RU2619577C2 - Personnel collective rescue station - Google Patents

Abstract

FIELD: rescue work.

SUBSTANCE: personnel collective rescue station consists of an air lock, a air lock chamber, a rescue chamber with explosion-proof sealed doors and overpressure valves protected by anti-explosion sections, of a ventilation system and stand-alone power supply. The feature is that the rescue station is installed in mines which are secured with reinforced supports of non-combustible materials and the explosion-proof sealed doors are installed in reinforced coal-cutting explosion-proof stoppings. The air flow is blown by a fan into the rescue chamber through a well drilled down from the surface. The rescue chamber is equipped with fixed drinking water tanks, sanitary facilities and automatic control equipment for air and gas protection. The rescue chamber has everything, which is necessary to maintain the personnel life, fire fighting equipment, a required storage of self-rescuers and respirators.

EFFECT: creation of a personnel collective rescue station, ensuring the people's safety during the period of rescue operations by replenishing the lack of oxygen in the air, ensuring fire and explosion safety.

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Description

The invention relates to mining, and in particular to means for ensuring the safety of people in the event of a life-threatening situation in the mine workings and the creation of an environment unsuitable for breathing.

To increase safety, a multi-stage self-rescue system is being introduced at the mines, which takes into account the variety of conditions for developing coal deposits and the location of miners' jobs. This system provides for the use in the mines of switching points to self-rescuers (hereinafter PPS) and collective rescue points (PCPS).

A well-known point of collective salvation of personnel (patent No. 149235, application No. 2014118166/03, priority date 05/05/2014, publication date 12/27/2014, bull. 36). A well-known item consists of a movable rigid frame sealed enclosure equipped with an explosion-proof sealed door, divided into a vestibule gateway and a inhabited compartment with a sealed bulkhead with a sealed door and an overpressure valve between the vestibule gateway and the inhabited compartment, and the vestibule gateway contains a secure entrance system including an intermediate a chamber, at the entrance and exit of which there are strip curtains and an air conditioning system, autonomous energy supply systems are installed in the housing, in an intermediate chamber has high-pressure air nozzles connected to a balloon ramp and to an external pneumatic network. The air conditioning system includes regenerative cartridges, an air filtering system including a filter of harmful impurities, and a cooling system further comprising a water tank connected to the air heater.

A disadvantage of the known technical solution is that the regenerative cartridges used cannot retain dust particles and products of human metabolism, and cannot provide a long two-, three-day existence of people. In addition, air regeneration is accompanied by an increase in its temperature.

The technical result of the invention is the creation of a collective rescue center for personnel, ensuring the safe stay of people during the rescue period by replenishing the lack of oxygen in the air, ensuring fire and explosion safety.

A collective rescue center for personnel (abbreviated PCSP) is proposed, consisting of a vestibule-lock, airlock, a rescue chamber, with explosion-proof sealed doors and overpressure valves protected by explosion-proof sections, a ventilation system and autonomous power supply. The difference is that the point is equipped in mine workings, which are fastened with reinforced support made of non-combustible materials, explosion-proof sealed doors are installed in the cut reinforced explosion-proof jumpers separating the vestibule-lock, lock chamber, rescue chamber, and the air supply is pumped by the fan into the rescue chamber through the well drilled from the surface, the rescue chamber is equipped with stationary tanks for drinking water, sanitary units and equipment for automatic control of air and gas protection, chambers and rescue is equipped with everything necessary to support the life of the staff, fire fighting equipment, the necessary supply of self-rescuers and respirators.

The mine workings, which are adapted for PCSS, as well as emergency exits to the surface, must be stable under the joint action of seismic blast waves and static loads from rock pressure, the strength characteristics of the rock formations where PKSS are located should be sufficient to ensure the stability of the structure throughout the entire period PCPP operation.

Excavations equipped under the PCSP should be fixed with a support made of non-combustible materials. If necessary, thermal insulation should be built in the PCP to protect people from both high and low temperatures, and should not be flooded by mine and surface water and contaminated with harmful gases during the specified period of use of these workings.

The invention is shown in FIG. 1 where a general diagram of the device for a collective rescue center is shown; FIG. 2 is a general view of a utility model; FIG. Figure 3 shows three options for locating a collective rescue center for personnel in mine workings and shows the structural elements of a utility model. In FIG. 1 the vestibule gateway is designated 1, the lock chamber is shown 2, the rescue chamber is 3. The tambour gateway 1, the lock chamber 2, the rescue chamber 3 are separated by explosion-proof jumpers 4, in which there are sealed doors 5. Explosion-proof jumpers are constructed from materials intended for the construction of explosion-proof lintels (Teckland, Elblend, Concrete, etc.). Cutting of cuts in the development for jumpers should be provided, as a rule, mechanically. To increase the adhesion of the bridge with the rocks, as well as in case of exceeding the calculated values of the pressure in the front of the shock wave, a reinforcement of the bridge is provided. The reinforcement of the jumper 4 is made by installing horizontal and vertical metal beams from a special interchangeable profile, anchored in the production office. The minimum thickness of the cutting bridge is taken equal to the maximum value of the two calculated values of h ₁ and h ₂ , where:

h ₁ - the thickness of the jumper plate, providing its bending strength under the action of equivalent pressure, m;

h ₂ is the thickness of the jumper plate, ensuring the strength of the cutting part of the jumper on the cut, m

The thickness h ₁ , m, providing bending strength of the plate of a monolithic bridge is calculated by the formulas:

- for b <a

- for b> a

where a is the width of the mine, m;

b - working height, m;

ΔР _e - quasistatic load equivalent to the pressure of reflection, MPa;

R _pact is the standard resistance of the material used to erect the lintel to tensile bending for the Teckland cement mixture, _Rpast = 2.0 MPa;

k _s - safety factor for the jumper material varies from 0.8 to 1.0 and is accepted by the project k _z = 1.0.

The thickness of the lintel plate, ensuring the strength of its cutting part to cut h ₂ , m, is determined by the formulas:

h ₂ = ΔP _e ⋅a⋅b / (2⋅ (a + b) ⋅R _sdv ),

wherein R _sh - regulatory resistance of the material used for the construction of bridges, the shear is determined from the expression R = 0,24R _{Sliding compression channel,} MPa

where R _sz - the standard resistance of the material used to erect the jumper for compression, for the Teckland cement mixture, R _sr = 7.5 MPa.

Protective-tight and hermetic doors 5 are designed to protect the collective rescue team from the penetration of shock waves and harmful mine gases. Therefore, the signs ensure the safety of people and are in a causal relationship with the claimed technical result.

The project provides for the use of commercially available doors DU-1-7, designed for use in civil defense shelters of the 1st class, as protective-tight doors. Doors of the selected type are the most powerful of the security doors commercially available by the domestic industry.

The main elements of the doors are the canvas, the box and the mechanism of closing. The canvas is a metal structure consisting of sheet and profile rolled products and serves to close the opening. The door frame (coaming) is a frame welded from profile steel, which serves to transfer the calculated load from the canvas to the building envelope and to seal the opening. The closing mechanism is designed to lock the door and seal the opening, i.e. tight connection. The closing mechanism is located on the inside of the door, includes a bevel gear, screw rods with wedges and two steering wheels (handles). When turning the helm, the locking wedges of the shutter press the canvas against the box. Tightness is ensured by a special sealant made of porous rubber located around the perimeter of the canvas. In this way, explosion and fire safety and reliable protection of personnel are ensured during a life-threatening situation. The sign is in a causal relationship with the claimed technical result.

The air supply system to the rescue chamber includes:

- a fan for supplying the required amount of air (not shown);

- an air heater for heating the supplied air in the cold season (not shown);

- a rigid air supply pipe from the fan;

- a well drilled in a shelter from the surface.

For mine conditions, as applied to the three options for placing the PCP in the mine workings shown in FIG. 3. Option 1 placement of the PCP in a specially mined mine is the most preferable for the claimed utility model. Option 2 shows the placement of the PCP in a fault between two workings. In the implementation of option 3, the construction of a longer explosion-proof jumper is required, which will require additional costs.

There are four possible options for airing the PCP:

- providing shelter with compressed air;

- providing shelter with air regeneration systems;

- ventilation in the mode of filtration and ventilation units with air taken from the mine workings;

- ventilation through a well drilled from the surface (shown in Fig. 1).

When airing with compressed air, it requires preliminary cleaning of oil inclusions and condensate with a special oil and water separator installed on the exhaust valve of the pneumatic pipeline, and also, in order to exclude damage to the pneumatic pipeline from destruction of the shock wave, it must be placed in pits. To ensure uniform distribution, it is necessary to use dividers in the form of a perforated pipe, laid along the PCB floor. To reduce the noise level created by compressed air when it exits the pipeline, it is necessary to install a receiver or other sound-absorbing device. These shortcomings make the use of this method unacceptable under given conditions.

PCSP air supply in clean ventilation mode using regenerative units is performed using regenerative cartridges containing chemical absorbers that purify the air in the following order (general order): compressed oxygen is supplied to the ejector and extracts the previously purified air, enriching it with oxygen, making it suitable for breathing. This ensures uniform distribution of oxygen-enriched air throughout the PCSS. When airing the PCPS with the help of filter ventilation units, mine air is used, which is sucked in by the fan and is cleaned of harmful impurities before passing it to the PCPS when it passes through multilayer filters. The disadvantage of this method of ventilation (as indicated above) is its unsuitability in cases where the concentration of oxygen in the mine air decreases or is completely absent.

Aeration of the PCB through the well (most suitable for the claimed utility model) drilled from the surface is shown in FIG. 1, and air is supplied by a fan (1 operating and 1 standby not shown) installed in a surface modular building. To ensure uniform distribution, dividers are used in the form of a perforated pipe laid along the PCB floor. Also, the well will be an independent guaranteed source of air supply from the surface, which will provide unlimited time to save the rescuers and wait for the personnel, and, if necessary, the appropriate diameter of the well to evacuate through it to the surface. In this case, the sign provides a guaranteed supply of fresh air and is in a causal relationship with the claimed technical result.

The surface building of the collective rescue center for personnel 6 is located on the surface and there is a fan (not shown) in it, which pumps air through the borehole into the rescue chamber 3, where excessive pressure is created. The well is an independent guaranteed source of air supply from the surface, which provides the necessary time to save the rescuers and for personnel to wait, and, if necessary, the appropriate diameter of the well to evacuate people through it to the surface. The generated excess pressure from the air in the rescue chamber contributes to the displacement of contaminated air during the entire operation period, including during periodic filling by people. The passage of people sheltering in a shelter in a polluted atmosphere is provided by the air stream coming from the shelter (under normal ventilation conditions). This increases ventilation and the flow of clean air. The sign is in a causal relationship with the claimed technical result.

Overpressure valves 7 are designed to automatically maintain a constant overpressure in adjacent rooms and to ensure that air flows from one room to another in only one direction. The valve 7 is activated (opens) due to the amplification created by excess pressure on the surface of the plate and is installed in a room with high pressure. After equalization of the set value of the differential pressure, as well as with an increase in pressure behind the valve, it closes under the action of gravity or pressure.

Valves can be made in two modifications:

- usual execution;

- anticorrosive stainless steel design.

Can be used, for example, valves brand KID-100.01-500.01. As the material of the sealing gaskets, heat-frost-acid-alkali-resistant rubber is used.

The collective rescue team provides autonomous power supply (not shown in Fig. 1). Power supply to each underground collective rescue station is provided from the surface module building of the PSCP further along the cable channels of the well drilled from the surface. Power supply and lighting must comply with the "Rules for the installation of electrical installations" and the "Rules of safety in coal mines." The modular building, in turn, is provided with a working and backup external power supply.

In stationary lighting, in case of stationary lighting, to ensure the evacuation of sheltering people, if necessary, you can use portable lamps for individual use at the rate of one lamp for ten concealed and taking into account ten percent stock. For example, you can use lamps for individual use SMG V.1A.003.01.05.

The present invention is intended to accommodate the maximum number of personnel (shift changes); containers for storing drinking water supplies; food warehouse; equipment of sanitary facilities; medical points (sanitary posts); fire fighting equipment; personal protective equipment; places for sitting and lying down of personnel, as well as areas for placing the control center of the facility and ventilation equipment on the surface (surface building of the PCP).

Additionally, PCPs are equipped with fire extinguishers, a set of medicines and products.

Collective rescue centers provide for the creation of a supply of drinking water. For this, stationary tanks for storing water (not shown) are used. Tanks are intended for storage of emergency stock of drinking and industrial water. These tanks are made in the form of vertical sections of rectangular cross-section, the number of sections depends on the required tank capacity, it is allowed to collect no more than 5 sections in the tank. The tanks are equipped with nozzles for connecting water level indicators, for supplying and discharging water, and the tanks are equipped with caps on the upper part for inspecting and cleaning the tanks. A stock of drinking water is created at the rate of 2 liters per day for one shelter.

Sanitary units (not shown) are equipped with tanks at the rate of taking 2 liters of feces per shelter per day.

The collective rescue station will provide reliable protection for people in an emergency situation in the mine and the possibility of their existence for a certain period before their evacuation.

The industrial applicability of the invention is proved in its practical implementation in the mining industry. The authors developed technical documentation for the technical re-equipment of the Kuznetsk coal basin mine in terms of equipping the mine workings with collective rescue points.

Claims (1)

The collective rescue center for personnel, consisting of a vestibule lock, airlock chamber, a rescue chamber equipped with explosion-proof sealed doors and overpressure valves, protected by explosion-proof sections, ventilation systems and autonomous power supply, characterized in that the station is equipped directly in the mine workings, which are fixed by reinforced lining made of non-combustible materials, and the explosion-proof tight doors are installed in the reinforced flameproof jumpers, air supply to Neta blower saving chamber through hole drilled from the surface, rescue camera equipped with stationary tanks for drinking water, sanitary nodes and automatic control equipment aerogas protection.

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