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Die Cast Aluminum Heat Sinks for Tank Tracks

Laser Deposited and Pre-Hardened Steel Rapid Tooling Case Western Reserve University / NADCA David Schwam. Die Cast Aluminum Heat Sinks for Tank Tracks. Material: A380 Size:4.5”x2.5”x1.15” Weight: 1.1 pounds. ABSORBS HEAT FROM THE RUBBER, EXTEND TRACK LIFE, PREVENT STRIP-OFF FAILURE.

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Die Cast Aluminum Heat Sinks for Tank Tracks

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  1. Laser Deposited and Pre-Hardened Steel Rapid Tooling Case Western Reserve University / NADCADavid Schwam

  2. Die Cast Aluminum Heat Sinks for Tank Tracks Material: A380 Size:4.5”x2.5”x1.15” Weight: 1.1 pounds ABSORBS HEAT FROM THE RUBBER, EXTEND TRACK LIFE, PREVENT STRIP-OFF FAILURE

  3. Die Cast Aluminum Heat Sinks for Tank Tracks Industrial Partner: St. Clair Die Casting, St. Clair. MO Die Material: Pre-hardened 42 HRC Dievar Leadtime: Three weeks Key Advantage: Short lead time. 49,000 parts (x4) were die cast with this pre-hardened tool.

  4. Shovel Nut DLA part. Industrial Partner: Empire Die Casting-Twinsburg, OH Die Material: Pre-hardened 42 HRC Dievar Leadtime: Three weeks (instead of 14 weeks) Key Advantage: Two hundred prototype parts were initially required. Production run is expected to exceed 100,000. So far at 49,000. The projects is running production with the prototyping tool, thus saving the entire cost of tooling.

  5. Display Control Module DRS’s Driver’s Vision Enhancer (DVE) Display Control Module (DCM) is a 10.4" liquid-crystal display (LCD) providing a rugged display technology to the warfighter on today’s digital battlefield.

  6. Warfighter Relevance

  7. Objectives • Problem • Current tool building practices are costly and time consuming • require sequential rough machining • heat treating • machining to final size • use steel that does not allow fast heat removal and optimal control of the thermal profile • Objective • Demonstrate rapid tooling methods • Use of pre-hardened steels to shorten lead times and extend die life • Use of high thermal conductivity materials including Toolox 44, Anviloy and laser deposited rapid and bi-metallic tooling to improve rate of production

  8. Benefits • Accelerate fabrication of parts made by metal mold technologies • Rapid tooling for die and permanent mold casting • More adaptive to frequent changes in design than • traditional tool making methods • Can quickly provide small, prototype batches yet, if needed, make production quantities • Demonstrate increased productivity and better mechanical properties of the castings by use of high thermal conductivity die materials

  9. Technical Approach Utilization of pre-hardened advanced steels to shorten lead-time and lower tooling cost Use of high thermal conductivity materials (laser deposited H13 on copper, Toolox 44 and Anviloy cores)

  10. Utilization of Pre-Hardened Superior Steels to Shorten Lead-Time and Lower Tooling Cost

  11. Display Control Module

  12. Implementation at Twin Cities Die Casting • Anticipated production was 40,000 parts • Using Pre-hardened tool steels of various types. Heat treat was 40 – 42 RC. • Machining method was primarily High Speed but some Electro-Discharge Machiningalso.

  13. Project Volume Increased • Original plan was to cast no more than 40,000 parts. • Tooling started to show some washout and heat checking around 20,000 shots. • Notified by customer that there would be a second order coming after completing the first 40,000 parts.

  14. Heat Check and Washout Inside after 24,000 shots

  15. Heat Checking Outside after 24,000 Shots

  16. Steel Repair Method • Steel checked for hardness. Steel had softened through usage to 39–40 HRC down from 40-42 HRC. • Cavity steel was ultrasonically cleaned, machined, welded and re-cut, polished and then nitrocarburized after 28,000 shots. • Repair lasted balance of first order.

  17. After Repair at 38,000 Shots

  18. After Repair at 38,000 Shots

  19. Tool Steel after First 40,000 Shots

  20. Next Order is Being Processed for 20,000 Parts • Steel has been polished and then Shot Peened. • Nitride re-applied after last maintenance. • Steel checks 39–40 HRC; no change from 20,000 shots. • Estimated life to replacement is another 40,000 shots. • Cost and time metrics needed

  21. Use of High Thermal Conductivity Materials: Laser Deposited H13 on Copper, Toolox 44 and Anviloy cores

  22. Rapid Tooling Method 1 Direct Metal Deposition of H13 on Copper - the POM Method *-Courtesy POM

  23. Die Cast Part for Evaluation of Improved Cores The core is surrounded by molten aluminum therefore overheats and solders. Extracting heat more efficiently from the core can lower temperature, prevent soldering and allow shorter cycle times.

  24. H13 Deposited on Cu – ready for machining

  25. H13/ Copper Core after 250 cycles The core creeps due to insufficient stiffness and strength at high temperature.

  26. Remedial Approaches Caves in The distortion of the core seems to originate from insufficient strength and stiffness at the operating temperature. Anviloy and H13 cores do not suffer from this problem. Bulges out Priority 1 - Increase strength: use core as deposited w/o tempering (downside-lower toughness). Priority 2 - Increase thickness of H13 layer(downside- slows down heat transfer). Use computer simulation

  27. Technical Progress • The life of the laser deposited core has been extended to 5,000+ shots. • A computer modeling effort is underway to optimize the thickness of the laser deposited H13 layer. • Other high thermal conductivity die materials (Toolox 44, Anviloy) are being tested. • A current NADCA/NEMAK/GM project is leveraging this effort.

  28. solidification cavity fill 1 cycle Finite Element Model Steel H13 Copper Alloy 300oF constant Temperature variation along outer surface Axi-symmetric analysis model

  29. Temperature and stress field at the end of cavity fill (deformation is enlarged by 100) σVon Mises (Psi) Temperature (oF)

  30. Project Plans • High cooling rates the mechanical properties. Shown is the improvement in Dendrite Arm Spacing (DAS) and respective tensile strength caused by a water cooled core.

  31. Improving Mechanical Properties with High Thermal Conductivity Cores High thermal conductivity, cooled cores in die cast aluminum blocks

  32. H13 Toolox 44 Anviloy 3C CuBe

  33. Project Plans • Continue Utilization of Pre-Hardened Superior Steels to Shorten Lead-Time and Lower Tooling Cost for Control Display Module • A computer modeling effort is underway to optimize the thickness of the laser deposited H13 layer.

  34. Implementation

  35. Conclusions • Use of high conductivity alloys in die components can shorten cycle time significantly. • In the present case, the cycle time dropped from 55 sec. for H13 to 40 sec.(13% ) • The life of a tempered, 40HRC H13/ Copper laser deposited core was 250 cycles. By using the core in the as-deposited condition at 51HRC, life was extended to 5,000+ cycles and going. • The balance between strength and toughness is critical to ensure durability of the core. High strength is required to prevent distortion while high toughness avoids cracking.

  36. Project Metrics

  37. JDMTP Criteria - Summary

  38. DLA - POC: Dean Hutchins (dean.hutchins@dla.mil, 804-279-5033) Laser Deposited and Pre-Hardened Steel Rapid Tooling • Problems: • Standard tooling for metal mold processes requires long lead times • High cycle times in the production of metal mold castings • Objective: • Evaluate advanced cooling techniques and rapid tooling techniques to reduce lead times • Benefits: • Demonstrate increased productivity by utilizing rapid tooling techniques and improve properties by incorporating high thermal conductivity die materials • Partners: • Case Western Reserve, Twin City Die Casting, POM, DCD, NADCA, St. Clair Die Casting, Genral Die Casting, Empire Die Casting • Milestones / Deliverables • Evaluation of toughness and thermal fatigue of dies with deposited materials • Optimization of laser deposited H13 layer • Transition Plan • The optimized laser deposited cores will be evaluated in production

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