RU113541U1 - COMPRESSOR STATION - Google Patents

Abstract

The inventive utility model relates to the field of engineering, and in particular to installations for producing compressed gas. EFFECT: increased efficiency of the liquid cooling system of the compressor of the compressor station, while reducing noise and vibration levels produced by the aforementioned cooling system. The compressor station comprises a power drive (1), a reciprocating compressor (2) and a liquid cooling system for the reciprocating compressor (2) comprising a radiator (4) and a fan (6). In this case, the fan (6) is made axial, and the impeller of the fan (6) is made of fiberglass.

14 cp, 1 ill.

Description

To application No. 2011140502/06

Compressor station

The field of technology.

The inventive utility model relates to the field of engineering, and in particular to installations for producing compressed gas. The inventive compressor station is used in the production of development and repair of oil wells, supply of compressed gas as an energy source for technological processes, repair and testing of pipelines, supplying compressed gas to a pneumatic tool and other purposes in various industries.

The prior art.

Among compressor stations, for example, a compressor unit is known, comprising a compressor with a drive motor and a cooling unit. The cooling unit is made in the form of a centrifugal fan mounted on the compressor shaft, a heat exchanger, and at least two ventilation grilles formed in the housing. (RU87126U, 2009)

The disadvantage of this analogue is the low efficiency of the centrifugal fan of the cooling unit. This leads to a decrease in the cooling efficiency of the heat exchanger and, as a consequence, a decrease in the efficiency of the cooling unit.

A gas filling station is also known, comprising an engine compartment and a compressor compartment, wherein an engine and a compressor cooling system with a fan are located in the engine compartment, and a multi-stage reciprocating compressor with a water or ethylene glycol cooling system is located in the compressor compartment. (RU39656U, 2004)

The disadvantage of this analogue is that when the fan of the cooling system is centrifugal, and the impeller of the fan is made of metal, such as sheet steel, the cooling efficiency decreases, the noise and vibration levels in the engine and compressor compartments increase during the operation of the cooling system.

The specified compressor installation is the combination of essential features the closest device of the same purpose of the claimed utility model. Therefore, it is adopted as a prototype of the claimed utility model.

Disclosure of a utility model.

The objective of the utility model is to increase the efficiency of the liquid cooling system of the compressor of the compressor station, while reducing noise and vibration levels produced by the aforementioned cooling system. The technical result consists in expanding the temperature range at which it is possible to operate the compressor station and reduce noise and vibration levels during its operation.

The essence of the utility model is that the compressor station contains a power drive, a piston compressor and a liquid piston compressor cooling system comprising a radiator and a fan. In this case, the fan is made axial, and the impeller of the fan is made of fiberglass.

The compressor station advantageously comprises a removable hood.

The power drive is preferably diesel.

The power drive and reciprocating compressor are predominantly mounted on a frame, which is fixed to the chassis of the vehicle or slide.

The power drive is preferably provided with a liquid and oil cooling unit.

The radiator mainly contains the first and second collectors, while the input of the first collector is connected to the liquid pipe of the expansion tank, the output of the first collector of the radiator is connected to at least one coolant inlet of the piston compressor through a water pump, the coolant output of the piston compressor is hydraulically connected to the input of the second collector .

The expansion tank mainly contains a liquid pipe and a steam pipe, wherein the inlet of the first manifold is hydraulically connected to the liquid pipe of the expansion tank, and the second manifold is connected to the steam pipe.

A steam valve is preferably installed on the expansion tank.

The radiator and fan are preferably located at the rear of the hood.

The radiator is preferably made sectional.

The radiator preferably contains blinds.

The fan can be connected to the shaft of the reciprocating compressor by a cardan drive and an intermediate pulley.

The fan impeller preferably comprises a hub and volumetric blades.

The compressor station advantageously comprises a purge system.

The compressor station preferably comprises a station heating system comprising heating elements.

The compressor station is predominantly equipped with an automation system.

The drawing shows a diagram of a compressor station.

Implementation of a utility model.

The compressor station comprises a removable hood, a power drive 1, a piston compressor 2, and a liquid cooling system of the piston compressor 2.

The removable hood is designed to protect the engine compartment of the compressor station from the effects of precipitation and damage.

Piston compressor 2 is designed to compress and pump atmospheric air and contains an inlet 12 and an outlet 13 of coolant.

The compressor is driven by a power drive 1. The power drive 1 is preferably diesel.

The liquid cooling system of the reciprocating compressor 2 is designed to remove the heat released during compression of air from the reciprocating compressor 2. Before starting work, the liquid cooling system is filled with coolant. The liquid cooling system includes an expansion tank 3, a radiator 4, a water pump 5 and a fan 6.

The expansion tank 3 is designed to compensate for changes in the volume of coolant in the liquid cooling system of the piston compressor 2. The expansion tank 3 contains a fluid pipe 8 and a steam pipe 9.

Radiator 4 is designed to cool the coolant with ambient air. Radiator 4 contains the first 10 and second 11 collectors. The inlet of the first collector 10 is hydraulically connected to the fluid pipe 8 of the expansion tank 3, and the output of the first collector of the radiator 10 is connected to the inlet of the coolant 12 of the reciprocating compressor 2 through a water pump 5 designed to circulate the coolant in the liquid cooling system. The output of the coolant 13 of the reciprocating compressor 2 is hydraulically connected to the inlet of the second manifold 11. In this case, the second manifold 11 is connected to the steam pipe 9 of the expansion tank 3. In order to facilitate repair or maintenance, the radiator 4 is preferably made sectional. To regulate the intensity of cooling, the radiator 4 contains blinds.

The fan 6 is designed to intensify the cooling of the spent coolant in the radiator 4. In this case, the fan 6 is made axial and contains an impeller made of fiberglass. In this case, the impeller of the fan 6 contains volumetric blades and a hub. It is known that one of the advantages of axial fans is their speed. Moreover, they are able to transport large amounts of air - up to several thousand cubic meters per hour. (Z.S. Shlipchenko, “Pumps, Compressors, and Fans,” Kiev, Technika Publishing House 1976, p. 347).

The choice of fiberglass as the structural material of the impeller of fan 6 is due to its advantages, namely, high strength and dielectric properties, relatively low density and thermal conductivity, as well as high atmosphere, water and chemical resistance ("Great Soviet Encyclopedia", publishing house "Soviet Encyclopedia" , 1969-1978 in 30 volumes, article "Fiberglass"). In this case, the fiberglass impeller of the fan 6 has a lower mass, compared with the impeller made of metal, which reduces the noise and vibration levels produced by the working cooling system.

Examples of specific performance.

Example 1. The power drive 1 and the reciprocating compressor 2 are mounted on a frame that is fixed to the chassis of the vehicle or slide.

Example 2. In order to remove heat from the loaded parts and maintain the optimum temperature of the operating diesel power drive 1, the above power drive 1 is equipped with a cooling unit for liquid and oil 14.

Example 3. In order to protect the radiator from destruction during a significant increase in pressure or the occurrence of vacuum in the cooling system, a steam-air valve is installed on the expansion tank 3.

Example 4. Radiator 4 and fan 6 are located at the rear wall of the hood.

Example 5. The fan 6 is connected to the shaft of the reciprocating compressor 2 by a cardan gear and an intermediate pulley.

Example 6. In order to remove condensate that accumulates during operation of the equipment, the compressor station contains a purge system.

Example 7. In order to preheat the diesel power drive 1 and reciprocating compressor 2 in the cold season, the compressor station contains a station heating system containing heating elements.

Example 8. In order to control the operation, protection and control of the operating parameters of the equipment, the compressor station is equipped with an automation system.

The implementation of the structural elements of the claimed utility model is not limited to the above examples.

Work description.

The compressor station is driven by a power drive 1. Atmospheric air enters the inlet of the piston compressor 2, is compressed sequentially in its stages and is supplied to the consumer. The compression of air in the compressor 2 is accompanied by the release of heat, most of which is discharged into the environment through the coolant in the liquid cooling system. Coolant is poured into the liquid cooling system and enters the radiator 4, from where it is pumped to the inlet of the coolant 12 of the piston compressor 2. In the piston compressor 2, its working units and parts are cooled. The spent coolant enters from the outlet of the coolant 13 of the reciprocating compressor 2 for cooling to the radiator 4. In the radiator 4, the spent coolant is cooled by air blown by the axial fan 6. The impeller of the axial fan 6 moves the air flow towards the radiator by rotating the blades. Since the impeller of the axial fan is made of fiberglass, during its operation the level of noise and vibration is reduced. Then, the coolant cooled in the radiator 4 is again pumped to the inlet of the coolant 12 of the reciprocating compressor 2.

The author of the utility model made a prototype of the claimed compressor station, the tests of which confirmed the achievement of the technical result.

The inventive compressor station is implemented using industrially produced devices and materials, can be assembled at a machine-building enterprise and will be widely used in the chemical, coal and mining industries, and the fields of extraction, processing, transportation and marketing of oil and gas products.

Claims (15)

1. A compressor station comprising a power drive, a reciprocating compressor and a liquid piston compressor cooling system comprising a radiator and a fan, characterized in that the fan is axial and the fan impeller is made of fiberglass. 2. The station according to claim 1, characterized in that it contains a removable hood. 3. The station according to claim 1, characterized in that the power drive is made of diesel. 4. The station according to claim 1, characterized in that the power drive and reciprocating compressor are mounted on a frame that is fixed to the chassis of the vehicle or slide. 5. The station according to claim 1, characterized in that the power drive is equipped with a cooling unit for liquid and oil. 6. The station according to claim 1, characterized in that the radiator contains the first and second collectors, while the input of the first collector is connected to the liquid pipe of the expansion tank, the output of the first radiator collector is connected to at least one coolant inlet of the piston compressor through a water pump, the coolant outlet of the reciprocating compressor is hydraulically connected to the inlet of the second manifold, while the second manifold is connected to the steam pipe of the expansion tank. 7. The station according to claim 6, characterized in that a steam-air valve is installed on the expansion tank. 8. The station according to claim 1, characterized in that the radiator and fan are located at the rear wall of the hood. 9. The station according to claim 1, characterized in that the radiator is made sectional. 10. The station according to claim 1, characterized in that the radiator contains blinds. 11. The station according to claim 1, characterized in that the fan is connected to the shaft of the reciprocating compressor by a cardan transmission and an intermediate pulley. 12. The station according to claim 1, characterized in that the fan impeller contains a hub and volumetric blades. 13. The station according to claim 1, characterized in that it contains a purge system. 14. The station according to claim 1, characterized in that it contains a station heating system containing heating elements. 15. The station according to claim 1, characterized in that it is equipped with an automation system.