Modelling of a two-phase thermofluidic oscillator for low-grade heat utilisation: Accounting for irreversible thermal losses

► Two models for a novel two-phase thermofluidic oscillator are developed. ► The effect of including a dissipative thermal loss (TL) parameter is investigated. ► The models predict the oscillation frequency of a prototype (0.1–0.2Hz) well. ► Excluding the TL parameter leads to a 30-fold overestimati...

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Veröffentlicht in:	Applied energy 2013-06, Vol.106, p.337-354
Hauptverfasser:	Solanki, Roochi, Mathie, Richard, Galindo, Amparo, Markides, Christos N.
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Schlagworte:	Applied sciences Devices Electrical analogy Energy Exact sciences and technology Heat engine heat exchangers heat transfer Low-grade heat phase transition prediction temperature Thermofluidic oscillator Unsteady thermal loss
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description	► Two models for a novel two-phase thermofluidic oscillator are developed. ► The effect of including a dissipative thermal loss (TL) parameter is investigated. ► The models predict the oscillation frequency of a prototype (0.1–0.2Hz) well. ► Excluding the TL parameter leads to a 30-fold overestimation of the measured efficiency. ► Including the TL parameter allows for a much improved prediction of the efficiency. The Non-Inertive-Feedback Thermofluidic Engine (NIFTE) is a two-phase thermofluidic oscillator which, by means of persistent periodic thermal-fluid oscillations when placed across a steady temperature difference, is capable of utilising low-grade (i.e., low temperature) heat to induce a fluid motion. Two linearised models of the NIFTE are presented in this paper, both containing a description of the phase-change convective heat transfer that takes place between the working fluid and the heat exchangers. The first model (LTP) imposes a steady linear temperature profile along the surface of the heat exchangers; whereas the second model (DHX) allows the solid heat exchanger blocks to store and release heat dynamically as they interact thermally with the working fluid. In earlier work [Solanki R, Galindo A, Markides CN. Appl Therm Eng; [24]] it was found that these models predict the oscillation (i.e., operation) frequency of an existing NIFTE prototype pump well, but significantly overestimate its reported efficiency. Specifically, the LTP and DHX models predicted exergetic efficiencies 11 and 30 times higher than those observed experimentally, respectively. In the present paper, a dissipative thermal loss parameter that can account for the exergetic losses due to the parasitic, cyclic phase change and heat exchange within the device is included in both models in an effort to make realistic predictions of the exergetic efficiencies. The LTP and DHX models, including and excluding the thermal loss parameter, are compared to experimental data. It is found that the inclusion of the thermal loss parameter increases the predicted oscillation frequencies in the DHX model, but has a negligible effect on the frequencies predicted by the LTP model. A more significant effect is observed with respect to the efficiencies, whereby the inclusion of the thermal loss parameter leads to a greatly improved prediction of the exergetic efficiencies of the prototype NIFTE pump by both the LTP and DHX models, both in trend and approximate magnitude. From the results it is
doi_str_mv	10.1016/j.apenergy.2012.12.069
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The Non-Inertive-Feedback Thermofluidic Engine (NIFTE) is a two-phase thermofluidic oscillator which, by means of persistent periodic thermal-fluid oscillations when placed across a steady temperature difference, is capable of utilising low-grade (i.e., low temperature) heat to induce a fluid motion. Two linearised models of the NIFTE are presented in this paper, both containing a description of the phase-change convective heat transfer that takes place between the working fluid and the heat exchangers. The first model (LTP) imposes a steady linear temperature profile along the surface of the heat exchangers; whereas the second model (DHX) allows the solid heat exchanger blocks to store and release heat dynamically as they interact thermally with the working fluid. In earlier work [Solanki R, Galindo A, Markides CN. Appl Therm Eng; [24]] it was found that these models predict the oscillation (i.e., operation) frequency of an existing NIFTE prototype pump well, but significantly overestimate its reported efficiency. Specifically, the LTP and DHX models predicted exergetic efficiencies 11 and 30 times higher than those observed experimentally, respectively. In the present paper, a dissipative thermal loss parameter that can account for the exergetic losses due to the parasitic, cyclic phase change and heat exchange within the device is included in both models in an effort to make realistic predictions of the exergetic efficiencies. The LTP and DHX models, including and excluding the thermal loss parameter, are compared to experimental data. It is found that the inclusion of the thermal loss parameter increases the predicted oscillation frequencies in the DHX model, but has a negligible effect on the frequencies predicted by the LTP model. A more significant effect is observed with respect to the efficiencies, whereby the inclusion of the thermal loss parameter leads to a greatly improved prediction of the exergetic efficiencies of the prototype NIFTE pump by both the LTP and DHX models, both in trend and approximate magnitude. 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The Non-Inertive-Feedback Thermofluidic Engine (NIFTE) is a two-phase thermofluidic oscillator which, by means of persistent periodic thermal-fluid oscillations when placed across a steady temperature difference, is capable of utilising low-grade (i.e., low temperature) heat to induce a fluid motion. Two linearised models of the NIFTE are presented in this paper, both containing a description of the phase-change convective heat transfer that takes place between the working fluid and the heat exchangers. The first model (LTP) imposes a steady linear temperature profile along the surface of the heat exchangers; whereas the second model (DHX) allows the solid heat exchanger blocks to store and release heat dynamically as they interact thermally with the working fluid. In earlier work [Solanki R, Galindo A, Markides CN. Appl Therm Eng; [24]] it was found that these models predict the oscillation (i.e., operation) frequency of an existing NIFTE prototype pump well, but significantly overestimate its reported efficiency. Specifically, the LTP and DHX models predicted exergetic efficiencies 11 and 30 times higher than those observed experimentally, respectively. In the present paper, a dissipative thermal loss parameter that can account for the exergetic losses due to the parasitic, cyclic phase change and heat exchange within the device is included in both models in an effort to make realistic predictions of the exergetic efficiencies. The LTP and DHX models, including and excluding the thermal loss parameter, are compared to experimental data. It is found that the inclusion of the thermal loss parameter increases the predicted oscillation frequencies in the DHX model, but has a negligible effect on the frequencies predicted by the LTP model. A more significant effect is observed with respect to the efficiencies, whereby the inclusion of the thermal loss parameter leads to a greatly improved prediction of the exergetic efficiencies of the prototype NIFTE pump by both the LTP and DHX models, both in trend and approximate magnitude. From the results it is concluded that, on accounting for thermal losses, the DHX model achieves the best predictions of the key performance indicators of the NIFTE, that is, of the oscillation frequency and exergetic efficiency of the device.</description><subject>Applied sciences</subject><subject>Devices</subject><subject>Electrical analogy</subject><subject>Energy</subject><subject>Exact sciences and technology</subject><subject>Heat engine</subject><subject>heat exchangers</subject><subject>heat transfer</subject><subject>Low-grade heat</subject><subject>phase transition</subject><subject>prediction</subject><subject>temperature</subject><subject>Thermofluidic oscillator</subject><subject>Unsteady thermal loss</subject><issn>0306-2619</issn><issn>1872-9118</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2013</creationdate><recordtype>article</recordtype><recordid>eNqFkU1vEzEQhi0EEqHwF8AXJC6b-iP2xpyoqgKVijhAz9bEO04cOetge1tV4sfjVQJX5LF8eeb1-DEhbzlbcsb15X4JRxwxb5-WgnGxbMW0eUYWfN2LznC-fk4WTDLdCc3NS_KqlD1jTHDBFuT3tzRgjGHc0uQp0PqYuuMOCtK6w3xIPk5hCI6m4kKMUFOmvu2YHrtthgHpDqHSqYYYCtSQxo_0yrk0jXWOnNGQMz5gLmETz6EQW38pWF6TFx5iwTfn84Lcf775ef21u_v-5fb66q5z0pjaDcLzlVNgvDeKSblxWmmGEjiHjRwQHazdyg0GhDCoPG9L9koodLpHtpIX5MMp95jTrwlLtYdQXHs2jJimYrliesW4krKh-oS63EbM6O0xhwPkJ8uZnXXbvf2r2866baumuzW-P98BxUH0GUYXyr9u0Qu57hVv3LsT5yFZ2ObG3P9oQbp9CZein4lPJwKbkoeA2Tb3ODocQkZX7ZDC_4b5A5WupfI</recordid><startdate>20130601</startdate><enddate>20130601</enddate><creator>Solanki, Roochi</creator><creator>Mathie, Richard</creator><creator>Galindo, Amparo</creator><creator>Markides, Christos N.</creator><general>Elsevier Ltd</general><general>Elsevier</general><scope>FBQ</scope><scope>IQODW</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7TA</scope><scope>8FD</scope><scope>F28</scope><scope>FR3</scope><scope>JG9</scope></search><sort><creationdate>20130601</creationdate><title>Modelling of a two-phase thermofluidic oscillator for low-grade heat utilisation: Accounting for irreversible thermal losses</title><author>Solanki, Roochi ; Mathie, Richard ; Galindo, Amparo ; Markides, Christos N.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c399t-d2f14c5a9ff95033bc6560e3a11ab3deeca8c4cd9a229e5f1f1f37525ec67e043</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2013</creationdate><topic>Applied sciences</topic><topic>Devices</topic><topic>Electrical analogy</topic><topic>Energy</topic><topic>Exact sciences and technology</topic><topic>Heat engine</topic><topic>heat exchangers</topic><topic>heat transfer</topic><topic>Low-grade heat</topic><topic>phase transition</topic><topic>prediction</topic><topic>temperature</topic><topic>Thermofluidic oscillator</topic><topic>Unsteady thermal loss</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Solanki, Roochi</creatorcontrib><creatorcontrib>Mathie, Richard</creatorcontrib><creatorcontrib>Galindo, Amparo</creatorcontrib><creatorcontrib>Markides, Christos N.</creatorcontrib><collection>AGRIS</collection><collection>Pascal-Francis</collection><collection>CrossRef</collection><collection>Materials Business File</collection><collection>Technology Research Database</collection><collection>ANTE: Abstracts in New Technology & Engineering</collection><collection>Engineering Research Database</collection><collection>Materials Research Database</collection><jtitle>Applied energy</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Solanki, Roochi</au><au>Mathie, Richard</au><au>Galindo, Amparo</au><au>Markides, Christos N.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Modelling of a two-phase thermofluidic oscillator for low-grade heat utilisation: Accounting for irreversible thermal losses</atitle><jtitle>Applied energy</jtitle><date>2013-06-01</date><risdate>2013</risdate><volume>106</volume><spage>337</spage><epage>354</epage><pages>337-354</pages><issn>0306-2619</issn><eissn>1872-9118</eissn><coden>APENDX</coden><abstract>► Two models for a novel two-phase thermofluidic oscillator are developed. ► The effect of including a dissipative thermal loss (TL) parameter is investigated. ► The models predict the oscillation frequency of a prototype (0.1–0.2Hz) well. ► Excluding the TL parameter leads to a 30-fold overestimation of the measured efficiency. ► Including the TL parameter allows for a much improved prediction of the efficiency. The Non-Inertive-Feedback Thermofluidic Engine (NIFTE) is a two-phase thermofluidic oscillator which, by means of persistent periodic thermal-fluid oscillations when placed across a steady temperature difference, is capable of utilising low-grade (i.e., low temperature) heat to induce a fluid motion. Two linearised models of the NIFTE are presented in this paper, both containing a description of the phase-change convective heat transfer that takes place between the working fluid and the heat exchangers. The first model (LTP) imposes a steady linear temperature profile along the surface of the heat exchangers; whereas the second model (DHX) allows the solid heat exchanger blocks to store and release heat dynamically as they interact thermally with the working fluid. In earlier work [Solanki R, Galindo A, Markides CN. Appl Therm Eng; [24]] it was found that these models predict the oscillation (i.e., operation) frequency of an existing NIFTE prototype pump well, but significantly overestimate its reported efficiency. Specifically, the LTP and DHX models predicted exergetic efficiencies 11 and 30 times higher than those observed experimentally, respectively. In the present paper, a dissipative thermal loss parameter that can account for the exergetic losses due to the parasitic, cyclic phase change and heat exchange within the device is included in both models in an effort to make realistic predictions of the exergetic efficiencies. The LTP and DHX models, including and excluding the thermal loss parameter, are compared to experimental data. It is found that the inclusion of the thermal loss parameter increases the predicted oscillation frequencies in the DHX model, but has a negligible effect on the frequencies predicted by the LTP model. A more significant effect is observed with respect to the efficiencies, whereby the inclusion of the thermal loss parameter leads to a greatly improved prediction of the exergetic efficiencies of the prototype NIFTE pump by both the LTP and DHX models, both in trend and approximate magnitude. From the results it is concluded that, on accounting for thermal losses, the DHX model achieves the best predictions of the key performance indicators of the NIFTE, that is, of the oscillation frequency and exergetic efficiency of the device.</abstract><cop>Kidlington</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.apenergy.2012.12.069</doi><tpages>18</tpages></addata></record>
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subjects	Applied sciences Devices Electrical analogy Energy Exact sciences and technology Heat engine heat exchangers heat transfer Low-grade heat phase transition prediction temperature Thermofluidic oscillator Unsteady thermal loss
title	Modelling of a two-phase thermofluidic oscillator for low-grade heat utilisation: Accounting for irreversible thermal losses
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