Simulation of heat stress of people wearing medical protective clothing in summer

doi:10.16265/j.cnki.issn1003-3033.2023.01.0427

Abstract

Abstract:

To reduce the health risks of wearing medical protective clothing for a long time in summer, the standard Chinese human body model was selected, three classical heat strain models (PHS model, HSDA model and Fiala body temperature regulation model) were used, and the core temperatures and sweat rates of the medical staff wearing medical protective clothing in various environments in summer were simulated. The recommended water intake rate and safe time for the medical staff in various environments in summer were determined. The results indicate that the physiological responses of human body are significantly affected by environmental parameters. In different environments, the maximum difference of core temperature and sweat rate is 11.17 ℃ and 6 592 g/h, respectively. When the ambient temperature increases by 1 ℃ or the ambient relative humidity increases by 1%, the average safety time decreases by 5.9 and 0.89 min, respectively. When the ambient temperatures is 36 and 40 ℃, the safety time is only 88-124 and 75-100 min, respectively. In the low temperature and low humidity conditions, the prediction results of the three models are relatively close. However, in the high temperature and high humidity conditions, the prediction results of the three models are significant different, and the maximum difference of the core temperature and sweat rate is 7.55 ℃ and 5 654.35 g/h, respectively.

Key words: summer, medical protective clothing, heat stress, medical staff, core temperature, sweat rate, predicted heat strain (PHS), heat strain decision aid (HSDA)

ZHENG Guozhong, DAI Wei. Simulation of heat stress of people wearing medical protective clothing in summer[J]. China Safety Science Journal, 2023, 33(1): 221-226.

Figures/Tables 6

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相对湿度/%	模型名称	出汗率/(g·h^-1)
相对湿度/%	模型名称	20 ℃	24 ℃	28 ℃	32 ℃	36 ℃	40 ℃
40	HSDA	800.6	915.1	1 042.2	1 190.8	1 377.6	1 639.8
	PHS	359.5	438.25	577.5	807	1 153.	1 218
	Fiala	267.1	467.7	875.2	1 133.2	1 263.6	1 321.6
60	HSDA	846.0	988.2	1 163.4	1 404.2	1 805.0	2 877.1
	PHS	402.5	554.25	851.75	1 194.5	1 214.5	1 211.5
	Fiala	305.9	538.1	942.7	1 168.0	1 286.8	1 351.7
80	HSDA	900.8	1 084.1	1 345.6	1 823.3	3 850.8	>4 500
	PHS	485.5	766.2	1 185	1 212.5	1 209.1	1 204.75
	Fiala	1 753.6	3 082.6	5 014.0	6 002.1	6 541.9	6 859.1

相对湿度/%	补水量/(g·h^-1)
相对湿度/%	20 ℃	24 ℃	28 ℃	32 ℃	36 ℃	40 ℃
40	476	607	832	1 044	1 265	1 393
60	518	694	986	1 256	1 435	1 813
80	1 047	1 644	2 515	3 013	3 867	4 188

相对湿度/%	模型名称	安全时间/min
相对湿度/%	模型名称	20 ℃	24 ℃	28 ℃	32 ℃	36 ℃	40 ℃
40	HSDA	193	158	136	120	108	97
	PHS	240^*	240^*	240^*	240^*	132	86
	Fiala	240^*	240^*	235	165	133	118
相对湿度/%	模型名称	安全时间/min
相对湿度/%	模型名称	20 ℃	24 ℃	28 ℃	32 ℃	36 ℃	40 ℃
60	HSDA	178	147	126	111	99	88
	PHS	240^*	240^*	228	114	74	51
	Fiala	240^*	240^*	215	156	127	113
80	HSDA	167	138	118	103	91	81
	PHS	240^*	240^*	119	74	52	39
	Fiala	240^*	240^*	197	147	121	106

相对湿度/%	安全时间/min
相对湿度/%	20 ℃	24 ℃	28 ℃	32 ℃	36 ℃	40 ℃
40	224	213	204	175	124	100
60	219	209	190	127	100	84
80	216	206	145	108	88	75