 = 7.5 mm MEASURED Φ23 = 19 deg Φ13 = 78 deg CARBIDE IDENTIFICATION BY INDEXING (RATIO METHOD) Ref: Ramachandran et al (4 1 1) (1 1 4) (3 2 1) (0 0 0) PLANES MATCHED WITH THE CARBIDE VC0.88 WITH ANGLES Φ23 = 19.098 deg AND Φ13 = 79.07 deg, WHICH MATCHES WITH MEASURED ANGLES ± 5 DEG. SADP
- 36. 15.90 14.90 MoK 31.40 56.50 W L 05.60 03.20 CoK 39.00 21.30 FeK 05.00 02.50 CrK 03.10 01.50 V K Atomic % Weight % Elem a b c d M 6 C - Fe 3 W 3 C T42 WITH CT
- 37. a) Magnification 100k X b) Magnification 125k X Martensite in T42 with CT (8 Hours soaking period) and Triple tempering
- 38. a) b) c) d) Deformation bands Dislocations Magnification 100k X Magnification 28k X Magnification 35k X Magnification 35k X 1.2 μm 571 nm 607 nm 1 μm 514 nm
- 39. AFTER 8 HOURS SOAKING PERIOD MATRIX DISLOCATIONS MATRIX-CARBIDE INTERFACE DISLOCATIONS CARBIDE DISLOCATION CLOUDS AT THE MATRIX CARBIDE INTERFACE. Magnification 66k X Magnification 88k X
- 40. AFTER 8 HOURS SOAKING PERIOD AND TEMPERING SADP EDS (PARTICLE) IDENTIFICATION M 6 C (Fe 2 W 4 C) η CARBIDE 16.80 16.50 MoK 27.80 52.20 W L 46.30 26.40 FeK 05.60 03.00 CrK 03.60 01.90 V K Atomic % Weight % Elem PARTICLE SIZE Largest diameter – 700 nm Smallest diameter – 100 nm MAGNIFICATION 35k X EDS QUANTIFICATION
- 41. CT WITH 16 HOURS SOAKING PERIOD Deformation Bands in Martnsite a) Magnification 125k X b) Magnification 28k X Dislocation cloud
- 42. CT WITH 24 HOURS SOAKING PERIOD Magnification 28k X EDS - CARBIDE MC 13.20 15.80 MoK 17.40 39.80 W L 00.40 00.30 CoK 04.40 03.10 FeK 06.90 04.50 CrK 57.70 36.60 V K Atomic % Weight % Elem CARBIDE QUANTIFICATION MC TYPE OF CARBIDE
- 43. CT WITH 24 HOURS SOAKING PERIOD 01.30 02.10 MoK 01.30 04.10 W L 10.70 10.90 CoK 80.30 77.20 FeK 05.30 04.70 CrK 01.20 01.10 V K Atomic % Weight % Elem EDS - MATRIX Magnification 45k X QUANTIFICATION Carbide size: 400 nm Gap between particle edge and the matrix = 30 nm
- 45. XRD INVESTIGATIONS: DIFFRACTION PATTERN OF CONVENTIONAL T42 30 40 50 60 70 80 90 100 110 Counts 0 200 400 600 V C0.88 V C (1 1 1) Mo2 C (0 2 2) W2C (1 0 2) MARTENSITE (1 1 0) Mo2 C (0 2 2) VC (5 3 0) Mo2 C (0 4 2) Cr23 C6 (9 1 1) Co (3 1 1)
- 46. PARTICLES IDENTIFICATION (PATTERN LIST) CONVENTIONAL T42 Co -0.059 Cobalt 12 00-001-1255 * Mo2 C 0.370 Molybdenum Carbide 16 01-071-0242 * Cr23 C6 -0.020 Chromium Carbide 4 00-035-0783 * W2 C 0.192 Tungsten Carbide 11 01-079-0743 * V C0.88 -0.376 Vanadium Carbide 13 01-077-2003 * V C -0.400 Vanadium Carbide 11 01-073-0476 * C0.08 Fe1.92 0.090 Martensite 37 00-044-1291 * Chemical Formula Displacement [°2Th.] Compound Name Score Ref. Code Visible
- 47. DIFFRACTION PATTERN FOR T42 AFTER CT (8 HRS) Counts Position [°2Theta] 30 40 50 60 70 80 90 100 110 0 200 400 600 V C0.88 V C Mo2 C W2 C MARTENSITE Mo2 C V C Mo2 C Cr7 C3 (10 0 ) Co T 2 cryo
- 48. PARTICLES IDENTIFICATION (PATTERN LIST) FOR T42 AFTER CT (8HRS) Cr7 C3 0.115 Heptachromium tricarbide 29 00-036-1482 * Co 0.068 Cobalt 12 00-015-0806 * W2 C 0.186 Tungsten Carbide 7 01-079-0743 * V C0.88 -0.333 Vanadium Carbide 11 01-077-2003 * V C -0.356 Vanadium Carbide 9 01-073-0476 * Mo2 C 0.313 Molybdenum Carbide 7 01-071-0242 * C0.08 Fe1.92 0.090 Martensite 37 00-044-1291 * Chemical Formula Displacement [°2Th.] Compound Name Score Ref. Code Visible