Beta C Spring made from PAM Single Melt Input Stock K.O. Yu 1, C.M. Bugle 2 and C. Pepka 3 1. RTI International Metals, Inc., Niles, OH 2. Dynamet Incorporated, Washington, PA 3. Renton Coil Spring Co., Renton, WA TITANIUM 2005 ITA 21 ST Annual Conference and Exhibition Scottsdale, AZ September 25-27, 2005
Outline Introduction Single melt PAM ingot Bar rolled from as-cast PAM ingot Heat treatment of rolled bar Coil making and evaluation Summary
Introduction Beta C is a high strength titanium alloy widely used for spring and fastener applications Input billet for bar rolling is currently made by VAR + Open Die Forging + GFM Forging route Use as-cast PAM single melt ingot as input stock for bar rolling provides potential to reduce cost Team effort to evaluate single melt Beta C product * RMI make PAM ingot, heat treatment study * Dynamet roll bar, heat treatment study * Renton Coil make coil, product evaluation
Comparison of Mill Processes for Beta C Bar Hot Rolled from VAR and PAM Ingots VAR PAM 30-Inch Diameter VAR Ingot Press Forge to Intermediate Size (Several Reheats) Press Forge to GFM Forged Input Size (Several Reheats) GFM Forge to Billet (Rough Turn to Approx. 4-inch Dia.) 5-Inch Diameter PAM Ingot Bar Rolling + Coil Manufacturing
Titanium Melting Processes Vacuum Arc Remelting (VAR) Plasma Arc Melting (PAM) Feeder Solid Skull Liquid Pool Plasma Torch Plasma Plume Pool Surface Depression Hearth Copper Crucible Continuously Cast Ingot
Plasma Arc Melting (PAM) Ingot
As-Cast Structure of PAM Ingots Transverse Longitudinal 5 cm 2 cm
Chemistry of Beta C 5 Single Melt PAM Ingot Chemical Composition, wt.% Location Al V Cr Mo Zr Top 3.3 7.9 6.4 4.3 4.1 Bottom 3.4 8.4 6.5 4.4 3.4 AMS 4958 3.0-4.0 7.5-8.5 5.5-6.5 3.5-4.5 3.5-4.5
Bar Rolling
Rolled 0.6 Bar
Evaluation of 0.6-Inch Diameter Beta C Bar Produced from 5-Inch Diameter PAM Ingot Heat Treatment Study - Determine effect of heat treatments on aging response and microstructure Selection of Heat Treatments for Mechanical Property Evaluation Mechanical Property Evaluation - Tensile - Fatigue - Double shear
Heat Treatment Studies Solution Treatment (ST) 1. Effect of ST temperature Aging 2. Effect of direct aging temperature 3. Effect of aging temperature after ST 4. Effect of aging time after ST Different Routes 5. Effect of as-cast PAM vs. forged VAR
Effect of ST Temperature on Macrostructure ST 1400 F or 1450 F or 1500 F, 30m, AC; Aging 925 F, 24hr, AC 0.6 1400 F 1450 F 1500 F
Effect of ST Temperature on Microstructure ST 1400 F or 1450 F or 1500 F, 30m, AC; Aging 925 F, 24hr, AC L T 1400 F 1450 F 1500 F
Effect of ST Temperature on Tensile Strength ST 1400 F or 1450 F or 1500 F, 30m, AC; Aging 925 F, 24hr, AC 209 208 207 9.75% UTS (ksi) 206 205 204 203 202 10.35% 201 200 199 9.3% 1400 1450 1500 ST Temperature (F) *Percent of Elongation
Effect of Direct Aging Temperature Direct Aging at 975 F vs. 925 F, 24 hrs, AC 925 F 975 F
Effect of Direct Aging Temperature Direct Aging at 975 F vs. 925 F, 24 hrs, AC 230 225 9% UTS (ksi) 220 215 210 205 11.8% 200 925 950 975 Temperature (F) *Percent of Elongation
Effect of Aging Temperature after ST on Macrostructure ST 1400 F, 30m, AC; Aging 900 F vs. 925 F, 24 hr, AC 0.6 900 F 925 F
Effect of Aging Temperature after ST on Microstructure ST 1400 F, 30m, AC; Aging 900 F vs. 925 F, 24 hr, AC L T 900 F 925 F
Effect of Aging Temperature after ST on Tensile Strength (UTS) 300 UTS (ksi) 250 200 150 100 8.6% 9.75% 50 0 900 905 910 915 920 925 Temperature (F) *Percent of Elongation
Effect of Aging Time after ST on Macrostructure ST (1500 F, 30m, AC); Aging at 925 F for 8 or 16 or 24 hrs, AC 0.6 8 hrs 16 hrs 24 hrs Longer aging time leads to more alpha precipitation. The surface and intermediate area have less alpha precipitation.
Effect of Aging Time after ST on Microstructure ST (1500 F, 30m, AC); Aging at 925 F for 8 or 16 or 24 hrs, AC L Direction 8 hrs 16 hrs 24 hrs
Effect of Aging Time after ST on Tensile Strength (UTS) ST (1500 F, 30m, AC); Aging at 925 F for 8 or 16 or 24 hrs, AC 205 UTS (ksi) 200 195 190 185 9.65% 9.3% 180 175 11.05% 8 16 24 Aging Time (hrs) *Percent of Elongation
As-Cast PAM vs. Forged VAR ST (1500 F, 30m, AC); Aging at 925 F for 8 or 16 or 24 hrs, AC T Direction VAR + PAM + 8 hrs 16 hrs 24 hrs
As-Cast PAM vs. Forged VAR ST (1500 F, 30m, AC); Aging at 925 F for 8 or 16 or 24 hrs, AC 250 200 11.05% 9.65% 9.3% UTS (ksi) 150 100 23.55% 16.05% 11.95% PAM VAR 50 0 0 5 10 15 20 25 30 Time (hrs) *Percent of Elongation
Double Shear Strength of Beta C Bar Produced from VAR and Single Melt PAM Ingots 160 140 Double Shear Stength, ksi 120 100 80 60 40 20 Shear Strength, ksi (VAR) Shear Strength, ksi (PAM) Linear ( Shear Strength, ksi (VAR)) 0 100 120 140 160 180 200 220 240.2% Yield Strength, ksi
Fatigue Data for Beta C Heat Treated Bar Produced from VAR and Single Melt PAM Ingots 160 140 Maximum Stress, ksi (R=0.1) 120 100 80 60 40 20 176 ksi UTS PAM 225 ksi UTS PAM 193/206 ksi UTS VAR 0 1.00E+03 1.00E+04 1.00E+05 1.00E+06 1.00E+07 Cycles to Failure
Coil Manufacturing Harsh Coiling Test mandrel size = wire size x 2
Coil Manufacturing PAM Beta C bar successfully passed such a test
Coil Manufacturing Bars made from single melt PAM ingot have successfully passed the Harsh Coiling Test Cycle test of springs is in-progress Microstructure and mechanical property evaluations are in-progress
Summary Beta C bars produced from as-cast PAM ingot have successfully passed the Harsh Coiling Test Tensile properties of single melt bars are comparable to those of VAR processed bars and meet the requirement of AMS 4958 (180 ksi min. UTS and 8% min. elongation) Spring cycle test and mechanical property evaluation are in-progress; results will be reported in the future