Experimental study on the thermal hydraulic performance of plate-fin heat exchangers for cryogenic applications

Jiang, Qingfeng; Ming, Zhuang; Zhang, Qiyong; Zhu, Zhigang; Geng, Maofei; Sheng, Linhai; Zhu, Ping

doi:10.1016/j.cryogenics.2018.02.006

Cited by 16 publications

(3 citation statements)

References 28 publications

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“…The correlation was also developed to define the single-phase convection heat transfer coefficients to the Reynolds number as a function that validates with another experimental research. In contrast to the above work, a comparable solution presented by flowing helium as working fluid by Jiang et al [44] and compare j and f factor with existing data. Kumar et al [45] conducted an experimental investigation of solidification and remelting of a brine solution over a cryocooled sphere.…”

Section: Introductionmentioning

confidence: 79%

Analytical and Experimental Investigation of a Plate Fin Heat Exchanger at Cryogenics Temperature

Gupta¹,

Kumar²,

Sahoo³

et al. 2021

IJHT

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Plate-fin heat exchangers provide a broad range of applications in many cryogenic industries for liquefaction and separation of gasses because of their excellent technical advantages such as high effectiveness, compact size, etc. Correlations are available for the design of a plate-fin heat exchanger, but experimental investigations are few at cryogenic temperature. In the present study, a cryogenic heat exchanger test setup has been designed and fabricated to investigate the performance of plate-fin heat exchanger at cryogenic temperature. Major parameters (Colburn factor, Friction factor, etc.) that affect the performance of plate-fin heat exchangers are provided concisely. The effect of mass flow rate and inlet temperature on the effectiveness and pressure drop of the heat exchanger are investigated. It is observed that with an increase in mass flow rate effectiveness and pressure drop increases. The present setup emphasis the systematic procedure to perform the experiment based on cryogenic operating conditions and represent its uncertainties level.

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Section: Introductionmentioning

confidence: 79%

Analytical and Experimental Investigation of a Plate Fin Heat Exchanger at Cryogenics Temperature

Gupta¹,

Kumar²,

Sahoo³

et al. 2021

IJHT

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“…EES provides many built-in mathematical and thermophysical property functions useful for engineering calculations. Many researchers used the EES for thermodynamic modeling of refrigeration systems [12], [20], [21], [25], [43], [59]- [63]. In the thermodynamic analysis, R744, R404A, and R410A refrigerants in the high temperature cycle (HTC), and R1150, R170, and R23 in the low temperature cycle (LTC) were used.…”

Section: 𝐶𝑂𝑃 𝑠𝑦𝑠𝑡𝑒𝑚 = 𝑄 ̇𝑒𝑣𝑎𝑝mentioning

confidence: 99%

Novel Design and Thermodynamic Analyses of Cascade Refrigeration System at Ultra-Low Temperature

Tan

Eri̇ṡen

2022

International Journal of Thermodynamics

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In this study, a cascade refrigeration system comprising gas and vapor compression cycles operating at ultra-low temperature was designed. In the thermodynamic analyses, R744, R404A, and R410A refrigerants in the high temperature cycle (HTC), and R1150, R170, and R23 in the low temperature cycle (LTC) were used. Thermodynamic analyses were carried out using the Engineering Equation Solver package program. Outputs considered were: system performance(COP), compression ratio, mass flow ratio and HTC cascade outlet temperature. Results show that, at different LTC condenser temperature values, R404A/R23 has the highest COP value, in the LTC, R23 has the highest compression ratio, while R1150 has the lowest one, in the HTC, R404A has the highest compression ratio, while R744 has the lowest one, the performance of the system increased with the decrease of the mass flow ratio.

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“…At present, there are few studies on the heat transfer and pressure drop characteristics of marine S-CO 2 power cycle hybrid heat exchangers, but many studies have been carried out on PCHEs and PFHEs. The research on PCHEs and PFHEs mainly focuses on two aspects: to research the variation of convection heat transfer coefficient and fanning drag coefficient with operating conditions and geometry parameters of channels [5][6]; optimize the design of the local structure and overall size to obtain a balance between greater heat exchange and smaller pressure drop [7][8].…”

Section: Introductionmentioning

confidence: 99%

Study on heat transfer and pressure drop characteristics in marine S-CO₂ power cycle hybrid heat exchangers

Wang

Sun

et al. 2020

E3S Web Conf.

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The S-CO2 power cycle has the advantages of compact structure and high energy density, which can be used to recover the waste heat of ship exhaust, thus improving the energy efficiency of ships and reducing emissions. The hybrid heat exchangers with etched plates and fins can be used as the heat transfer device of S-CO2 and exhaust, its heat transfer and pressure drop characteristics have a great influence on S- CO2 power cycle performance. In this study, a CFD model of the hybrid heat exchangers was established. The effects of different exhaust inlet temperatures, inlet mass flow rates and inlet pressures on the heat transfer and the pressure drop characteristics were analyzed by Fluent. The results show that the inlet temperatures and inlet mass flow rates of exhaust have a great influence on the heat transfer characteristics of the hybrid heat exchanger. The inlet mass flow rates and inlet pressures of exhaust have a great influence on the pressure drop characteristics of the hybrid heat exchangers. In the design of the hybrid heat exchangers, the status of the exhaust need to be considered to ensure efficient operation of the heat exchangers. The study can provide guidance for the design of the hybrid heat exchangers.

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Experimental study on the thermal hydraulic performance of plate-fin heat exchangers for cryogenic applications

Cited by 16 publications

References 28 publications

Analytical and Experimental Investigation of a Plate Fin Heat Exchanger at Cryogenics Temperature

Analytical and Experimental Investigation of a Plate Fin Heat Exchanger at Cryogenics Temperature

Novel Design and Thermodynamic Analyses of Cascade Refrigeration System at Ultra-Low Temperature

Study on heat transfer and pressure drop characteristics in marine S-CO₂ power cycle hybrid heat exchangers

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Experimental study on the thermal hydraulic performance of plate-fin heat exchangers for cryogenic applications

Cited by 16 publications

References 28 publications

Analytical and Experimental Investigation of a Plate Fin Heat Exchanger at Cryogenics Temperature

Analytical and Experimental Investigation of a Plate Fin Heat Exchanger at Cryogenics Temperature

Novel Design and Thermodynamic Analyses of Cascade Refrigeration System at Ultra-Low Temperature

Study on heat transfer and pressure drop characteristics in marine S-CO2 power cycle hybrid heat exchangers

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Product

Resources

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Study on heat transfer and pressure drop characteristics in marine S-CO₂ power cycle hybrid heat exchangers