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Alpha Magnetic Spectrometer - 02

Alpha Magnetic Spectrometer - 02. Flight Safety Review Phase II May 21 - 25, 2007 Analysis - Welding and Brazing Dan Rybicki – Materials Analysis Jacobs – ESCG (281) 244-5181. AMS-02 Welding & Brazing Requirements. Major Systems Super-Fluid Helium Tank Vacuum Case

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Alpha Magnetic Spectrometer - 02

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  1. Alpha Magnetic Spectrometer - 02 Flight Safety Review Phase II May 21 - 25, 2007 Analysis - Welding and Brazing Dan Rybicki – Materials Analysis Jacobs – ESCG (281) 244-5181

  2. AMS-02 Welding & Brazing Requirements • Major Systems • Super-Fluid Helium Tank • Vacuum Case • Integral Plumbing Tubing and Fittings

  3. Welding and brazing governed by NASA, Military, or industry standards: • NASA-STD-5006 (Top level - Flight Hardware) • MSFC-SPEC-504 (Fusion Welding - Aluminum) • MSFC-SPEC-560 (Fusion Welding - Steels) • MIL-STD-2219 (Fusion Welding) • ANSI/AWS C3.x (Brazing Specifications)

  4. To assure mission safety, all welding and brazing procedures and personnel qualifications and certifications were required from the fabricators for review by ESCG prior to commencement of operations on flight hardware • Weld qualification plans were reviewed and approved by NASA’s fracture control engineering personnel (ES4)

  5. At the earliest stages of the program, NASA and ESCG materials engineering and fracture control personnel contributed to the design effort of welded and brazed hardware to ensure: • acceptable (high weldability) materials were selected • designs were optimized for weld and braze-ability • all applicable requirements were understood and applied to the design.

  6. Super-Fluid Helium Tank

  7. Super-Fluid Helium Tank

  8. Super-Fluid Helium Tank • 5083 aluminum alloy • 5183 Aluminum filler alloy • Gas Tungsten Arc Welding (GTAW) • All pressure retaining welds are full penetration • 95% of welds (including most rework and repair areas) made using automated equipment • Manual welding was used for areas where the machine weld head could not physically gain access or where rework/repair areas were short in length • Where deemed necessary, weld joints utilized thickened weld seam cross sections to compensate for “knockdown” of as-welded properties of base material and/or to assist in fitup • Weld joint designs did not prohibit the inspectability of the welds by standard NDE techniques (visual, penetrant and radiographic inspection) • Although difficult to radiograph, the final closure welds were accepted by utilizing multiple and repeated radiographic shots and ‘zone specific’ engineering stress and fracture analysis • No welding performed on vessel after final acceptance tests • FINAL ACCEPTANCE TESTS: • Proof pressure at 3.3 bar • Leak rate at 3.3 bar differential pressure was 8.7 x 10E-10 mbar L/sec

  9. Super-Fluid Helium Tank Example of weld uniformity from automated process (Pre-production weld trial of closure weld)

  10. Super-Fluid Helium Tank Example of weld uniformity from fully automated (robotic) process

  11. Super-Fluid Helium Tank Example of weld uniformity from automated process

  12. Super-Fluid Helium Tank Example of weld quality from manually applied process

  13. Super-Fluid Helium Tank

  14. Super-Fluid Helium Tank

  15. Vacuum Case (VC)

  16. Vacuum Case (VC) • 2219 aluminum alloy • 2319 filler alloy • Two (2) identical circumferential welds at opposing ends of inner cylinder • Final Closure welds • Full penetration butt joint design utilizes integral backing. This feature provides: • precise control of joint fitup • ability to “contain” the internal weld bead penetration to ensure the cold mass “keep in” zone is not breached, • latitude for weld rework (2X) without loss of the conical flanges

  17. Vacuum Case (VC)

  18. Vacuum Case (VC)

  19. Vacuum Case • Gas Tungsten Arc Welding (GTAW) • Welding accomplished with automated equipment • Flat position weld • Welding head fixed and VC rotates about bore axis • Weld reinforcement removed flush to surface of inner cylinder (specified finished condition) • Manual welding techniques were developed to support potential welding rework/repair on-site at vendor facility. • 3 pass weld (1st pass acted as tacking or ‘seal’ pass) • Joints were 100% inspectable by surface and 100% volumetric sub-surface NDE techniques • Fluorescent Penetrant Testing (PT) and specialized Ultrasonic Testing (UT) techniques developed by NASA/ESCG • Phased Array Ultrasonic Testing (PAUT) specified for final production weld inspection • No repairs required on STA weld

  20. Vacuum Case Production welding STA Pre-production weld trial in STA bore

  21. Vacuum Case Production welding STA

  22. Vacuum Case 34 ksi achieved from ESCG design conceptdevelopment effort (non pulsed current) Minimum penetration depth requirement 37 ksi achieved on-site at SCL by ESCG sub-contractor (pulsed current) 0.259” IC wall thkns (min penetration)

  23. Vacuum Case • Welding and inspection procedures and techniques developed by NASA/ESCG in Houston included: • establishing as-welded mechanical properties (with and w/o weld reinforcement) from which a weld design allowable value was specified • part specific acceptance criteria for UT inspection • To ensure highest probability of success, transfer of process technology and all procedures to subcontractor was accomplished via close collaboration of ESCG and subcontractor personnel • Vendor final on-site (SCL) pre-production STA weld qualification achieved 37.3 ksi • Minimum data point seen was 35.2 ksi • AMS02 minimum established allowable = 32.0 ksi • Visual inspection prior to shaving weld bead flush • 100% PT inspected after shaving weld bead flush • 100% UT using Phased Array Ultrasonic Testing • FINAL ACCEPTANCE: • Vacuum leak test • Proof pressure and leak test

  24. Integral Plumbing Tubing & Fittings • TRD gas, thermal control, cryogenic fluid, and warm Helium gas systems • 300 series “L” grade CRES, pure copper, and 1xxx, 5xxx and 6xxx aluminum alloys • Dissimilar metal weld joints • Explosion welding was the selected process for joining (aluminum to CRES alloys) • Some components were brazed due to fabrication and/or installation constraints • Tubular weld joint were welded using fully automatic Orbital Tube Gas Tungsten Arc Welding techniques (OT-GTAW) • In at least one case, LASER welding was utilized to weld adaptors onto small diameter tubing to facilitate final closure welds using OT-GTAW • Weld joint designs did not prohibit the inspectability of the welds by standard NDE techniques (visual, penetrant and/or radiographic inspection) • Proof pressure and leak testing at system level

  25. Integral Plumbing Tubing & Fittings Example of TTCS LASER Weld Quality Example of TTCS OTGTAW Closure Weld Quality

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