Flow pattern, heat transfer and frictional pressure drop investigation of R365mfc condensation in a micro-structured corrugated gap with mixed angles

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Ru Wang
  • Yifan Zhang
  • Wei Li
  • Stephan Kabelac

Organisationseinheiten

Externe Organisationen

  • Zhejiang University
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Details

OriginalspracheEnglisch
Aufsatznummer117812
FachzeitschriftApplied Thermal Engineering
Jahrgang201
Frühes Online-Datum15 Nov. 2021
PublikationsstatusVeröffentlicht - 25 Jan. 2022

Abstract

This paper experimentally investigates the condensation of R365mfc in a micro-structured corrugated gap with mixed 27°/63° chevron angle. The condensation mechanisms are analyzed by visualizing the flow patterns through a transparent polyurethane plate, and the measurements are carried out at saturation pressure 1.12 bar (pred = 0.034), mass flux between 6.14 and 44.56 kg/m2s and a mean vapor quality from 0.58 to 0.92. Six flow patterns are identified as the mass flux is decreasing: annular flow, wispy-annular flow, partial film flow, smooth liquid film flow, churn flow and slug flow. A flow pattern map is drawn as a function of mass flux and vapor quality, G ≈ 20 kg/m2s is considered as a transition, after which no partial film flow is observed. The combination of G ≈ 20 kg/m2s and x ≈ 0.83 is the transition of the condensation mechanism between gravity-controlled condensation and a combination of gravity-controlled and convection condensation. The frictional pressure drop increases with the increase of mass flux and vapor quality and is not influenced by flow patterns. The experimental heat transfer coefficients and frictional pressure drop are compared with the prediction results calculated by the correlations in the literature and a new heat transfer model is developed, which includes the individual heat transfer models of a gravity-controlled regime, a transition regime and a shear force-controlled regime as well as the transition criterion between these regimes. The new model predicts 97% of experimental data within ±30%, the root mean square error and the mean absolute error is 12.7% and 9% respectively.

ASJC Scopus Sachgebiete

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Flow pattern, heat transfer and frictional pressure drop investigation of R365mfc condensation in a micro-structured corrugated gap with mixed angles. / Wang, Ru; Zhang, Yifan; Li, Wei et al.
in: Applied Thermal Engineering, Jahrgang 201, 117812, 25.01.2022.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Wang R, Zhang Y, Li W, Kabelac S. Flow pattern, heat transfer and frictional pressure drop investigation of R365mfc condensation in a micro-structured corrugated gap with mixed angles. Applied Thermal Engineering. 2022 Jan 25;201:117812. Epub 2021 Nov 15. doi: 10.1016/j.applthermaleng.2021.117812
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title = "Flow pattern, heat transfer and frictional pressure drop investigation of R365mfc condensation in a micro-structured corrugated gap with mixed angles",
abstract = "This paper experimentally investigates the condensation of R365mfc in a micro-structured corrugated gap with mixed 27°/63° chevron angle. The condensation mechanisms are analyzed by visualizing the flow patterns through a transparent polyurethane plate, and the measurements are carried out at saturation pressure 1.12 bar (pred = 0.034), mass flux between 6.14 and 44.56 kg/m2s and a mean vapor quality from 0.58 to 0.92. Six flow patterns are identified as the mass flux is decreasing: annular flow, wispy-annular flow, partial film flow, smooth liquid film flow, churn flow and slug flow. A flow pattern map is drawn as a function of mass flux and vapor quality, G ≈ 20 kg/m2s is considered as a transition, after which no partial film flow is observed. The combination of G ≈ 20 kg/m2s and x ≈ 0.83 is the transition of the condensation mechanism between gravity-controlled condensation and a combination of gravity-controlled and convection condensation. The frictional pressure drop increases with the increase of mass flux and vapor quality and is not influenced by flow patterns. The experimental heat transfer coefficients and frictional pressure drop are compared with the prediction results calculated by the correlations in the literature and a new heat transfer model is developed, which includes the individual heat transfer models of a gravity-controlled regime, a transition regime and a shear force-controlled regime as well as the transition criterion between these regimes. The new model predicts 97% of experimental data within ±30%, the root mean square error and the mean absolute error is 12.7% and 9% respectively.",
keywords = "Condensation mechanism, Flow pattern, Frictional pressure drop, Heat transfer model, Micro-structured plate, Mixed angle",
author = "Ru Wang and Yifan Zhang and Wei Li and Stephan Kabelac",
note = "Funding Information: The author acknowledge the financial support from the China Scholarship Council (CSC) under contract No. 201708330250. ",
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TY - JOUR

T1 - Flow pattern, heat transfer and frictional pressure drop investigation of R365mfc condensation in a micro-structured corrugated gap with mixed angles

AU - Wang, Ru

AU - Zhang, Yifan

AU - Li, Wei

AU - Kabelac, Stephan

N1 - Funding Information: The author acknowledge the financial support from the China Scholarship Council (CSC) under contract No. 201708330250.

PY - 2022/1/25

Y1 - 2022/1/25

N2 - This paper experimentally investigates the condensation of R365mfc in a micro-structured corrugated gap with mixed 27°/63° chevron angle. The condensation mechanisms are analyzed by visualizing the flow patterns through a transparent polyurethane plate, and the measurements are carried out at saturation pressure 1.12 bar (pred = 0.034), mass flux between 6.14 and 44.56 kg/m2s and a mean vapor quality from 0.58 to 0.92. Six flow patterns are identified as the mass flux is decreasing: annular flow, wispy-annular flow, partial film flow, smooth liquid film flow, churn flow and slug flow. A flow pattern map is drawn as a function of mass flux and vapor quality, G ≈ 20 kg/m2s is considered as a transition, after which no partial film flow is observed. The combination of G ≈ 20 kg/m2s and x ≈ 0.83 is the transition of the condensation mechanism between gravity-controlled condensation and a combination of gravity-controlled and convection condensation. The frictional pressure drop increases with the increase of mass flux and vapor quality and is not influenced by flow patterns. The experimental heat transfer coefficients and frictional pressure drop are compared with the prediction results calculated by the correlations in the literature and a new heat transfer model is developed, which includes the individual heat transfer models of a gravity-controlled regime, a transition regime and a shear force-controlled regime as well as the transition criterion between these regimes. The new model predicts 97% of experimental data within ±30%, the root mean square error and the mean absolute error is 12.7% and 9% respectively.

AB - This paper experimentally investigates the condensation of R365mfc in a micro-structured corrugated gap with mixed 27°/63° chevron angle. The condensation mechanisms are analyzed by visualizing the flow patterns through a transparent polyurethane plate, and the measurements are carried out at saturation pressure 1.12 bar (pred = 0.034), mass flux between 6.14 and 44.56 kg/m2s and a mean vapor quality from 0.58 to 0.92. Six flow patterns are identified as the mass flux is decreasing: annular flow, wispy-annular flow, partial film flow, smooth liquid film flow, churn flow and slug flow. A flow pattern map is drawn as a function of mass flux and vapor quality, G ≈ 20 kg/m2s is considered as a transition, after which no partial film flow is observed. The combination of G ≈ 20 kg/m2s and x ≈ 0.83 is the transition of the condensation mechanism between gravity-controlled condensation and a combination of gravity-controlled and convection condensation. The frictional pressure drop increases with the increase of mass flux and vapor quality and is not influenced by flow patterns. The experimental heat transfer coefficients and frictional pressure drop are compared with the prediction results calculated by the correlations in the literature and a new heat transfer model is developed, which includes the individual heat transfer models of a gravity-controlled regime, a transition regime and a shear force-controlled regime as well as the transition criterion between these regimes. The new model predicts 97% of experimental data within ±30%, the root mean square error and the mean absolute error is 12.7% and 9% respectively.

KW - Condensation mechanism

KW - Flow pattern

KW - Frictional pressure drop

KW - Heat transfer model

KW - Micro-structured plate

KW - Mixed angle

UR - http://www.scopus.com/inward/record.url?scp=85119380019&partnerID=8YFLogxK

U2 - 10.1016/j.applthermaleng.2021.117812

DO - 10.1016/j.applthermaleng.2021.117812

M3 - Article

AN - SCOPUS:85119380019

VL - 201

JO - Applied Thermal Engineering

JF - Applied Thermal Engineering

SN - 1359-4311

M1 - 117812

ER -