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Vol 231
Pages:
326
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RUS ENG

Mathematical model of heat exchange processes for heat ptotective cooling suit of a rescuer

Authors:
V. R. Alabev1
G. V. Zavyalov2
About authors
  • 1 — Kuban State Technological University ▪ Orcid
  • 2 — Donetsk Academy of Civil Defence
Date submitted:
2017-12-27
Date accepted:
2018-03-22
Date published:
2018-06-25

Abstract

Fires are followed by the range of factors hazardous for human health; a radiant thermal stream accompanied by the high temperature of the environment is one of these factors. For protection of firemen special protective clothing from heat impact and the insulation type clothing are used. The paper demonstrates that the concept of action of such clothing is based on the passive heat protection owing to the use of materials with low conducting capacity or high specific heat. The time of effective protection of a suit is not considerable which reduces the duration of work under the unfavorable climatic conditions drastically, increases the work labor input, leads to the hyperthermia. One of the ways focused on the improvement of the heat protective clothing is a design of suits with cooling, which is stated in the paper. The paper shows that the developed heat protective suits on the basis of water-ice cooling elements are not widely used due to considerable costs. A more reasonable idea refers to the design of heat protective suits with cooling by using running water as the most available coolant circulating along polyvinylchloride pipes arranged between the layers of a suit. The objective stated in the paper is to derive the patterns of non-stationary heat exchange processes in the system «heat flow of the fire source – heat protective suit – rescuer’s body» with cooling the rescuer’s organism by running water circulating along polyvinylchloride pipes in the inner lining space as well as a development of a method to determine time of effective protection of the heat protective suit which was realized by solving the equation of non-stationary heat conductivity by the finite elements method. A mathematical model differs in the way of taking into consideration the external radiant thermal stream from a fire, internal thermal stream of a rescuer’s body, heat insulation properties of the suit materials, their geometrical parameters, temperature of coolant. The paper stated that the time of effective protection of a protective suit with water cooling is well above in comparison with the suits of a similar purposes for firemen and rescuers of the Ministry of emergency situations.

10.25515/pmi.2018.3.326
Go to volume 231

References

  1. Voronov P.S., Mariychuk I.Ph. Equipment for freezing of the cooling elements for the heat protective means of mine rescuers. Ugol Ukrainy. 2003. N 11 (563), p. 12-14 (in Russian).
  2. Gavrilko O.A. The mathematical modeling of the non-stationary heat transfer in the protective clothing with the water-ice cooling system of fire men and mine rescuers. Pozhezhna bezpeka: Zb. nauk. prats’ LIPB, UkrNDIPB MNS Ukrainy. L’viv. 2002. N 3, p. 76-82 (in Ukraine).
  3. GOSТ ISO 11612-2014. Occupational safety standards system. Clothing for protection against heat and flame. General and performance requirements. Мoscow: Standartinform, 2015, p. 23 (in Russian).
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  13. Fire – no. Personal protection. URL: https://pojaru.net.ru/_ld/15/1561_W6N.pdf (date of access 14.10.2017).
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