Influence of temperature measurement method on surface heat transfer during spray cooling

doi:10.11949/j.issn.0438-1157.20160606

Abstract

Abstract:

Spray cooling is widely used in industries. Cryogen spray cooling has been implemented for the epidermis protection during laser surgery. For the improvement of cooling efficiency, the surface temperature was measured to calculate the surface heat transfer characteristics by the reverse heat conduction method. In order to investigate the influence of temperature measurement methods on the experimental result, a transient spray cooling rig was constructed to study the different heat transfer characteristics by using the thin film thermocouple (TFTC) fabricated by magnetron sputtering, the fine thermocouple (FTC) and the slice thermocouple (STC). The result suggested that the TFTC had the most sensitive thermal response, which can accurately reflect the temperature variation and corresponding heat flux. As for the FTC and STC, due to the limitation of indirect measurement, there was an obvious lag in temperature variation, which affected the subsequent analysis such as heat flux and apparent convective heat transfer coefficient. The employment of thin film thermocouple ensured the precise investigation of surface heat transfer during transient spray cooling, with reliable reference for clinical treatment.

Key words: spray cooling, surface heat transfer, temperature measurement, R404A

摘要：

喷雾冷却在工业过程中应用广泛，制冷剂喷雾是激光皮肤手术中实施表皮冷保护的必要手段。为提高冷却效率，需要通过表面温度的测量反推表面传热特性。为探索不同表面温度测量方式对实验结果的影响，搭建了瞬态喷雾冷却实验台，分别使用磁控溅射薄膜热电偶（TFTC）、丝状热电偶（FTC）和片状热电偶（STC）研究了R404A制冷剂喷雾环氧树脂表面传热特性的差异。实验结果表明，磁控溅射薄膜热电偶（TFTC）热响应性能最佳，能准确及时地反映表面温度的瞬态变化且可与热通量变化准确对应。丝状热电偶（FTC）和片状热电偶（STC）属于间接测温，温度变化存在明显滞后，影响热通量、对流传热系数等表面传热特性的精确分析。薄膜溅射热电偶测温是准确研究瞬态喷雾冷却表面传热过程的可靠手段，可为临床治疗提供理论指导。

关键词: 喷雾冷却, 表面传热, 温度测量, R404A

CLC Number:

TK124

YANG Tao, ZHOU Zhifu, CHEN Bin, ZHAO Xi, WANG Guoxiang. Influence of temperature measurement method on surface heat transfer during spray cooling[J]. CIESC Journal, 2016, 67(11): 4558-4565.

杨涛, 周致富, 陈斌, 赵曦, 王国祥. 表面温度测量方式对喷雾冷却表面传热特性的影响[J]. 化工学报, 2016, 67(11): 4558-4565.

References 25

[1]	LANDTHALER M, ULRICH H, HOHENLEUTNER S, et al. Role of laser therapy in dermatology clinical aspects[J]. Dermatology, 2004, 208(2):129-134.
[2]	KAUFMANN R. Lasers in dermatology-state of the art[J]. Medical Laser Application, 2005, 20(2):103-109.
[3]	SCHNEIDER B V, MITSUHASHI Y, SCHNYDER U W. Ultrastructural observations in port wine stains[J]. Archives of Dermatological Research, 1988, 280(6):338-345.
[4]	CHAPAS A, EICKHORST K, GERONEMUS R. Efficacy of early treatment of facial port-wine stains in newborns:a review of 49 cases[J]. Lasers in Surgery and Medicine, 2007, 39(7):56-568.
[5]	CHANG C J, ANVARI B J, NELSON J S. Cryogen spray cooling for spatially selective photocoagulation of hemangiomas:a new methodology with preliminary clinical reports[J]. Plastic and Reconstructive Surgery, 1998, 102(2):459-463.
[6]	ANDERSON R R, PARRISH J A. Selective photothermolysis:precise microsurgery by selective absorption of pulsed radiation[J]. Science, 1983, 220(4596):524-527.
[7]	DAI T, YASEEN M A, DIAGARADJANE P, et al. Comparative study of cryogen spray cooling with R-134a and R-404a:implications for laser treatment of dark human skin[J]. Journal of Biomedical Optics, 2006, 11(4):312-320.
[8]	ALTSHULER G B, ZENZIE H H, EROFEEV A V, et al. Contact cooling of the skin[J]. Physics in Medicine and Biology, 1999, 44(4):1003-1023.
[9]	NELSON J S, MILNER T E, ANVARI B J, 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.
[10]	NELSON J S, MILNER T E, ANVARI B J, et al. Dynamic epidermal cooling in conjunction with laser-induced hotothermolysis of port wine stain blood vessels[J]. Lasers in Surgery and Medicine, 1996, 19(2):224-229.
[11]	ZHOU Z F, CHEN B, WANG Y S, et al. An experimental study on pulsed spray cooling with refrigerant R-404a in laser surgery[J]. Applied Thermal Engineering, 2012, 39(3):29-36.
[12]	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.
[13]	AGUILAR G, VERKRUYSSE W, MAJARON B, et al. Measurement of heat flux and heat transfer coefficient during continuous cryogen spray cooling for laser dermatologic surgery[J]. IEEE Journal of Selected Topics in Quantum Electronics, 2001, 7(6):1013-1021.
[14]	VERKRUYSSE W, MAJARON B, AGUILAR G, et al. Dynamics of cyrogen deposition relative to heat extraction rate during cryogen spray cooling[J]. Proc. SPIE, 2000, 3907(3907):37-48.
[15]	周致富, 陈斌, 白飞龙, 等. 新型喷嘴R404A闪蒸瞬态喷雾冷却传热特性[J]. 化工学报, 2015, 66(S1):100-105. ZHOU Z F, CHEN B, BAI F L, et al. Heat transfer dynamics of R404a flashing pulsed spray cooling using expansion-chamber nozzle[J]. CIESC Journal, 2015, 66(S1):100-105.
[16]	AGUILAR G, VU H, NELSON J S. Influence of angle between the nozzle and skin surface on the heat flux and overall heat extraction during cryogen spray cooling[J]. Physics in Medicine and Biology, 2004, 49(10):N147-N153.
[17]	AGUILAR G, WANG G X, NELSON J S. Dynamic behavior of cryogen spray cooling:effects of spurt duration and spray distance[J]. Lasers in Surgery and Medicine, 2003, 32(2):152-159.
[18]	JIA W, AGUILAR G, WANG G X, et al. Heat-transfer dynamics during cryogen spray cooling of substrate at different initial temperatures[J]. Physics in Medicine and Biology, 2004, 49(23):5295-5308.
[19]	周致富, 吴威涛, 王国祥, 等. 制冷剂闪蒸瞬态喷雾冷却表面温度的快速测量[J]. 化工学报, 2011, 62(11):3060-3065. ZHOU Z F, WU W T, WANG G X, et al. Thin-film thermocouples for rapid measurement of transient surface temperature in cryogen spray cooling[J]. CIESC Journal, 2011, 62(11):3060-6065.
[20]	周致富. 制冷剂闪蒸喷雾与传热特性实验及液滴蒸发理论研究[D]. 西安:西安交通大学, 2013. ZHOU Z F. Experimental study on the spray characteristics and heat transfer dynamics of cryogen flashing spray, and theoretical study on the droplet evaporation model[D]. Xi'an:Xi'an Jiaotong University, 2013.
[21]	FRANCO W, LIU J, WANG G X, et al. Radial and temporal variations in surface heat transfer during cryogen spray cooling[J]. Physics in Medicine and Biology, 2005, 50(2):387-397.
[22]	周致富, 徐腾宇, 赵曦, 等. 喷雾冷却表面瞬态热流密度计算方法研究[J]. 工程热物理学报, 2016(in press). ZHOU Z F, XU T Y, ZHAO X, et al. Methodology for prediction of time-varying heat flux during pulsed spray cooling[J]. Journal of Engineering Thermophysics, 2016(in press).
[23]	DUCK F A. Physical Properties of Tissue:A Comprehensive Reference Book[M]. London:Acadamic Press, 1990.
[24]	ZHOU Z F, XU T Y, CHEN B. Algorithms for the estimation of transient surface heat flux during ultra-fast surface cooling[J]. International Journal of Heat and Mass Transfer, 2016, 100(2016):1-10.
[25]	AGUILAR G, WANG G X, NELSON J S. Effect of spurt duration on the heat transfer dynamics during cryogen spray cooling[J]. Physics in Medicine and Biology, 2003, 48(14):2169-2181.