RU2790009C2 - Method for determination of thermal-fireproof characteristics of personal protective equipment - Google Patents

Abstract

FIELD: personal protective equipment.

SUBSTANCE: invention relates to the field of personal protective equipment and is a method for determination of thermal-fireproof characteristics of personal protective equipment for different classes of workers, including firefighters, and its technical implementation in the form of a test bench. The method for determination of thermal-fireproof characteristics of personal protective equipment (PPE) being in a working position on a transformer mannequin includes tests for impact of dangerous heat factors on protective equipment, and, when testing the transformer mannequin, its anthropometric parameters are changed for elimination of impact of factors of sizes of personal protective equipment on sensor readings, when determining their thermal-fireproof parameters.

EFFECT: increase in the accuracy, reliability, and information content of tests.

1 cl, 2 dwg

Description

The invention relates to the field of personal protective equipment and represents a method for determining the thermal fire-retardant characteristics of personal protective equipment for various categories of workers, including firefighters, and its technical implementation in the form of a test bench.

It is known that the level of safety of a person’s work and the degree of his protection when exposed to dangerous thermal factors of the surrounding working environment is determined, among other things, by the thermal and fire-protective characteristics of the personal protective equipment used (hereinafter referred to as PPE). Thermal factors include open flames and sparks, heat flow, elevated ambient temperature.

The characteristics that determine the thermal fire protection of PPE are the temperature (falling heat flux) and the time of the onset of thermal destruction of the PPE, leading to a malfunction of the product, the maximum allowable thermal parameters of the internal space of the PPE in direct contact with the human body (temperature of the internal space, passing heat flow) and the time to achieve them, the response of the human body working in PPE under various thermal effects.

The characteristics of thermal fire protection of PPE depend on the properties and relative position in a multilayer package of materials and fabrics used for the manufacture of PPE, air gaps between layers, the design of PPE, the distribution of its elements over the human body, according to size.

Tests of individual samples of structural materials and elements of PPE do not give a complete picture of all the characteristics of thermal fire protection of products. When conducting thermal tests of PPE with the involvement of testers, subjective evaluation factors are not excluded, due to the physical and psychological state of the tester, his professional training. In addition, it is not always possible to conduct such tests due to safety reasons, and it is also problematic to cover the entire size range of PPE.

In this regard, there is a practical need to obtain an objective assessment of PPE according to the characteristics of thermal fire protection with full-scale physical modeling of conditions as close as possible to the practical conditions of exposure to PPE by thermal factors, with the ability to control the characteristics of thermal fire protection of PPE by placing the structural elements of PPE in the working position on a specially equipped full-size manikin -transformer, which allows you to change its anthropometric parameters, as well as the position of the mannequin and its components relative to the sources of thermal exposure.

Known test benches (dummy systems) with various, including patented names - "Thermomen", "Pyroman", implementing a method for testing the fire retardant properties of fire clothing and equipment according to the requirements of ISO13506:2008. The stands include a full-size human mannequin suspended on a special rod or on special racks, made of non-combustible materials, with temperature (heat flow) sensors built into it and racks with nozzles located around the mannequin for exposing the mannequin to an open flame (1. ThePyroMan ^tm manikin - found via internet: URL: http://www.tx.ncsu.edu/tpacc/heat-and-flame-protection/pvroman.cfm: 2. The UCS Flame Manikin System - found via internet: URL: http:// www.ucsshoe.com/images/Flame Manikin System.pdf 3. "New-ton" Articulated Thermal Manikin - found online: URL: http://www.mtnw-usa.com/thermalsystem/pdf/Newton brochure.pdf; 4. New 13-zone "Simon" thermal manikin - found via internet: URL: http://www.mtnw-usa.com/thermalsystem/pdf/Thermal.Newsletter7.pdf).

And also: patents RU 2120813C1, 10/27/1998; RU 2121389, 11/10/1998; CN101881743, 11/10/2010; US 2023516, 12/10/1935; CN 202436648, 09/19/2012.

Known patents CN No. 101303339, G01N 25/00, G01N 33/36 (2006.01), published 2008.11.12.

Known installation for fire testing of breathing apparatus (European standard EN 137 "Protective respiratory device - a self-contained breathing apparatus of open circuit with compressed air with a full-face part. Requirements, testing, marking"). The dummy, which is part of the stand, is only the upper body of a person without arms and legs, its design allows testing only respiratory and eye protection. The disadvantage of the installation is the feature that it is designed to test personal protective equipment when exposed to only an open flame. The dummy is fixed on the platform. All this significantly reduces the test capabilities of the installation. Other disadvantages include the fact that all these devices use dummies, the variability of the sizes of which is not provided, i.e. their anthropometric parameters are unchanged, which does not allow in all cases to obtain accurate indicators of the parameters of protective clothing, because the readings of temperature sensors and heat flow sensors are distorted due to a possible discrepancy between the dimensions of the protective clothing and the dimensions of the mannequin (on a small size mannequin, protective clothing of large size is also folded at the locations of the heat flow sensors, sometimes increasing the thickness of the thermal insulation by several times and thereby underestimating the readings of the sensors. On a large mannequin wearing small protective clothing, the latter is stretched over the sleeves, abdomen, back, shoulder girdle, reducing the thickness of the protective layer, or even exposing parts of the body, which leads to an overestimation of the readings of the sensors.This also leads to a decrease in air gaps between layers of protection, which also changes the values of the passing heat flux and the readings of the sensors.

The closest analogue adopted for the prototype of the claimed technical solution is a dummy flame system for checking the thermal and fire-retardant characteristics of PPE when exposed to an open flame of burners on a moving dummy imitating a walking person (CN101881743, G01N 25/22 (2006.01), published 2010.11.10).

This method is carried out on a stand, which is a fire chamber, in the upper part of which there are guides with a pulley installed on them, connected to a rotating disk by a fixed bracket.

The rotating disc is connected to the dummy by another bracket. Burners are installed on both sides of the mannequin at the same distance, forming a corridor. The length of the corridor is equal to the length of the guides along which the dummy moves during the test.

This method has the following disadvantages:

- tests are carried out only when exposed to an open flame;

- fixing the dummy to the top track limits the capabilities of the test system;

- it is impossible to test head protection equipment, various types of personal respiratory and vision protection equipment (PPE);

- it is impossible to change the dimensions of the dummy for testing PPE of various designs and sizes.

The inventive method and device for checking the thermal fire-retardant characteristics of personal protective equipment eliminates these disadvantages.

The essence of the proposed method for determining the thermal fire-retardant characteristics of personal protective equipment, which are in the working position on the transforming dummy, by testing the impact of hazardous thermal factors on the protective equipment, and when testing the transforming dummy, its anthropometric parameters are changed to eliminate the influence of factors of the size of personal protective equipment on the readings of sensors when determining the parameters of their thermal fire protection.

The essence of the proposed device lies in the fact that in the device for determining the thermal and fire protection characteristics of personal protective equipment, containing a transforming mannequin, in which temperature and heat flow sensors are mounted, a system for automatic control and registration of the obtained parameters, the transforming mannequin has the ability to change anthropometric parameters in accordance with with the size of personal protective equipment, excluding the influence of factors of discrepancy between the dimensions of the mannequin and personal protective equipment, and also has the ability to change the location of the temperature and heat flow sensors to obtain information in the controlled parts of the body, while the replaceable elements of the mannequin with the sensors installed in them can be rotated at any angle in the plane of their rotation to change the location of the temperature and heat flow sensors, and - to test personal protective equipment for respiratory and vision organs.

The use of these methods and devices improves the accuracy, reliability and information content of the tests.

In FIG. 1 shows a test bench for testing the thermal fire-retardant characteristics of personal protective equipment, and Fig. 2 - dummy-transformer with changing anthropometric parameters.

The test bench (Fig. 1) is located in two rooms and consists of a test chamber 1 made of non-combustible materials, the dimensions of which allow the transforming dummy to be freely moved and experiments to be carried out under various environmental parameters and thermal effects, and an operator's room 2.

The rooms have a common wall with a viewing window 3 for visual observation of the experiment.

The test bench includes:

- transforming mannequin 4 with changing anthropometric parameters of a person, made of non-combustible materials with built-in temperature and heat flow sensors, mounted on a special rack 5 and moved automatically in the desired direction, and the arms and legs of the mannequin are hinged to the body, which allows you to give any position convenient for the experiment, and mounting the dummy on the stand allows you to put on it any types of PPE, including protection for hands, feet, head, respiratory organs and vision. Moreover, the transforming mannequin may have, for example, a frame on which replaceable elements are put on to select the parameters of the mannequin corresponding to a specific size of the human body, and the replaceable elements have, for example, holes for mounting temperature and heat flow sensors. By rotating the replaceable elements around its own axis, it is possible to produce the desired orientation and fixation of the sensor to obtain information in the desired part of the body. According to GOST R 53264-2009 “Fire fighting equipment. Special protective clothing for firefighters. General technical requirements. Test Methods.» the dimensions of various types of firefighters overalls, and therefore the height of the transforming mannequin should be 1580-1880 mm, with a chest volume of 960-1120 mm, and a head circumference of 560-620 mm, which should provide a set of interchangeable elements. All control mechanisms are fireproof;

- movable radiant thermal panels 6 with a height of at least 2 m to create an adjustable heat flow, having reflective screens in the side and upper parts, and heat-insulating pads on the back to reduce heat losses;

- four movable racks 7, each of which has two gas burners, the location of which can be changed in height and angle of inclination, with nozzles of a certain shape, with an electric ignition system and a system for regulating the intensity of supply to the flame dummy;

- ventilation system 8, including for creating convective flows of varying intensity in the surrounding working gas-air environment;

- height-adjustable portable racks 9 with temperature and heat flow sensors located on them to monitor the parameters of the surrounding working environment;

- integrated temperature and humidity sensors that allow determining the characteristics of thermal fire protection of PPE depending on the humidity of the environment, perspiration of a person, etc.;

- emergency extinguishing system 10 in case of emergency situations.

Operator room 2 contains: a control panel for a dummy, thermal panels, gas burners and an automatic registration and control system on a personal computer using a special program for obtaining data on the parameters of the working environment in the test chamber and the characteristics of thermal fire protection of PPE in tabular form, graphically and in the form of color information on the silhouette of a person, the time of the experiment.

Claims (1)

A method for determining the thermal and fire retardant characteristics of personal protective equipment in the working position on a transforming mannequin by testing the effects of hazardous thermal factors on protective equipment, characterized in that replaceable elements are preliminarily installed on the transforming mannequin and temperature sensors are installed in them and heat flow by rotating replaceable elements, orient the sensors in a given position, fix them relative to the transforming mannequin, act on the mannequin by means of thermal panels of gas burners to determine and remove the parameters of thermal fire protection of personal protective equipment, change the anthropological parameters of the transforming mannequin, the location of replaceable elements with sensors and repeat the removal of the parameters of thermal fire protection.

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