Effect of flow pattern inside nozzle on spray characteristics of R134a flashing spray

doi:10.11949/j.issn.0438-1157.20161083

Abstract

Abstract:

The flow patterns of liquid inside nozzles have great effect on spray characteristics in flashing spray. A transparent nozzle was manufactured to investigate the flow characteristic inside nozzles during flashing spray and its effects on spray characteristics. The flow patterns of R134a inside the nozzle and spray outside the nozzle were recorded by a high-speed CCD camera under different injection pressure of 0.77, 0.8, 0.9 and 1.5 MPa. The relationship between the internal flow inside the nozzle and external flashing spray were analyzed. It was found that spray patterns will expand immediately around the exit of the nozzle when vaporization occurred inside the nozzle, while the further development of spray radius could be restricted in the same condition. The spray cone angle caused by internal flashing spray was smaller than that caused by external flashing spray in the same condition for the flashing spray of R134a which had high superheated degree at room temperature and atmospheric pressure. The internal flow pattern was extremely unstable under a certain scope of injection pressure, and it was helpful to form stabilized spray patterns when homogeneous bubble flow was formed inside the nozzle.

Key words: flashing spray, visualization, internal flow, spray pattern, gas-liquid flow, nucleation, phase change

摘要：

闪蒸喷雾过程中喷管内流动状态对喷雾形态及雾化效果具有重要的影响。为了观察喷管内流动状态及其对应的喷雾形态，使用高速相机对不同喷射压力条件下制冷剂R134a在石英玻璃直喷管中的流动状态及喷雾形态进行可视化研究，同时分析不同喷射压力条件下喷雾半径的动态变化情况。研究发现，喷管内的气化可以促进喷管出口处喷雾半径的迅速扩大，但同时限制了喷雾半径在喷雾过程中的进一步发展。喷管内流动状态在一定喷射压力下具有极强的不稳定性，在喷管内形成均匀的泡状流有利于形成均匀、稳定的喷雾形态。

关键词: 闪蒸喷雾, 可视化, 管内流动, 喷雾形态, 气液两相流, 成核, 相变

CLC Number:

TK121

WANG Xinsheng, CHEN Bin. Effect of flow pattern inside nozzle on spray characteristics of R134a flashing spray[J]. CIESC Journal, 2016, 67(12): 4929-4935.

王新升, 陈斌. R134a闪蒸喷雾过程中喷管内流动形态对喷雾特性的影响[J]. 化工学报, 2016, 67(12): 4929-4935.

References 20

[1]	周致富, 吴威涛, 王国祥, 等. R134a闪蒸喷雾液滴动力学特征实验研究[J]. 工程热物理学报, 2013, 34(1):87-90. ZHOU Z F, WU W T, WANG G X, et al. An experimental study on the droplets dynamics of flashing spray with R134a[J]. Journal of Engineering Thermophysics, 2013, 34(1):87-90.
[2]	BROWN R, YORK J L. Sprays formed by flashing liquid jets[J]. AIChE Journal, 1962, 8(2):149-153.
[3]	SENDA J, YAMAGUCHI M, TSUKAMOTO T, et al. Characteristics of spray injected from gasoline injector[J]. JSME International Journal Series B-Fluids and Thermal Engineering, 1994, 37(4):931-936.
[4]	NELSON J, MILNER T, ANVARI B, et al. Dynamic epidermal cooling during pulsed laser treatment of port-wine stain:a new methodology with preliminary clinical evaluation[J]. Archives of Dermatology, 1995, 131(6):695-700.
[5]	WANG R, ZHOU Z F, CHEN B, et al. Surface heat transfer characteristics of R404a pulsed spray cooling with an expansion-chambered nozzle for laser dermatology[J]. International Journal of Refrigeration, 2015, 60:206-216.
[6]	OZA R D, SINNAMON J F. An experimental and analytical study of flash-boiling fuel injection[R]. SAE Technical Paper, 1983.
[7]	OZA R D. On the mechanism of flashing injection of initially subcooled fuels[J]. Journal of Fluids Engineering, 1984, 106(1):105-109.
[8]	REITZ R D. A photographic study of flash-boiling atomization[J]. Aerosol Science and Technology, 1990, 12(3):561-569.
[9]	VIEIRA M M, SIMOES-MOREIRA J R. Low-pressure flashing mechanisms in iso-octane liquid jets[J]. Journal of Fluid Mechanics, 2007, 572:121-144.
[10]	LIN T C, SHEN Y J, WAND M R. Effects of superheat on characteristics of flashing spray and snow particles produced by expanding liquid carbon dioxide[J]. Journal of Aerosol Science, 2013, 61:27-35.
[11]	ZHANG Y Y, LI S Y, ZHENG B, et al. Quantitative observation on breakup of superheated liquid jet using transparent slit nozzle[J]. Experimental Thermal and Fluid Science, 2015, 63:84-90.
[12]	JU D H, FANG J H, ZHANG T T, et al. High-speed shadow imaging in internal flow pattern and macroscopic characteristics of a R134a flash-boiling spray discharged through a vertical twin-orifice atomizer[J]. International Journal of Multiphase Flow, 2015, 75:224-236.
[13]	JU D H, WANG C H, QIAO X Q, et al. Internal flow pattern and macroscopic characteristics of a flash-boiling spray actuated through a twin-orifice atomizer with low injection pressure[J]. Atomization and Sprays, 2016, 26(4):377-410.
[14]	周致富, 白飞龙, 王锐, 等. 带膨胀腔喷嘴制冷剂R134a闪蒸喷雾可视化研究[J]. 工程热物理学报, 2015, 36(12):2646-2650. ZHOU Z F, BAI F L, WANG R, et al. Visualization of the flashing spray generating by the expansion-chamber nozzle using R134a[J]. Journal of Engineering Thermophysics, 2015, 36(12):2646-2650.
[15]	GÜNTHER A, WIRTH K E. Evaporation phenomena in superheated atomization and its impact on the generated spray[J]. International Journal of Heat and Mass Transfer, 2013, 64:952-965.
[16]	LI S Y, ZHANG Y Y, XU B. Correlation analysis of superheated liquid jet breakup to bubble formation in a transparent slit nozzle[J]. Experimental Thermal and Fluid Science, 2015, 68:452-458.
[17]	KRESS T S. Mass transfer between small bubbles and liquids in concurrent turbulent pipeline flow[R]. Oak Ridge National Lab., Tenn., 1972.
[18]	HINZE J O. Fundamentals of the hydrodynamic mechanism of splitting in dispersion processes[J]. AIChE Journal, 1955, 1(3):289-295.
[19]	NAGAI N, SATO K, LEE C W. Atomization characteristics of superheated liquid jets[C]//International Conference on Liquid Atomization and Spray Systems, ICLASS-85. 1985:1-11.
[20]	PARK B S, LEE S Y. An experimental investigation of the flash atomization mechanism[J]. Atomization and Sprays, 1994, 4(2):159-179.