RU2112144C1 - Rescue gear - Google Patents

Abstract

FIELD: mining industry, rescue of miners and other personnel subjected to action of poison and harmful substances. SUBSTANCE: proposed rescue gear includes isolated chamber for people and system supplying air into it. Chamber is formed in the thick of salt rock, has perforated floor with filter-saturator in the form of layer of crushed salt rock and communicates through holes in floor with box of air preparation. In addition chamber has platform for accommodation of people positioned with clearance with respect to surface of floor and side walls of chamber. EFFECT: rescue gear facilitates saturation of air with clusters and absorption of gas and perspiration release of people. 1 dwg

Description

 The invention relates to mining and the satisfaction of human needs and can be used as a rescue device for miners and other persons exposed to toxic and harmful substances, as well as people who are in a state of "imaginary" death.

 Shelter chambers are known [1], and a gas protection device for miners is also known [2].

 A disadvantage of the known devices is that they do not ensure the creation and maintenance for a predetermined period of time of the qualitative characteristics of the gas environment inside the room in which people are located, in terms of maintaining the required level of content of electrically charged light air ions, as well as the inability to prevent exposure to respiratory products decay of heavy radioactive gases.

 The present invention is aimed at solving the problem of creating and maintaining in a rescue device full air of physico-chemical characteristics, ensuring the preservation and rehabilitation of human health.

The solution to this problem is mediated by a new technical result, which consists in generating in a rescue device electrically charged clusters ranging in size from 2.5 • 10 ^-4 to 6 • 10 ^-3 microns, capable of precipitating in the respiratory tract and exerting a restorative and preventive effect both due to directly into the bloodstream of the vital ions of mineral salts (K, Na, Mg, Cl), as well as the transfer of electric charge, as well as in the placement of people in the chamber with a stable nature of the flow of mass processes and outside the zone of accumulation of heavy radioactive gases.

где
H - высота палаты, м;
δ - максимальная ширина отверстия в полу палаты, м;
величина зазора между платформой и боковыми стенами палаты составляет не менее
В = 0,1 L,
где
L - длина палаты, м;
а отношение площади, занятой платформой, к площади палаты составляет не более 0,65.Salient features of the claimed technical solution: restrictive - the rescue device contains an isolated chamber for accommodating people and a system for supplying air into the chamber; distinctive - the isolated chamber is formed in the thickness of the salt rocks, is equipped with a perforated floor with a filter-saturator in the form of crushed salt rock and communicated through holes in the floor with an air preparation box, while the chamber has a platform for accommodating people with a gap relative to the floor surface and side walls chambers, the gap between the platform and the floor is at least

Where
H - chamber height, m;
δ is the maximum width of the hole in the floor of the chamber, m;
the gap between the platform and the side walls of the chamber is not less
B = 0.1 L,
Where
L is the length of the chamber, m;
and the ratio of the area occupied by the platform to the area of the chamber is not more than 0.65.

 The drawing shows a rescue device V.A. Startseva.

где
H - высота палаты, м;
δ - максимальная ширина отверстий в полу 3 палаты 1, м;
величина зазора между платформой 5 и боковыми стенами палаты 1 составляет не менее
В = 0,1L,
где
L - длина палаты 1, м,
а отношение площади, занятой платформой 5, к площади палаты 1 составляет не более 0,65.The rescue device of V. A. Startsev contains an isolated chamber 1 for accommodating people formed in the thickness of salt rocks 2. Chamber 1 is equipped with a perforated floor 3 with a filter filter 4 in the form of crushed salt, platform 5 with sunbeds 6 for accommodating people. The platform 5 is located with a gap relative to the surface of the floor 3 and the side walls of the chamber 1. Moreover, the gap between the platform 5 and the floor 3 is not less than

Where
H - chamber height, m;
δ is the maximum width of the holes in the floor 3 of the chamber 1, m;
the gap between the platform 5 and the side walls of the chamber 1 is not less than
B = 0.1L,
Where
L - the length of the chamber 1, m,
and the ratio of the area occupied by platform 5 to the area of chamber 1 is not more than 0.65.

 The chamber 1 comprises an inlet channel 7 and, through openings in the floor 3, channels 8, 9, 10, 11 and a fan 12, is connected to an air preparation box 13 provided with an inlet channel 14.

 When operating the rescue device V.A. Startsev's people are placed in an isolated ward 1 on sunbeds 6.

 Microclimatic parameters and the material composition of the air in the chamber 1 is supported as follows.

 1. In the presence of an external source of constant "power" of the rescue device - fresh air-conditioned air. Fresh conditioned air through the inlet channel 14 passes into the air preparation box 13 and, using the fan 12 through the channels 11, 10, 9, 8, through the openings in the perforated floor 3 and the salt filter-saturator 4 enters the chamber 1. When air passes through the filter Saturation 4 is cleaned from dust and allergens and saturated with electrically charged salt clusters. The air passing through filter saturator 4 is mixed with the air of chamber 1 and is used to breathe people placed in chamber 1. Excess air, together with respiratory waste from people, exits outside chamber 1 through outlet channel 7.

 2. If there is an external source of "power" of the rescue device - fresh, but not air-conditioned air.

 Fresh air through the inlet channel 14 enters the air preparation box 13, where an air conditioning operation is performed using an air conditioner (not shown in the drawing) and through a channel 12 through channels 11, 10, 9, 8, through holes in a perforated floor 3 and a salt filter - satifier 4 enters chamber 1, mixes with the air of chamber 1 and is used to breathe people placed in chamber 1. Excess air, along with respiratory waste from people, exits outside chamber 1 through outlet channel 7.

 3. In the absence of an external source of constant “power” to the rescue device — fresh air and the implementation of exhaust air regeneration.

 The output channel 7 is aerodynamically connected to the input channel 14, in the air preparation box 13 there is a regeneration unit (not shown), including a compressed oxygen cylinder, cartridges with a chemical absorber of carbon dioxide, cartridges with an air dryer. As the fan 12, a manual or combination fan is used. The ventilation of the chamber 1 is carried out in recirculation mode with the regeneration of exhaust air. The exhaust air from the chamber 1 is discharged through the outlet channel 7 and through the inlet channel 14 enters the air preparation box 13, where it is conditioned: dehumidification, absorption of carbon dioxide and oxygen saturation. Air conditioning using fan 12 through channels 11, 10, 9, 8, through openings in the floor 3 and a salt filter-filter 4 enters chamber 1, mixes with the air in chamber 1, and is used to breathe people placed in chamber 1. Excess air together with the respiratory waste of people through the outlet channel 7 and the inlet channel 14 enters the air preparation box 13.

 4. In the absence of an external source of constant “power” to the rescue device — fresh air and the use of accumulated conditioned air.

 The output channel 7 is aerodynamically associated with the beginning of the tank (not shown), which accumulates conditioned air, and the end of the tank with the input channel 14.

 Excess (exhaust) air from the chamber 1 is discharged through the outlet channel 7 to the beginning of the container that accumulates the conditioned air, is mixed with the latter and through the inlet channel 14 enters the air preparation box 13, from where, using the fan 12 through the channels 11, 10, 9, 8 , through the holes in the perforated floor 3 and the salt filter saturator 4 enters the chamber 1, mixes with the air of the chamber 1 and is used to breathe people placed in the chamber 1.

 Excess air together with respiratory waste of people through the outlet channel 7 enters the tank of accumulated air and mixes with it. From the tank, the air mixture passes through the inlet channel 14 into the air preparation box 13.

 Example.

In a potash mine, in a salt stratum, represented by sylvinite rock, composed of water-soluble minerals: sylvine (KCl) and halite (NaCl), a PK-8 miner passed a mine working - an isolated chamber 1 with a section of 9.8 m ² and a length of 30 m, which through the vestibule is connected to a 600 m ³ accumulated mine working in air-conditioned air, passed in the thickness of salt rocks, which through the vestibule is connected to an air preparation box 13 with a volume of 50 m ³ . Mining - chamber 1 through a hole 7 with a diameter of 80 mm is aerodynamically connected to the beginning of the accumulating mining, and the air preparation box 13 through the hole 14 with a diameter of 80 mm is aerodynamically connected to the end of the accumulating mining and through channels 11, 10, bore 9, channel 8, holes in the floor 3 - with a hole - chamber 1. Perforated floor 3 is placed at a distance of 200 mm from the soil of the excavation - chamber 1 and is made of grate fenders with a hole size of 1 mm. A layer of crushed sylvinite rock (pieces 40–60 mm in size) 100–150 mm thick is placed on floor 3. At a height of 400 mm from floor 3 with a gap relative to the walls of chamber 1, a platform 5 with a width of 2.2 m and a length of 28 m was mounted. On platform 5 there are 10 sunbeds 6 for rescued people. In the air preparation box 13, a combined fan 12 is mounted with a capacity of up to 10 m ³ per hour of air, which is aerodynamically connected for injection to the channel 11.

 The results of the production experiment and calculations show that when using the rescue device, V.A. Startseva in the specified design provides an autonomous life stay of 10 people for four days. This is facilitated by the saturation of the air supplied for the breathing of people with salt electrically charged clusters and the ability of the salt surfaces enclosing the mine - chamber 1, which accumulates the mine and the air preparation box 13 to absorb respiratory waste, gas and moisture from people.

Claims (1)

A rescue device containing an isolated chamber for accommodating people and a system for supplying air inside the chamber, characterized in that the isolated chamber is formed in the thickness of salt rocks, equipped with a perforated floor with a filter filter in the form of crushed salt rock and communicated through the holes in the floor with the preparation box air, while the chamber has a platform for accommodating people with a gap relative to the floor surface and the side walls of the chamber, the gap between the platform and the floor is not less than her

where H is the height of the chamber, m;
δ is the maximum width of the hole in the floor of the chamber, m,
the gap between the platform and the side walls of the chamber is not less
B = 0.1 L,
where L is the length of the chamber, m,
and the ratio of the area occupied by the platform to the area of the chamber is not more than 0.65.