SU1745966A1 - Device for ventilation of mining pits - Google Patents

Abstract

Use: for ventilation of deep quarries in the absence of solar activity. SUMMARY OF THE INVENTION: The device comprises a heat accumulator located outside the pit ventilation zone, a heat exchanger located inside the heat accumulator, a pipeline for supplying a heat transfer fluid to pumps, one end of which is connected to the heat exchanger and the other is located in the ventilation zone of the pit, the pit air suction pipeline , check valve and pipeline to remove groundwater. The heat accumulator is made in the form of a heat-insulated chamber in which a heat exchanger is installed with the formation of an air cavity, with one end of the pipe for suction of open-air air communicating with the air cavity of the heat accumulator, and the other end with the pit airing zone. A non-return valve is installed in the upper part of the heat accumulator, and a pipeline for the removal of groundwater is connected to the pipeline for supplying the coolant. 2 hp f-ly, 3 ill. (Ls

Description

The invention relates to the mining industry and is intended to ventilate deep quarries, mainly at negative air temperatures,

A device containing an open pond with a coolant in the form of ground water is known.

The closest in technical essence to the present invention is a pit aerating device comprising a heat accumulator located outside the pit aerating zone, a heat exchanger located inside the heat accumulator, a pipeline for supplying a heat transfer medium with pumps, one end of which is connected to the heat exchanger and the other is located in the area where the pit is ventilated. The heat exchanger is made in the form of channels

or pools with a coolant and provides for the heating of the latter by absorbing solar energy with a solar concentrator. The cavities of the heat accumulator are formed with the help of reinforced concrete pipes located in rock dumps.

The known device has a number of disadvantages. Due to the high heat capacity of humid air at a negative temperature of atmospheric air, the flow of coolant down to the pit ventilation zone does not allow for its good ventilation. The implementation of the known device requires a considerable amount of accumulated heat transfer fluid stored for a long time in the cavity of the heat accumulator, and the generation of heat energy during the absence of a salt.

Sec o

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This activity is excluded due to the loss of accumulated heat.

When the heat carrier is pumped down to the ventilation zone, a portion of the heat carrier heat is lost through the pipeline.

The purpose of the invention is to increase the efficiency of pit ventilation during the period of no solar activity due to the use of the heat of groundwater.

The goal is achieved by the fact that a known device for ventilating a pit, including a heat accumulator, located outside the pit ventilation zone, a heat exchanger, located inside the heat accumulator, a pipeline for supplying a coolant with pumps, one end of which is connected to the heat exchanger and the other is located in the zone pit ventilation, equipped with a pipeline for suction of open-air air, a check valve and a pipeline to remove groundwater, and the heat accumulator is made in the form of heat A heat exchanger with an air cavity is installed in this case, with one end of the pit air suction pipe connected to the heat accumulator air cavity, and the other end connected to the pit ventilation zone, the check valve is installed in the upper part of the heat accumulator, and the removal of groundwater is connected to the pipeline for the supply of coolant.

Moreover, the pipeline for suction of open-pit air may be placed inside the pipeline for supplying coolant, or the pipeline for supplying coolant may be placed inside the pipeline for suction of open-pit air.

FIG. 1 shows a device for ventilating a pit, general view; in fig. 2 shows the layout of the pipeline for suction of the open-air air inside the pipeline for supplying the coolant; in fig. 3 shows the layout of the pipeline for supplying coolant inside the pipeline for sucking open air.

A heat accumulator 2 is installed on the surface of the ground, outside the zone of airing pit 1, which is a sealed heat-insulated chamber in which a heat exchanger 3 is installed with the formation of an air cavity.

The heat exchanger 3 is connected on one side to the pipeline 4 for supplying the heat transfer fluid communicated with the pipeline

to remove groundwater from the pit (not indicated), and on the other hand to pipeline 5 to drain groundwater from heat exchanger 3 to the reservoir behind the pit’s contour

1. In addition, the device is equipped with a pipe 6 for suction of open-air air, one end of which is connected to the ventilation zone of pit 1 and the other to the air cavity of the heat accumulator 2. B

0, the upper part of the heat accumulator 2 has a check valve 7. The pipelines for supplying 4 and discharging 5 heat carrier - ground water - are equipped with pumps 8. At that, pipeline 6 for suction of the quarry

5 air can be placed either inside or outside the pipeline 4 for supplying the coolant.

A device for aerating the pit operates as follows.

0 Groundwater accumulating on

pit 1 is removed through a pipeline to remove the groundwater to which the pipeline 4 is connected to supply the coolant — groundwater iodine — and with

5 of the pump 8, it is supplied to the capacity of the heat exchanger 3, from where the coolant is then removed by means of the pump 8 via a pipeline 5 for draining groundwater into the reservoir. The groundwater passing through the heat exchanger 3, through the walls of the tank, heats the air in the air cavity of the heat accumulator 2, which then accumulates in its upper part due to its lower specific gravity as compared to the cooler air.

Making the heat accumulator 2 in the form of a sealed and thermally insulated chamber makes it possible to reduce the loss of thermal energy. When a threatened career occurs, the check valve 7 is opened and the warm air from the air cavity of the heat accumulator 2 rushes into the atmosphere, and a vacuum is created in the air cavity of the heat accumulator, causing the contaminated air to leak from the airing zone of pit 1 conduit 6 for exhaust air suction. The check valve 7 is closed and the cycle is repeated,

0

In that case, if the pipeline 6 for suction of open-air air is placed inside the pipeline 4 for supplying heat-transfer agent or vice versa, pipeline 4 for supplying

5, the coolant will be placed inside the pipeline 6 for the suction of the open air (Figs. 2 and 3), then during the supply of groundwater to the heat exchanger 3, the air inside the pipeline 6 for the exhaust of the open air will be heated and

by convective flow enter the air cavity of the heat accumulator 2.

The heat accumulator 2 together with the heat exchanger 3 can be placed in the ground, in addition, a body of water into which ground water is discharged can be used as the heat exchanger 3. This reduces the construction costs of the proposed device.

Claims (3)

Claim 1. Device for pit ventilation, including heat accumulator, located outside pit ventilation zone, heat exchanger, located inside heat accumulator, heat transfer pipe with pumps, one end of which is connected to the heat exchanger and the other is located in the pit ventilation zone, characterized in that, in order to increase the efficiency of pit ventilation during the period of no solar activity due to the use of the heat of groundwater, five 0 The equipment is equipped with a pit air suction pipeline, a check valve and a groundwater removal pipeline, and the heat accumulator is in the form of a heat-insulated sealed chamber in which a heat exchanger is installed to form an air cavity, with one end of the career air suction pipe connected to the air cavity the heat accumulator and the other with the pit aeration zone, a check valve is installed in the upper part of the heat accumulator, and a pipeline to remove the groundwater in d communicates with the conduit for supplying heat transfer fluid 2. The device according to claim 1, characterized in that the pipeline for suction of career air is placed inside the pipeline for supplying the coolant. 3. The device according to claim 1, characterized in that the pipeline for supplying the coolant is placed inside the pipeline for sucking open-air air. ,  2 FIG. 3