SU1532721A1 - Hydropneumatic compressed air accumulator - Google Patents

Abstract

The invention relates to mining, in particular to the design of compressed air installations for powering mining equipment. The goal is to increase the specific volume of the battery while reducing operating costs. The hydropneumatic accumulator includes a hydrocamera (GC) 1, part of which is made in the form of rising production, a pneumocamera (PC) 3, supply air duct / В / 5 and discharge B 7. The latter is equipped with heat insulator 9, and B 5 is made of heat conducting material, such as steel or aluminum, and is located in the cavity of the CC 1. In the last m. there is a hydraulic conduit 14 in contact with B 5. Water is poured into the PC 3 through HA 1. Compressed air is pumped in via B 5, the passage through which air is cooled to T of water in HA 1 with a decrease in volume. The compressed air supply from the PC 3 to the consumer is carried out according to B 7, in which the air is heated to T air in the barrel 8, increasing in volume. Additional cooling of compressed air injected into PC 3 is carried out by ensuring the circulation of cold water through a hydraulic conduit 14 in contact with B 5. 1 Cpf, 2 sludge.

Description

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The invention relates to mining, in particular, to designs of compressed air installations for powering mining equipment.

The purpose of the invention is to increase the specific volume of the battery while reducing operating costs.

FIG. 1 shows a hydropneumatic accumulator, vertical section; Fig 2 is a section A-A in FIG. one.

The hydropneumatic accumulator of compressed air consists of hydrocamera 1, passed in the rock massif, made in the form of rising outcrop, communicated by rebirth outflow 2 with pneumocamera 3 located below. Hydrocamera 1 is passed close to compressor station 4. The supply air duct 5 is located, which connects the compressor station 4 with the cavity of the pneumatic chamber 3. In the diverting gateway 6, there is an exhaust air duct 7, which connects the cavity of the pneumatic chamber 3 with the consumer and compressed air at the mining sites. Part of the air duct 7 is laid along the barrel 8, and in the area adjacent to the pneumatic chamber 3, the air duct 7 is equipped with a heat insulator 9. The exhaust air duct 7 is made of heat-conducting material, for example steel or aluminum. In pneumatic chamber 3, a retaining wall 10 of the retaining wall type is installed opposite the rising production side 2, followed by sealing web 11. To monitor the state of the web 11 between it and the web 10, water is poured, which by means of line 13 communicates with the cavity of the pneumatic chamber 3. In the rising generation of the Icamera 1, a hydraulic line 14 can be located, which is connected to a source of cold water. A line can be used as such a hydraulic line 14 technical water feed mining equipment. In the interval of the rising production of the hydraulic chamber 1, the hydraulic actuator 14 is brought into contact with the inlet air transport: first conductor 5 and outputted via jumper 15 and generation 16 into the trunk 8. Gndrokamera 1 measures the spreading valve 17.

Hydropneumatic battery works as follows.

Through the hydraulic chamber 1 in the pneumocamera 3 pour water. After that, pneumatic chamber 3 is supplied with compressed air from compressor station 4 through supply duct 5. Air, the passage through duct 5, is cooled to the water temperature of hydro chamber 1.

The expander 17 provides a constant heat exchange in the rising production of the hydraulic chamber 1. The air cooled in this way takes up less volume than in the initial state at the same pressure, which results in an increase in the specific volume of the hydroaccumulator. Additional air cooling is provided by running cold water circulating through the hydraulic line 14.

The compressed air is supplied by the consumer through the air duct 7. In the barrel 8, the compressed air is heated and its corresponding expansion, which ensures its consumption for technological needs.

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Claims (2)

1. Hydropneumatic accumulator of compressed air, including passed in the rock massif and communicating with each other hydrocamera and pneumocamera, located below the hydrocamera, supplying air duct, communicating with pneumocamera, and discharging air duct, connecting the pneumocamera with compressed air consumers, different the fact that, in order to increase the specific volume of the battery with a simultaneous decrease in operating costs, at least part of the hydrocamera is made in the form of rising production, while channeling systems in a portion adjacent to the pneumatic chamber is provided with a heat-torus and the inlet duct is made of a conductive thermally conductive material and positioned in the cavity generating the insurgent gidrokamery. 2. The accumulator according to claim 1, characterized in that it is provided with a hydraulic conductor in communication with a source of cold water and brought into contact with a supply air duct in the interval of a rising production of a hydro chamber. Aa eleven YU 12