THERMAL SCIENCE

International Scientific Journal

Li-Hua Cao

,

He-Yong Si

,

En-Fu Dong

,

Zhan-Zhou Wang

,

Huan-Huan Luo

,

Gui-Ping Zhou

,

Nan Wu

EVAPORATION CHARACTERISTICS AND EFFICIENT WORKING AREA OF MULTI-STAGE HIGH PRESSURE AND TEMPERATURE REDUCING VALVE

ABSTRACT
A well understanding on the evaporation characteristics and efficient working area of multi-stage high pressure and temperature reducing valve (MSHPTRV) is important for improving the performance and safety of MSHPTRV. The water spraying and evaporation model are integrated into the flow model of MSHPTRV. Compared with the experimental data, the model can show the thermal process well. The flow characteristics and interaction between steam and droplets are presented. On this basis, the increase rate of entropy, Sdis, is adopted to analyze the thermodynamic loss and innovatively determine the efficient working area of MSHPTRV. The results show that the pressure reducing effect of the second orifice plate is prominent, which accounts for 41.6% of the total pressure drop. The "steam-water layer" is formed at the boundary of steam and water. At the inlet of second orifice plate, the maximum Sdis is 0.782, and the downstream of second orifice plate is the efficient working area of MSHPTRV. The length of evaporation section increases with the droplets diameter significantly.
KEYWORDS
multi-stage high pressure and temperature reducing valve, evaporation model, water spraying, flow characteristics, increase rate of entropy
PAPER SUBMITTED: 2020-07-19
PAPER REVISED: 2021-03-02
PAPER ACCEPTED: 2021-03-09
PUBLISHED ONLINE: 2021-05-16
DOI REFERENCE: https://doi.org/10.2298/TSCI200719162C
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2022, VOLUME 26, ISSUE Issue 2, PAGES [1623 - 1636]
REFERENCES
  1. Zou D, et al., Solving the combined heat and power economic dispatch problems by an improved genetic algorithm and a new constraint handling strategy, Applied Energy, 237 ( 2019 ), pp. 646-670.
  2. Pujihatma P, et al., Combined heat and power - multi-objective optimization wit h an associated petroleum and wet gas utilization constraint, Journal of Natural Gasence and Engineering, 54 ( 2018 ), pp. 25-36.
  3. Wu M Q, Comparison of integrated and divided desuperheater (in Chinese), Chemical Engineering Design Communications, 42 ( 2016 ), 2, pp. 101-102+107 .
  4. Li Guangjun, et al., The structure design and analysis of temperature and pressure of water cooling ( in Chinese ), Valve, ( 2015 ) 4, pp. 7-9 .
  5. Wang P, et al., Influence of a circular strainer on unsteady flow behavior in steam turbine control valves, Applied Thermal Engineering, 115 (2017), pp.463-476.
  6. Wang P, et al., Unsteady flow behavior of a steam turbine control valve in the choked condition: Field measurement, detached eddy simulation and acoustic modal analysis, Applied Thermal Engineering, 117 (2017), pp. 725-739.
  7. Zhao B, et al., FSI model of valve motion and pressure pulsation for investigating thermodynamic process and internal flow inside a reciprocating compressor, Applied Thermal Engineering, 131 (2018), pp. 998-1007.
  8. Fan X, et al ., Energy consumption investigation of electromagnetic valve train at gas pressure conditions, Applied Thermal Engineering, 146 (2019), pp. 768-774.
  9. Qian J Y, et al., Mach number analysis on multi-stage perforated plates in high pressure reducing valve, Energy Conversion & Management, 119 ( 2016 ), pp. 81-90.
  10. Qian J Y, et al., Flow rate analysis of compressible superheated steam through pressure reducing valves, Energy, 135 ( 2017 ), pp. 650-658.
  11. Xu H, et al., Hydrodynamic characterization and optimization of Contra-push check valve by numerical simulation, Annals of Nuclear Energy, 38 ( 2011 ), 6, pp. 1427-1437.
  12. Li S, et al., CFD simulation of dynamic characteristics of a solenoid valve for exhaust gas turbocharger system, Applied Thermal Engineering, 110 ( 2017 ), pp. 213-222.
  13. Jin Z J, et al., Numerical analysis of flow and temperature characteristics in a high multi-stage pressure reducing valve for hydrogen refueling station, International Journal of Hydrogen Energy, 41 ( 2016 ), 12, pp. 5559-5570.
  14. Zhang J, et al., Prediction of blowdown of a pressure relief valve using response surface methodology and CFD techniques, Applied Thermal Engineering, (2018), pp. 713-726.
  15. Hou C W, et al., Parametric analysis on throttling components of multi-stage high pressure reducing valve, Applied Thermal Engineering, 128 ( 2018 ), pp. 1238-1248.
  16. Aung N Z, et al., CFD analysis of flow forces and energy loss characteristics in a flapper - nozzle pilot valve with different null clearances, Energy Conversion & Management, 83 ( 2014 ), pp. 284-295.
  17. Menéndez B, et al., Unsteady three-dimensional modeling of the Fluid - Structure Interaction in the check valves of diaphragm volumetric pumps, Journal of Fluids and Structures, 90 ( 2019 ), pp. 432-449.
  18. Li F Q, et al., Transient thermal behaviors of a scaled turbine valve: Conjugate heat transfer simulation and experimental measurement, International Journal of Heat and Mass Transfer, 141 ( 2019 ), pp. 1 16-128.
  19. Jalali A, et al., Failure analysis in a steam turbine stop valve of a thermal power plant, Engineering Failure Analysis, 105 ( 2019 ), pp. 1131-1140.
  20. Chen F Q, et al., Pressure analysis on two-step high pressure reducing system for hydrogen fuel cell electric vehicle, International Journal of Hydrogen Energy, 42 ( 2017 ), 16, pp. 11541-11552.
  21. Chen F Q, et al., Turbulent compressible flow analysis on multi-stage high pressure reducing valve, Flow Measurement and Instrumentation, 61 ( 2018 ), pp.26-37 .
  22. Chen F Q, et al., Thermo-mechanical stress and fatigue damage analysis on multi-stage high pressure reducing valve, Annals of Nuclear Energy, 110 ( 2017 ), pp. 753-767.
  23. Boccardi G, et al., Two-phase flow through pressure safety valves. Experimental investigation and model prediction, Chemical Engineering Science, 60 (2005), pp. 5284-5293.
  24. Schmidt J, Sizing of nozzles, venturis, orifices, control and safety valves for initially sub-cooled gas/liquid two-phase flow - The HNE-DS method, Forschung Im Ingenieurwesen, 71 (2007), pp. 47-58.
  25. Mansour A, et al., A review of flash evaporation phenomena and resulting shock waves, Experimental Thermal and Fluid Science, 107 (2019), pp. 146-168.
  26. Xu M, et al., Effect of water spray in exhaust passage of steam turbine on flow field of the last stage during windage, International Journal of Heat and Mass Transfer, 161 (2020), pp. 120296.
  27. Cao L, et al., Effects of leakage vortex on aerodynamic performance and loss mechanism of steam turbine, Proceedings of the Institution of Mechanical Engineers Part A Journal of Power and Energy, 0 (2019), pp. 1-11.
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Evaporation characteristics and efficient working area of multi-stage high pressure and temperature reducing valve

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence