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Cryocoolers 12

  • Ronald G. RossJr.
Book

Table of contents

  1. Front Matter
    Pages i-xviii
    PDF

  2. Government Cryocooler Development Programs

    1. NASA Space Cryocooler Programs—An Overview
      R. G. Ross Jr., R. F. Boyle
      Pages 1-8
    2. Air Force Research Laboratory Space Cryogenic Technology Research Initiatives
      B. J. Tomlinson, B. Flake, T. Roberts
      Pages 9-16
    3. Status Report on the Linear Drive Coolers for the Department of Defense Standard Advanced Dewar Assembly (SADA)
      W. E. Salazar
      Pages 17-25

  3. Space Stirling Cryocooler Developments

    1. Development of a Low-Power Stirling Cycle Cryocooler for Space Applications
      J. S. Reed, G. D. Peskett
      Pages 27-30
    2. High Capacity Flexure Bearing Stirling Cryocooler On-Board the ISS
      T. Trollier, A. Ravex, P. Crespi, J. Mullié, P. Bruins, T. Benschop
      Pages 31-35
    3. Space Flight Qualification Program for the AMS-02 Commercial Cryocoolers
      K. A. Shirey, I. S. Banks, S. R. Breon, R. F. Boyle
      Pages 37-44
    4. Thermodynamic Performance of the Ball Aerospace Multistage Stirling Cycle Mechanical Cooler
      W. J. Gully, D. Glaister, E. Marquardt, R. Stack, G. P. Wright
      Pages 45-50
    5. Performance Characterization of the Ball Aerospace 35/60K Protoflight Spacecraft Cryocooler
      C. H. Y. Bruninghaus, B. J. Tomlinson, N. Abhyankar
      Pages 51-58
    6. Continued Characterization Results for the Astrium 10K Developmental Cryocooler
      S. A. Yarbrough, B. A. Flake, B. J. Tomlinson, N. Abhyankar
      Pages 59-67

  4. Tactical and Commercial Stirling Cryocoolers

    1. Technology Development Related to Tactical Cryocoolers at Raytheon Infrared Operations
      B. A. Ross, M. L. Brest, F. I. Mirbod
      Pages 69-74
    2. Performance and Reliability Data for a Production Free Piston Stirling Cryocooler
      M. Hanes, A. O’baid
      Pages 75-78
    3. CMCEC Life Test Results and Related Issues
      S.W.K. Yuan, D.T. Kuo, T.D. Lody
      Pages 79-85
    4. MTTF Prediction in Design Phase on Thales Cryogenics Integral Coolers
      J. M. Cauquil, J. Y. Martin, P. Bruins, T. Benschop
      Pages 87-94
    5. An Experimental Study of the Phase Shift between Piston and Displacer in a Stirling Cryocooler
      S.J. Park, Y.J. Hong, H.B. Kim, D.Y. Koh, B.K. Yu, K.B. Lee
      Pages 95-101
    6. Dynamic Analysis of a Free Piston Stirling Refrigerator
      Y-J. Hong, S-J. Park, H-B. Kim, D-Y. Koh
      Pages 103-108

  5. Tactical and Commercial Pulse Tube Cryocoolers

    1. Low Vibration 80 K Pulse Tube Cooler with Flexure Bearing Compressor
      P.C. Bruins, A. de Koning, T. Hofman
      Pages 109-114
    2. Development of 40–80K Linear-Compressor Driven Pulse Tube Cryocoolers
      J. Liang, J.H. Cai, Y. Zhou, W.X. Zhu, L.W. Yan, W. Jing et al.
      Pages 115-121
    3. Performance and System Design of 60K Pulse Tube Coolers Driven by a Linear Compressor for HTS Filter Subsystems
      Y.L. Ju, K. Yuan, Y.K. Hou, W. Jing, J.T. Liang, Y. Zhou
      Pages 123-129
    4. High Capacity Pulse Tube Cryocooler
      I. Charles, J. M. Duvaland, L. Duband, T. Trollier, A. Ravex, J. Y. Martin
      Pages 131-138
    5. Development of Single and Two-Stage Pulse Tube Cryocoolers with Commercial Linear Compressors
      K. B. Wilson, D. R. Gedeon
      Pages 139-147
    6. Development of a 5 W at 80 K Stirling-Type Pulse Tube Cryocooler
      L. W. Yang, N. Rolff, G. Thummes, H.U. Häfner
      Pages 149-155
    7. Design and Test of a 70 K Pulse Tube Cryocooler
      Y. Yasukawa, K. Ohshima, K. Toyama, T. Itoyama, Y. Tsukahara, R. Kikuchi et al.
      Pages 157-164

  6. Space Pulse Tube Cryocooler Developments

    1. Miniature 50 to 80 K Pulse Tube Cooler for Space Applications
      T. Trollier, A. Ravex, I. Charles, L. Duband, J. Mullié, P. Bruins et al.
      Pages 165-171
    2. Design and Characterization of a Miniature Pulse Tube Cooler
      A.S. Gibson, R. Hunt, I. Charles, L. Duband, M. Crook, A.H. Orlowska et al.
      Pages 173-182
    3. Low Cost, Lightweight Space Cryocoolers
      C. S. Kirkconnell, G. R. Pruitt, K. D. Price, B. A. Ross Jr., W. R. Derossett
      Pages 183-190
    4. JAMI Flight Pulse Tube Cooler System
      J. Raab, R. Colbert, J. Godden, D. Harvey, R. Orsini, G. Toma
      Pages 191-197
    5. Performance Testing of a Lightweight, High Efficiency Cooler
      Salerno L. J, Kittel P, Helvensteijn B. P. M, Kashani A
      Pages 199-204
    6. Development of a Lightweight Pulse Tube Cryocooler for Space Applications
      T. Nast, J. Olson, P. Champagne, B. Evtimov, Todd Renna, G. Sarri et al.
      Pages 205-212
    7. Development of a Two-Stage Pulse Tube Cryocooler for 35 K Cooling
      T. C. Nast, J. Olson, B. Evtimov, V. Kotsubo
      Pages 213-218
    8. High Capacity Two-Stage Pulse Tube Cooler
      C.K. Chan, T. Nguyen, C. Jaco, B. J. Tomlinson, T. Davis
      Pages 219-224
    9. Development of a High Capacity Two-Stage Pulse Tube Cryocooler
      W.G. Foster, J. Olson, P. Champagne, B. Evtimov, E. Will, A. Collaco et al.
      Pages 225-232
    10. Two Stage Hybrid Cryocooler Development
      K.D. Price, C.S. Kirkconnell
      Pages 233-239
    11. Development of a 10 K Pulse Tube Cryocooler for Space Applications
      J. Olson, T. C. Nast, B. Evtimov, E. Roth
      Pages 241-246

  7. Linear Compressor Development and Modeling

    1. Scaling of Cryocooler Compressors
      P.B. Bailey, M.W. Dadd, C.F. Cheuk, N.G. Hill, Jeff Raab
      Pages 247-253
    2. The Linearity of Clearance Seal Suspension Systems
      M.W. Dadd, P.B. Bailey, G. Davey, T. Davis, B. J. Tomlinson
      Pages 255-264
    3. Piston Resonance in the Orifice Pulse Tube
      P.C.T. de Boer, J.-M. Duval, I. Charles, L. Duband
      Pages 265-274
    4. Producibility of Cryocooler Compressors
      C. F. Cheuk, N. G. Hill, R. Strauch, P.B. Bailey, Jeff Raab
      Pages 275-281

  8. GM-Type Pulse Tube Coolers for Low Temperatures

    1. Helium-3 Pulse Tube Cryocooler
      I.A. Tanaeva, A.T.A.M. de Waele
      Pages 283-292
    2. Two-Stage Pulse Tube Cryocoolers for 4 K and 10 K Operation
      C. Wang, P.E. Gifford
      Pages 293-300
    3. Development of a 4K Two-stage Pulse Tube Cryocooler
      M.Y. Xu, P.D. Yan, T. Koyama, T. Ogura, R. Li
      Pages 301-307
    4. Performance of a 4K Pulse Tube Refrigerator And Its Improvement
      S.W. Zhu, M. Nogawa, S. Katsuragawa, M. Ichikawa, T. Inoue
      Pages 309-315
    5. Experimental Investigation of a G-M Type Coaxial Pulse Tube Cryocooler
      K. Yuan, J.T. Liang, Y.L. Ju
      Pages 317-323

  9. Hybrid Cryocoolers Using Pulse Tubes

    1. Experimental Study on Two-stage Pulse Tube Refrigeration with Mixtures of Helium and Hydrogen
      N. Jiang, Z. H. Gan, G. B. Chen, L. M. Qiu, Y. L. Jiang, Y. L. He et al.
      Pages 325-329
    2. Experimental Investigation of 4K VM Type Pulse Tube Cooler
      W. Dai, Y. Matsubara, H. Kobayashi
      Pages 331-336
    3. Affecting the Gross Cooling Power of a Pulse Tube Cryocooler with Mass Flow Control
      A. Waldauf, T. Schmauder, M. Thürk, P. Seidel
      Pages 337-342
    4. Pressure Wave Generator for a Pulse Tube Cooler
      Y. Matsubara, W. Dai, H. Sugita, S. Tooyama
      Pages 343-348
    5. A First Order Model of a Hybrid Pulse Tube/Reverse-Brayton Cryocooler
      G. F. Nellis, J. R. Maddocks, A. Kashani, J. H. Baik, J. M. Pfotenhauer
      Pages 349-359

  10. Pulse Tube Analyses and Experimental Measurements

    1. The Role of the Orifice and the Secondary Bypass in a Miniature Pulse Tube Cryocooler
      Y.K. Hou, Y.L. Ju, W. Jing, J.T. Liang
      Pages 361-369
    2. Surface Heat Pumping Loss in a Pulse Tube Refrigerator
      J. Jung, S. Jeong
      Pages 371-378

About this book

Introduction

The last two years have witnessed a continuation in the breakthrough shift toward pulse tube cryocoolers for long-life, high-reliability cryocooler applications. One class of pulse tubes that has reached maturity is referred to as “Stirling type” because they are based on the linear Oxford Stirling-cooler type compressor; these generally provide cooling in the 30 to 100 K temperature range and operate at frequencies from 30 to 60 Hz. The other type of pulse tube cooler making great advances is the so-called “Gifford-McMahon type. ” Pulse tube coolers of this type use a G-M type compressor and lower frequency operation to achieve temperatures in the 2 to 10 K temperature range. Nearly a third of this proceedings covers these new developments in the pulse tube arena. Complementing the work on low-temperature pulse tubes is substantial continued progress on rare earth regenerator materials and Gifford-McMahon coolers. These technologies continue to make great progress in opening up the 2 - 4 K market. Also in the commercial sector, continued interest is being shown in the development of long-life, low-cost cryocoolers for the emerging high temperature superconductor electronics market, particularly the cellular telephone base-station market. At higher temperature levels, closed-cycle J-T or throttle-cycle refrigerators are taking advantage of mixed refrigerant gases to achieve low-cost cryocooler systems in the 65 to 80 K temperature range.

Keywords

design development modeling semiconductor space

Editors and affiliations

  • Ronald G. RossJr.
    • 1
  1. 1.Jet Propulsion LaboratoryCalifornia Institute of TechnologyPasadena

Bibliographic information

  • DOI https://doi.org/10.1007/b100535
  • Copyright Information Springer Science+Business Media New York 2003
  • Publisher Name Springer, Boston, MA
  • eBook Packages Springer Book Archive
  • Print ISBN 978-0-306-47714-0
  • Online ISBN 978-0-306-47919-9
  • Buy this book on publisher's site