RU63447U1 - DEVICE FOR RADON REMOVAL FROM RAILWAY TUNNEL - Google Patents

Abstract

A device for removing radon from a railway tunnel containing a recessed vestibule, a platform with a tray, a ventilation shaft, characterized in that the tray is closed with sets of floor slabs, including plates with an air intake, a visor towards the air flow, several plates without peaks, a closing plate with an air intake with a visor along the flow of air. The air intake is a plate on which a visor is located on the edge of the plate, and has, for example, an oval shape and the angle of inclination of the air intake to the plate at least 30 degrees.

Description

A utility model relates to a device for removing radon from long-distance railway tunnels in which effective ventilation is not provided naturally.

A known method of protection against radon emissions of a coal seam (1).

The essence of protection against radon emissions is that from the field preparatory and local crossholes to the approach of the lava, the fans of the wells are drilled into the side rocks with the faces of the holes staggered out to the soil of the formation in the area of the conveyor cut, while the fans of the wells are located on both sides production, and from a field drift only on the side of the coal seam, after which, in one row, air is blown into the holes to support the coal seam, and radon is sucked out of the other row.

When the lava approaches 3-5 meters to the bottom of the wells, ventilate the formation through cracks in the maximum extraction zone and supply air through the wells to the bottomhole space until the lava approaches. When gas is sucked out, cloth filters are installed at the beginning of the wells to trap particles of radon decay and their subsequent burial.

It is not possible to use this method, since it will be necessary to drill a large number of wells and install fabric filters to block radon decay particles, which will require significant costs.

A known method of limiting the flow of radon into mine workings (2).

This method includes drilling wells in mine workings in the surrounding rock mass and pumping radon through the wells.

In the near-well part of the well, pressure is created and maintained in excess of the pressure in the wellbore.

Removing radon in a railway tunnel according to the proposed method will require drilling a large number of wells, creating and maintaining pressures in excess of the pressure in the wellbore, which will require significant costs.

The closest analogue is the ventilation method of a dead end subway station (3).

The proposed method includes moving air flows under the influence of a moving electric train and supplying fresh air to the passenger platform of the station through the ventilation shaft.

Moreover, when the electric train approaches the station, the mine’s ventilation valve is closed, and all the warm exhaust air is vented into the atmosphere through the lobby, and when the electric train leaves the dead-end station, part of the fresh air to the station’s passenger platform is supplied through the ventilation shaft by opening the ventilation valve, and part through the lobby .

It is known that the water entering the tunnel from the drainage system contains radon, which is released from the water and accumulates in the lower layers of the air and in the trays of the tunnel.

The existing ventilation system is not designed to extract the accumulated radon in the air space close to the tray, so using this ventilation method in a railway tunnel does not remove radon, since radon is heavier than air and accumulates in the lower layers of air.

The objective of the proposed device is the removal of radon from the railway tunnel at the lowest cost.

The problem is solved by the fact that the proposed device for removing radon from the railway tunnel, containing a recessed lobby, a platform with trays and plates for swelling water,

ventilation shaft characterized in that the tray is closed with a set of floor slabs, including plates with an air intake, a visor towards the air flow, several plates without visors, a closing plate with an air intake with a visor along the air stream.

The essence is illustrated by drawings.

In figure 1. General scheme of a tray with floor slabs in a railway tunnel.

In figure 2. The cross section of the air intake is 1-1.

In figure 3. The intake cross section along the flow in 2-2.

Figure 1 shows: tray 1, above it there is a floor slab 2, which has an inlet air inlet 3, through several plates without air inlets there is a floor slab 2 with an exhaust air inlet 4.

The air intake 1 is a floor slab 2, on which there is a visor on the front of the plate. In the cross section, the visor has, for example, an oval section, in a longitudinal section, the angle of inclination to the plate 2 is at least 30 degrees.

Figure 2 shows in cross section the shape of the air intake 3.

Figure 3 shows the angle of inclination of the air intake 3 with respect to the slab 2.

The removal of radon is as follows.

The train, when driving in a single-track tunnel, compresses the air in front of itself, forms a strong air stream along the walls of the tunnel.

Part of the air flow is captured by the air intakes 3.

The air stream entering the tray 1 captures the accumulated radon, mixes with it, passes through the tray 1 and leaves through another air intake 4 forming turbulence when leaving the tray in the tunnel. In a tunnel, a turbulent air stream with radon is captured by existing ventilation and emitted into the atmosphere. Radon removal is ensured by the fact that the air sucked out by the system as a result of turbulence increases

the concentration of radon, taking in the radon that has accumulated in the space of the tray system.

Studies conducted on models have shown high efficiency in removing radon from a railway tunnel.

Literature:

1. RF patent №2116444, IPC E 21 C 41/18, priority date 07/18/1997

2. RF patent №2121062, IPC E 21 F 7/00, priority date 04/15/1997

3. RF patent No. 2278268, IPC E 21 F 1/00, priority date 06/23/2004

Claims (2)

1. Device for removing radon from a railway tunnel, containing a recessed vestibule, platforms with a tray, a ventilation shaft, characterized in that the tray is closed with a set of floor slabs, including plates with an air intake, a visor towards the air flow, several plates without peaks, while the closing plate with an air intake with a visor along the air flow. 2. The device according to claim 1, characterized in that the air inlet in the form of a visor is located on the edge of the plate and has, in cross section, for example, an oval shape, the angle of inclination of the air inlet visor to the plate is at least 30 ° C.