RU2104527C1 - Method of estimation of cooling microclimate effect on human organism - Google Patents

Abstract

FIELD: studying of cooling microclimate factors. SUBSTANCE: in addition to determination of actual value of dermatopulmonic moisture losses and category of hardness of work done, normalized minimum permissible level of dermatopulmonic moisture losses corresponding to this work is found, and actual value of dermatopulmonic moisture losses is subtracted from it. The remainder of moisture losses obtained is used to estimate effect of cooling microclimate and heat-shielding properties of worn clothes on human organism. Method gives integral objective estimation of effect of cooling microclimate and heat-shielding properties of clothes on human organism on any level of muscular activity. EFFECT: extended field of application. 3 tbl

Description

 The invention relates to medicine, namely to methods for studying the conditions of human life and can be used by hygienists, physiologists and organizers of production for an in-depth study of the factors of the cooling microclimate and the development of effective measures for their optimization.

 There is a method of studying the microclimate and determining its effect on the body by measuring the individual components of it (temperature, relative humidity, air mobility, thermal radiation) and comparing their values with existing standards. However, the application of this method often gives errors, since this method does not take into account the effect of the combined action of microclimate factors on the body.

 There is a method of assessing the influence of the microclimate and heat-protective properties of clothing on the body according to the debit of skin-pulmonary moisture loss, which is the main indicator of the functional state of the human thermoregulatory apparatus. The magnitude of these moisture losses in a person under the influence of a heating microclimate is determined by the combined influence of heat generation caused by muscle load and reduced heat transfer due to high temperature, humidity, low air mobility, wearing an insulating suit, etc. When exposed to a cooling microclimate, the value of skin-pulmonary moisture loss is determined by the combined effect of heat generation caused by muscle load and increased heat transfer due to low temperature, high humidity, air mobility, wearing clothes with low thermal insulation properties, etc. There is also a method by which it is possible to predict the total dehydration of sweating at rest in a well physically trained and acclimatized subject for a continuous 4-hour period in an environment with known physical characteristics. This value, expressed in liters over 4 hours, is called the “Predictable four-hour sweating rate”.

 However, these methods also have significant drawbacks that reduce the accuracy of the results and limit their scope: 1) in addition to moisture losses due to the heating, cooling microclimate and heat-protective properties of clothes, these methods take into account moisture losses caused by muscle activity, which is the reason for their low accuracy; 2) it is possible to use these methods only on a person who is at rest, which in practice is feasible only in laboratory conditions and is unacceptable for research on the job; this is the reason for limiting the scope of the method.

 There is a method for assessing the effect of a heating microclimate on the human body, according to which, in addition to the actual value of skin and pulmonary moisture losses, a severity category of the work performed is determined, the normalized upper permissible level of skin and pulmonary moisture losses corresponding to this work is found and subtracted from the actual value of skin and pulmonary moisture losses; on the basis of the obtained balance of these moisture losses, the effect of the heating microclimate and the heat-protective properties of clothes on the human body is evaluated. This method allows you to give an integral, objective assessment of the influence of only the heating microclimate and heat-protective properties of clothing on the human body at any levels of muscle activity, which is the reason for reducing the scope of the method, since they cannot evaluate the effect of the cooling properties of the environment.

 The aim of the invention is to expand the scope by establishing the magnitude of the skin-pulmonary moisture loss, provided by the influence of only the cooling microclimate and heat-protective properties of clothing.

 The goal is achieved by the fact that in a known way of finding skin-pulmonary moisture losses, which consists in determining the algebraic sum of the differences in the body weight of the test person and the amount of fluid consumed and extracted during the studied time, the actual value of skin-pulmonary moisture losses is determined, the severity category of the work performed is determined by a known method the normalized lower permissible level of skin and pulmonary moisture losses corresponding to this work is found (takes place in normal climatic conditions, i.e., in conditions of sintering the thermal equilibrium of the human body), then when studying the effect of the cooling microclimate (the actual skin-pulmonary moisture loss is less than the lower normalized allowable energy consumption of the skin-pulmonary moisture loss) from the normalized lower acceptable level of skin-pulmonary moisture loss, the actual value of the skin-pulmonary moisture loss is subtracted and the received balance of these moisture losses assesses the effect of the cooling microclimate and the heat-protective properties of clothes on the human body century.

 Based on the known standards of the permissible thermal state of a person with different amounts of energy expenditure of the body under normal microclimate, Table 1 is compiled. Using this table, one can easily determine the normalized lower permissible level of cutaneous pulmonary moisture loss, which is ensured by muscular work in normal microclimatic conditions. In order to obtain reliable results, before comparing the actual skin-pulmonary moisture losses found in the studies with the normative material presented in Table 1, the first should be divided by the average weight in the experimental group of the studied and multiplied by 70, since the norms of skin-pulmonary moisture losses presented in the above table calculated for a person weighing 70 kg.

For the convenience of using the data obtained using the proposed method in various kinds of microclimate studies, the following empirical formula (I) was compiled for calculating the effect of the cooling microclimate and the heat-protective properties of wearable clothing on the human body (P):
P = C • B + 1, conv. units, (I)
Where
P is an indicator of the degree of influence of the cooling microclimate and the heat-shielding properties of wearable clothing on the human body;
C is a coefficient equal to values of 0.0180; 0.0077; 0.0054; 0.0046 and 0.0036, respectively, for a person in a state of relative rest, with light, moderate, heavy and very heavy work;
B - the residual value of skin-pulmonary moisture loss, obtained by comparing the normative and actual data of these moisture losses, g / h.

 In the preparation of formula I, the following provisions are conditionally adopted: at P ≤ I, there is no adverse effect of the cooling microclimate and heat-protective properties of wearable clothing on the human body, and at P> I there is an adverse effect of the cooling microclimate and heat-protective properties of wearable clothing. When determining the value of coefficient C, which reflects the physiological cost of skin-pulmonary moisture losses in Formula I, we proceeded from literature data that the physiological cost of skin-pulmonary moisture losses during a cooling microclimate is approximately 10 times higher than the physiological cost of these moisture losses during a heating microclimate. The difference in the levels of the physiological cost of skin-pulmonary moisture losses during cooling and heating microclimate varies with a certain regularity in a number of works of varying severity. So, in a state of relative rest, during mild, moderate, heavy and very hard work, the physiological cost of the limiting values of skin and pulmonary moisture losses during cooling and heating microclimates differs by 18; 7.7; 5.4; 4.6; and 3.6 times, respectively. Since, in relation to assessing the influence of the heating microclimate, the coefficient C is taken equal to 0.0010, for the characteristics of the cooling microclimate the values of the coefficient C in a state of relative rest, with light, moderate, heavy, and very hard work, should be equal to, respectively, 0.0180; 0.0077; 0.0054; 0.0046 and 0.0036.

 Thus, according to the actual value of muscle load and energy expenditure established in studies of working conditions (the largest value of one of the criteria for the severity of the muscle work presented in Table 1), the normalized lower value of skin-pulmonary moisture losses acceptable for normal climatic conditions is found, from which subtract the actual value of skin-pulmonary moisture loss and the resulting moisture loss by means of formula I assess the effect of the cooling microclimate and heat-shielding properties hope for the human body.

 A comparative analysis of the proposed solution with the prototype shows that the claimed method differs from the known one in that they find the normalized lower permissible level of skin-pulmonary moisture loss and subtract from it the debit of the actual skin-pulmonary moisture loss, the effect of the cooling microclimate on the resulting residual skin-pulmonary moisture loss is estimated human organism.

 Thus, the claimed method meets the criteria of the invention of "novelty." There are known technical solutions in which other objective indicators of the functional state of the body, for example, skin temperature (weighted average skin temperature, gradient of the temperature of the skin of the trunk and feet), and body temperature are used to assess the effect of the cooling microclimate and the heat-protective properties of clothes on humans. However, a theoretical analysis of the issue indicates that the indicators cannot serve as accurate criteria for the degree of influence of the cooling microclimate on the body, since under the given microclimate the temperature gradient of the body and feet correlates with heat sensations only if the subjects are at rest or do light work ; for the same reason, the weighted average temperature of the skin, established by measuring the skin temperature at several specific points of the proximal and distal parts of the body, with medium, heavy and very heavy muscle loads, cannot be a reliable criterion for assessing the effect of the cooling microclimate and heat-protective properties of worn clothing on the body person. Nor can body temperature be a reliable indicator of the body’s thermal state, since it depends primarily on the severity of the work performed and, being a homeostatic constant, is little dependent on the effect of the cooling microclimate. With a normally functioning system of thermoregulation with an increase in cold exposure to the body, body temperature is maintained at a constant level, provided by the magnitude of muscle load and the mechanisms of involuntary chemical thermoregulation.

 Thus, the known technical solutions do not provide a determination of the level of functional changes in the body, which is caused by the influence of only the cooling microclimate and heat-protective properties of clothing. The determination of this level of changes in the functional state of a person is achieved in the claimed technical solution. This allows us to conclude that the claimed technical solution meets the criterion of "significant differences".

 Testing the proposed method for assessing the effect of the cooling microclimate and heat-protective properties of clothes on 50 male and female workers in 4 professions at the Tajik, Irkutsk aluminum, Verkhnesalda iron foundries and the Yekaterinburg pasta factory in warm (Table 2) and cold (Table 3) periods of the year showed the efficiency of the method.

From table 2 it is seen that as the average shift in air temperature decreases from 18.5 to 10.9 ^o C, all other factors being equal microclimate and the same heat-shielding properties of wearable clothing (0.5 cl), the adverse effect of the cooling microclimate and heat-shielding properties of worn clothing in terms of indicator P significantly increases (P <0.001).

 In order to adapt the data obtained using the proposed method for assessing the effect of the cooling microclimate on the human body to the existing standards for assessing the factors of the cooling microclimate by means of industrial studies (Table 2), the values of P (the degree of influence of the cooling microclimate and heat-protective properties of clothes on the human body) were determined, which correspond to three degrees of harmfulness and danger of work regulated by hygienic criteria for assessing working conditions ...

The average values of P, their sigmal deviations and errors at 1, 2 and 3 degrees of harmfulness of the work were respectively: 1,052 conventional units, 0.06 and ± 0.030; 1.142 conventional units, 0.06 and ± 0.030; 1.225 conventional units, 0.06 and ± 0.032. Statistical analysis of the obtained material showed that the indicated average values of P are typical for their variant, since 95% of all cases in the studied series are within ± 2 sigma, therefore, the results obtained by adapting P to standard data should be considered reliable. As a criterion for adapting P to Hygienic criteria for assessing working conditions in terms of harmfulness and danger of factors of the working environment, severity and intensity of the labor process, we selected the air temperature of the working area of industrial premises, in which at the time of the study there were no sources of radiant heat, significant differences in humidity , air mobility, and the studied workers were dressed in a set of light clothing with thermal insulation of 0.5 clo. Based on the data obtained, the first, second and third degrees of harmfulness of work correspond to the following ranges P for a cooling microclimate: I degree 1.001 ^o C 1.100 srvc .; 2 degree 1,101 ^o C 1,200 srvc; 3 degree> 1,200 srvc.

 Taking into account the presented standards P, the effect of the cooling microclimate for the operators of the dough-depositing plants corresponds to the 1st degree of harmfulness of the work, for the silicon cleaners - the 2nd degree of the harmfulness of the work, for the charge shakers - the 3rd degree of the harmfulness of the work.

The use of the proposed method for assessing the effect of a cooling microclimate on the human body under the combined effects of climate-forming factors with cooling, heating and heat-insulating properties (Table 3) showed that, despite the low level of ambient air temperatures characterizing (according to traditional methods for assessing the microclimate) harmfulness 2-3 degrees of labor, skin and pulmonary moisture losses in workers exceeded the lower permissible level for the amount of energy consumption available during operation indicator of minute volume of breath. This indicates the absence of voltage of the thermoregulation system, which is confirmed by the subjective assessment of the thermal state of workers on a seven-point Krichagin scale. The heat sensation of workers is on average 3.8 ^o C 3.9, which characterizes their thermal state as comfort-cool. The satisfactory thermal condition of the workers under study (Table 3) is apparently due to the charge builders significant heat generation due to the severity of work and the use of warm clothing, and electrolytic cells, due to the positive influence of thermal clothing and local heat sources from the serviced technological equipment.

 Thus, the testing of the proposed method for assessing the effect of the cooling microclimate on the human body indicates that the claimed method, compared with the existing ones, allows us to evaluate the effect of the cooling microclimate and heat-protective properties of clothing, taking into account the combined effect of all climate-forming factors at any levels of muscle activity. This leads to a significant expansion of the scope of the method in the process of studying the working conditions of workers exposed to a cooling microclimate.

Claims (1)

 A method for assessing the effect of a cooling microclimate on the human body, which consists in determining the skin-pulmonary moisture loss and the severity category of the work performed, characterized in that they find the corresponding normalized lower permissible level of skin-pulmonary moisture loss, from which the debit of skin-pulmonary moisture loss is subtracted to one hundred once the remainder of these moisture losses is added an empirical coefficient equal to 1, and with a result of less than or equal to 1, the adverse effect of the cooling microclimate is absent, and if More 1 ultat cooling effect nebragopriyatno microclimate.

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