Counterflow Heat Transfer in He II Contained in Porous Media

This dissertation presents a study of steady He II (superfluid helium) counter flow heat transfer in porous media. Porous insulation were suggested as potential alternatives to conventional fully impregnated insulations in superconducting magnet technology. Superconducting magnets are usually cooled...

Full description

Bibliographic Details
Other Authors: Dalban-Canassy, Matthieu (authoraut)
Format: Others
Language:English
English
Published: Florida State University
Subjects:
Online Access:http://purl.flvc.org/fsu/fd/FSU_migr_etd-0855
id ndltd-fsu.edu-oai-fsu.digital.flvc.org-fsu_169036
record_format oai_dc
collection NDLTD
language English
English
format Others
sources NDLTD
topic Philosophy
spellingShingle Philosophy
Counterflow Heat Transfer in He II Contained in Porous Media
description This dissertation presents a study of steady He II (superfluid helium) counter flow heat transfer in porous media. Porous insulation were suggested as potential alternatives to conventional fully impregnated insulations in superconducting magnet technology. Superconducting magnets are usually cooled with He II. Use of porous insulation requires thus a good knowledge of the behavior of He II within porous materials, when set in motion or exposed to a heat source. The present work was focused on the design of an apparatus capable of performing both steady and transient counterflow measurements in He II saturating a porous material with a geometry similar to potential candidate porous insulations. Those will most likely be composed of tapes of pre-impregnated woven ceramic fibers, forming a highly anisotropic compound, with a wide pore size distribution. The samples were provided by Composite Technology Development Inc. and are circular pellets (3.08 mm thick and 28.58 mm in diameter) of 20 compressed layers of pre-impregnated woven magnet insulation. The porous material was carefully characterized prior to experimental runs in He II. The samples exhibit a porosity and a permeability of respectively 20+-1% and 0.95x10^-14 m^2 for water measurements. The woven fiber rovings, composing the insulation, were found to be 0.04 mm^2 of average cross sectional area with fibers of average diameter of 10.6 micron. The He II experimental apparatus is composed of a vacuum insulated open channel whose top extremity is closed to a Minco heater. The temperature differences and pressure drops across the porous plug were measured by two Lakeshore barechip Cernox 1050BC thermometers and a Validyne DP10-20 differential pressure sensor. Applied heat fluxes ranged up to 0.5 kW/m^2 of sample cross section. Steady temperature differences, up to 570 mK, and pressure drops, up to 1800 Pa (limit of the sensor), measurements were performed at bath temperatures ranging from 1.6 to 2.1 K. In the low heat flux regime, the permeability data corroborate room temperature measurements. In the high heat flux regime however, we show evidence of the failure of previous models based on the inclusion of the tortuosity in the turbulent equation. We propose to include a constriction factor denoting an average maximum change in cross section in the heat path in addition to the increased path length denoted by the tortuosity. In the turbulent regime, this constriction factor is predominant as it enters in the model with a cubic power. Measurements of the critical characteristics, corresponding to the point of transition from the laminar regime, where Darcy law is applicable to the non-linear regime, where the heat flux adopts its characteristic cubic relationship, corresponding to the appearance of turbulence within He II are also reported. We obtained critical heat fluxes ranging from 20 to 70 W/m^2, Reynolds numbers of 0.5 to 4 and normal fluid velocities from 0.5 to 2.5 mm/s, varying with bath temperature. To confirm the room temperature measurements of permeability, we also conducted a forced flow experiment. Unfortunately, the flow range covered is outside of the laminar regime and does not permit an accurate estimation of the permeability. The results are however favorably comparable to earlier data recorded in the turbulent regime in similar flow conditions but with very different materials. === A Dissertation submitted to the Department of Mechanical Engineering in partial fulfllment of the requirements for the degree of Doctor of Philosophy. === Degree Awarded: Spring Semester, 2010. === Date of Defense: November 12, 2009. === Cryogenics, Heat Transfer, Magnet Insulation, Porous Media, Counterflow, Superfluid Helium === Includes bibliographical references. === Steven W. Van Sciver, Professor Directing Dissertation; Janet Peterson, University Representative; Cesar Luongo, Committee Member; Juan Ordonez, Committee Member; Ongi Englander, Committee Member.
author2 Dalban-Canassy, Matthieu (authoraut)
author_facet Dalban-Canassy, Matthieu (authoraut)
title Counterflow Heat Transfer in He II Contained in Porous Media
title_short Counterflow Heat Transfer in He II Contained in Porous Media
title_full Counterflow Heat Transfer in He II Contained in Porous Media
title_fullStr Counterflow Heat Transfer in He II Contained in Porous Media
title_full_unstemmed Counterflow Heat Transfer in He II Contained in Porous Media
title_sort counterflow heat transfer in he ii contained in porous media
publisher Florida State University
url http://purl.flvc.org/fsu/fd/FSU_migr_etd-0855
_version_ 1719217760364396544
spelling ndltd-fsu.edu-oai-fsu.digital.flvc.org-fsu_1690362019-07-01T05:12:44Z Counterflow Heat Transfer in He II Contained in Porous Media Dalban-Canassy, Matthieu (authoraut) Sciver, Steven W. Van (professor directing dissertation) Peterson, Janet (university representative) Luongo, Cesar (committee member) Ordonez, Juan (committee member) Englander, Ongi (committee member) Department of Mechanical Engineering (degree granting department) Florida State University (degree granting institution) Text text Florida State University English eng 1 online resource computer application/pdf This dissertation presents a study of steady He II (superfluid helium) counter flow heat transfer in porous media. Porous insulation were suggested as potential alternatives to conventional fully impregnated insulations in superconducting magnet technology. Superconducting magnets are usually cooled with He II. Use of porous insulation requires thus a good knowledge of the behavior of He II within porous materials, when set in motion or exposed to a heat source. The present work was focused on the design of an apparatus capable of performing both steady and transient counterflow measurements in He II saturating a porous material with a geometry similar to potential candidate porous insulations. Those will most likely be composed of tapes of pre-impregnated woven ceramic fibers, forming a highly anisotropic compound, with a wide pore size distribution. The samples were provided by Composite Technology Development Inc. and are circular pellets (3.08 mm thick and 28.58 mm in diameter) of 20 compressed layers of pre-impregnated woven magnet insulation. The porous material was carefully characterized prior to experimental runs in He II. The samples exhibit a porosity and a permeability of respectively 20+-1% and 0.95x10^-14 m^2 for water measurements. The woven fiber rovings, composing the insulation, were found to be 0.04 mm^2 of average cross sectional area with fibers of average diameter of 10.6 micron. The He II experimental apparatus is composed of a vacuum insulated open channel whose top extremity is closed to a Minco heater. The temperature differences and pressure drops across the porous plug were measured by two Lakeshore barechip Cernox 1050BC thermometers and a Validyne DP10-20 differential pressure sensor. Applied heat fluxes ranged up to 0.5 kW/m^2 of sample cross section. Steady temperature differences, up to 570 mK, and pressure drops, up to 1800 Pa (limit of the sensor), measurements were performed at bath temperatures ranging from 1.6 to 2.1 K. In the low heat flux regime, the permeability data corroborate room temperature measurements. In the high heat flux regime however, we show evidence of the failure of previous models based on the inclusion of the tortuosity in the turbulent equation. We propose to include a constriction factor denoting an average maximum change in cross section in the heat path in addition to the increased path length denoted by the tortuosity. In the turbulent regime, this constriction factor is predominant as it enters in the model with a cubic power. Measurements of the critical characteristics, corresponding to the point of transition from the laminar regime, where Darcy law is applicable to the non-linear regime, where the heat flux adopts its characteristic cubic relationship, corresponding to the appearance of turbulence within He II are also reported. We obtained critical heat fluxes ranging from 20 to 70 W/m^2, Reynolds numbers of 0.5 to 4 and normal fluid velocities from 0.5 to 2.5 mm/s, varying with bath temperature. To confirm the room temperature measurements of permeability, we also conducted a forced flow experiment. Unfortunately, the flow range covered is outside of the laminar regime and does not permit an accurate estimation of the permeability. The results are however favorably comparable to earlier data recorded in the turbulent regime in similar flow conditions but with very different materials. A Dissertation submitted to the Department of Mechanical Engineering in partial fulfllment of the requirements for the degree of Doctor of Philosophy. Degree Awarded: Spring Semester, 2010. Date of Defense: November 12, 2009. Cryogenics, Heat Transfer, Magnet Insulation, Porous Media, Counterflow, Superfluid Helium Includes bibliographical references. Steven W. Van Sciver, Professor Directing Dissertation; Janet Peterson, University Representative; Cesar Luongo, Committee Member; Juan Ordonez, Committee Member; Ongi Englander, Committee Member. Philosophy FSU_migr_etd-0855 http://purl.flvc.org/fsu/fd/FSU_migr_etd-0855 http://diginole.lib.fsu.edu/islandora/object/fsu%3A169036/datastream/TN/view/Counterflow%20Heat%20Transfer%20in%20He%20II%20Contained%20in%20Porous%20Media.jpg