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Dimensionless Scaling and Prediction of Vortex Tube Temperature Separation
Ranque–Hilsch vortex tubes split an incoming fluid stream into two outgoing streams: one with a higher total temperature than the incoming fluid and the other with a lower total temperature. This 90-year-old device accomplishes its temperature separation with no moving parts and no external power so...
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| Published in: | Journal of thermophysics and heat transfer 2022-10, Vol.36 (4), p.930-939 |
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| Main Authors: | , |
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| cites | cdi_FETCH-LOGICAL-a212t-27d4c6aa52e5571c050e3777640da6dc1b224596e776a7c11b8b46d17ef345ff3 |
| container_end_page | 939 |
| container_issue | 4 |
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| container_title | Journal of thermophysics and heat transfer |
| container_volume | 36 |
| creator | Fuqua, Matthew N. Rutledge, James L. |
| description | Ranque–Hilsch vortex tubes split an incoming fluid stream into two outgoing streams: one with a higher total temperature than the incoming fluid and the other with a lower total temperature. This 90-year-old device accomplishes its temperature separation with no moving parts and no external power sources, and despite a diversity of extant theories regarding the underlying mechanism, it is clear that a rapidly swirling flow inside the tube is key to its operation. While many parametric studies have characterized the degree of temperature separation as a function of a host of variables (e.g., inlet pressure, inlet temperature, working gas, tube geometry), no previous effort has identified the governing nondimensional parameters that would simplify further characterization. In the present work, we nondimensionalize the energy equation as it applies to Ranque–Hilsch vortex tubes and identify the governing nondimensional parameters and nondimensional dependent variables. The governing nondimensional parameters are shown to be the Reynolds number, the Péclet number, and a lesser-known nondimensionalization of the Joule–Thomson coefficient, ρ0Cp,0μJT,0. To discern the dependence of temperature separation on these nondimensional parameters, experimental data were analyzed. We show that a unique dimensionless form of the product of the total temperature, density, and specific heat collapses across a wide range of the aforementioned governing nondimensional parameters, although some dependence remains evident, particularly in the case of ρ0Cp,0μJT,0, for which an extremely wide range of values were obtained through comparison of carbon dioxide with air. A method is demonstrated to predict temperature separation for new cooling scenarios, reducing the experimental burden for new applications. |
| doi_str_mv | 10.2514/1.T6432 |
| format | article |
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This 90-year-old device accomplishes its temperature separation with no moving parts and no external power sources, and despite a diversity of extant theories regarding the underlying mechanism, it is clear that a rapidly swirling flow inside the tube is key to its operation. While many parametric studies have characterized the degree of temperature separation as a function of a host of variables (e.g., inlet pressure, inlet temperature, working gas, tube geometry), no previous effort has identified the governing nondimensional parameters that would simplify further characterization. In the present work, we nondimensionalize the energy equation as it applies to Ranque–Hilsch vortex tubes and identify the governing nondimensional parameters and nondimensional dependent variables. The governing nondimensional parameters are shown to be the Reynolds number, the Péclet number, and a lesser-known nondimensionalization of the Joule–Thomson coefficient, ρ0Cp,0μJT,0. To discern the dependence of temperature separation on these nondimensional parameters, experimental data were analyzed. We show that a unique dimensionless form of the product of the total temperature, density, and specific heat collapses across a wide range of the aforementioned governing nondimensional parameters, although some dependence remains evident, particularly in the case of ρ0Cp,0μJT,0, for which an extremely wide range of values were obtained through comparison of carbon dioxide with air. A method is demonstrated to predict temperature separation for new cooling scenarios, reducing the experimental burden for new applications.</description><identifier>ISSN: 1533-6808</identifier><identifier>ISSN: 0887-8722</identifier><identifier>EISSN: 1533-6808</identifier><identifier>DOI: 10.2514/1.T6432</identifier><language>eng</language><publisher>Reston: American Institute of Aeronautics and Astronautics</publisher><subject>Carbon dioxide ; Dependent variables ; Fluid flow ; Inlet pressure ; Inlet temperature ; Mathematical analysis ; Parameter identification ; Power sources ; Reynolds number ; Separation ; Swirling ; Temperature dependence ; Thomson coefficient ; Tubes ; Vortices</subject><ispartof>Journal of thermophysics and heat transfer, 2022-10, Vol.36 (4), p.930-939</ispartof><rights>This material is declared a work of the U.S. Government and is not subject to copyright protection in the United States. All requests for copying and permission to reprint should be submitted to CCC at ; employ the eISSN to initiate your request. See also AIAA Rights and Permissions .</rights><rights>This material is declared a work of the U.S. Government and is not subject to copyright protection in the United States. All requests for copying and permission to reprint should be submitted to CCC at www.copyright.com; employ the eISSN 1533-6808 to initiate your request. See also AIAA Rights and Permissions www.aiaa.org/randp.</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-a212t-27d4c6aa52e5571c050e3777640da6dc1b224596e776a7c11b8b46d17ef345ff3</citedby><cites>FETCH-LOGICAL-a212t-27d4c6aa52e5571c050e3777640da6dc1b224596e776a7c11b8b46d17ef345ff3</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27924,27925</link.rule.ids></links><search><creatorcontrib>Fuqua, Matthew N.</creatorcontrib><creatorcontrib>Rutledge, James L.</creatorcontrib><title>Dimensionless Scaling and Prediction of Vortex Tube Temperature Separation</title><title>Journal of thermophysics and heat transfer</title><description>Ranque–Hilsch vortex tubes split an incoming fluid stream into two outgoing streams: one with a higher total temperature than the incoming fluid and the other with a lower total temperature. This 90-year-old device accomplishes its temperature separation with no moving parts and no external power sources, and despite a diversity of extant theories regarding the underlying mechanism, it is clear that a rapidly swirling flow inside the tube is key to its operation. While many parametric studies have characterized the degree of temperature separation as a function of a host of variables (e.g., inlet pressure, inlet temperature, working gas, tube geometry), no previous effort has identified the governing nondimensional parameters that would simplify further characterization. In the present work, we nondimensionalize the energy equation as it applies to Ranque–Hilsch vortex tubes and identify the governing nondimensional parameters and nondimensional dependent variables. The governing nondimensional parameters are shown to be the Reynolds number, the Péclet number, and a lesser-known nondimensionalization of the Joule–Thomson coefficient, ρ0Cp,0μJT,0. To discern the dependence of temperature separation on these nondimensional parameters, experimental data were analyzed. We show that a unique dimensionless form of the product of the total temperature, density, and specific heat collapses across a wide range of the aforementioned governing nondimensional parameters, although some dependence remains evident, particularly in the case of ρ0Cp,0μJT,0, for which an extremely wide range of values were obtained through comparison of carbon dioxide with air. A method is demonstrated to predict temperature separation for new cooling scenarios, reducing the experimental burden for new applications.</description><subject>Carbon dioxide</subject><subject>Dependent variables</subject><subject>Fluid flow</subject><subject>Inlet pressure</subject><subject>Inlet temperature</subject><subject>Mathematical analysis</subject><subject>Parameter identification</subject><subject>Power sources</subject><subject>Reynolds number</subject><subject>Separation</subject><subject>Swirling</subject><subject>Temperature dependence</subject><subject>Thomson coefficient</subject><subject>Tubes</subject><subject>Vortices</subject><issn>1533-6808</issn><issn>0887-8722</issn><issn>1533-6808</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><recordid>eNpdkFtLxDAUhIMouK7iXwgo-NQ1J9fuo3iXBYWtvoY0PZUuu21NWtB_b3QFxacZ5nzMgSHkGNiMK5DnMCu0FHyHTEAJkemc5bt__D45iHHFGOjcwIQ8XDUbbGPTtWuMkS69WzftK3VtRZ8CVo0f0ol2NX3pwoDvtBhLpAVuegxuGAPSJfYu2UQdkr3arSMe_eiUPN9cF5d32eLx9v7yYpE5DnzIuKmk184pjkoZ8EwxFMYYLVnldOWh5FyqucYUOeMByryUugKDtZCqrsWUnGx7-9C9jRgHu-rG0KaXlhsulJ4rCYk621I-dDEGrG0fmo0LHxaY_RrKgv0eKpGnW9I1zv12_cc-AbbpZO0</recordid><startdate>202210</startdate><enddate>202210</enddate><creator>Fuqua, Matthew N.</creator><creator>Rutledge, James L.</creator><general>American Institute of Aeronautics and Astronautics</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TB</scope><scope>8FD</scope><scope>FR3</scope><scope>H8D</scope><scope>KR7</scope><scope>L7M</scope></search><sort><creationdate>202210</creationdate><title>Dimensionless Scaling and Prediction of Vortex Tube Temperature Separation</title><author>Fuqua, Matthew N. ; Rutledge, James L.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a212t-27d4c6aa52e5571c050e3777640da6dc1b224596e776a7c11b8b46d17ef345ff3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2022</creationdate><topic>Carbon dioxide</topic><topic>Dependent variables</topic><topic>Fluid flow</topic><topic>Inlet pressure</topic><topic>Inlet temperature</topic><topic>Mathematical analysis</topic><topic>Parameter identification</topic><topic>Power sources</topic><topic>Reynolds number</topic><topic>Separation</topic><topic>Swirling</topic><topic>Temperature dependence</topic><topic>Thomson coefficient</topic><topic>Tubes</topic><topic>Vortices</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Fuqua, Matthew N.</creatorcontrib><creatorcontrib>Rutledge, James L.</creatorcontrib><collection>CrossRef</collection><collection>Mechanical & Transportation Engineering Abstracts</collection><collection>Technology Research Database</collection><collection>Engineering Research Database</collection><collection>Aerospace Database</collection><collection>Civil Engineering Abstracts</collection><collection>Advanced Technologies Database with Aerospace</collection><jtitle>Journal of thermophysics and heat transfer</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Fuqua, Matthew N.</au><au>Rutledge, James L.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Dimensionless Scaling and Prediction of Vortex Tube Temperature Separation</atitle><jtitle>Journal of thermophysics and heat transfer</jtitle><date>2022-10</date><risdate>2022</risdate><volume>36</volume><issue>4</issue><spage>930</spage><epage>939</epage><pages>930-939</pages><issn>1533-6808</issn><issn>0887-8722</issn><eissn>1533-6808</eissn><abstract>Ranque–Hilsch vortex tubes split an incoming fluid stream into two outgoing streams: one with a higher total temperature than the incoming fluid and the other with a lower total temperature. This 90-year-old device accomplishes its temperature separation with no moving parts and no external power sources, and despite a diversity of extant theories regarding the underlying mechanism, it is clear that a rapidly swirling flow inside the tube is key to its operation. While many parametric studies have characterized the degree of temperature separation as a function of a host of variables (e.g., inlet pressure, inlet temperature, working gas, tube geometry), no previous effort has identified the governing nondimensional parameters that would simplify further characterization. In the present work, we nondimensionalize the energy equation as it applies to Ranque–Hilsch vortex tubes and identify the governing nondimensional parameters and nondimensional dependent variables. The governing nondimensional parameters are shown to be the Reynolds number, the Péclet number, and a lesser-known nondimensionalization of the Joule–Thomson coefficient, ρ0Cp,0μJT,0. To discern the dependence of temperature separation on these nondimensional parameters, experimental data were analyzed. We show that a unique dimensionless form of the product of the total temperature, density, and specific heat collapses across a wide range of the aforementioned governing nondimensional parameters, although some dependence remains evident, particularly in the case of ρ0Cp,0μJT,0, for which an extremely wide range of values were obtained through comparison of carbon dioxide with air. A method is demonstrated to predict temperature separation for new cooling scenarios, reducing the experimental burden for new applications.</abstract><cop>Reston</cop><pub>American Institute of Aeronautics and Astronautics</pub><doi>10.2514/1.T6432</doi><tpages>10</tpages></addata></record> |
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| ispartof | Journal of thermophysics and heat transfer, 2022-10, Vol.36 (4), p.930-939 |
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| source | Alma/SFX Local Collection |
| subjects | Carbon dioxide Dependent variables Fluid flow Inlet pressure Inlet temperature Mathematical analysis Parameter identification Power sources Reynolds number Separation Swirling Temperature dependence Thomson coefficient Tubes Vortices |
| title | Dimensionless Scaling and Prediction of Vortex Tube Temperature Separation |
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