RU135014U1 - COMPRESSOR PISTON OPPOSITIVE SURVIVAL TWO STAGE - Google Patents

Abstract

1. A two-stage opposing reciprocating compressor compressor comprising a first cylinder of a first stage, a first cylinder of a second stage and a first interstage gas cooler, wherein the first cylinder of the first stage is placed in the first row and the first cylinder of the second stage is placed in the second row, wherein the gas outlet of the first cylinder the first stage is connected to the gas inlet of the first interstage gas cooler, the gas outlet of which is connected to the gas inlet of the first cylinder of the second stage, characterized in that - in the first row there is a second second stage cylinder, forming a differential block of cylinders with the first cylinder of the first stage, while the first cylinder of the first stage is placed on the side of the bed; - in the second row on the side of the bed is the second cylinder of the first stage, which forms the differential cylinder block with the first cylinder of the second stage; - output the gas of the second cylinder of the first stage is connected to the inlet of the second interstage gas cooler, the gas outlet of which is connected to the gas inlet of the second cylinder of the second stage; - contains a collector, the first input of which th connected to an output gas of the first cylinder of the second stage, a second input coupled to an output gas of the second cylinder of the second stage, the outlet manifold is connected to the input terminal gazoohladitelya.2. The compressor according to claim 1, characterized in that the cylinders are single acting. The compressor according to claim 1, characterized in that it contains a frame with lamps, while the first remote lamp is installed between the first lamp of the frame and the first cylinder of the first stage, and between the second lamp of the frame and the second cylinder of the first stage

Description

The field of technology.

The inventive utility model relates to the field of engineering, namely to compressor engineering. The inventive reciprocating piston opposing booster two-stage is designed to compress natural gas under pressure.

The prior art.

Known opposed double-row crosshead two-stage compressor containing a bed with lights, a cylinder of the first stage, a cylinder of the second stage, an interstage cooler, a moisture separator and a lubrication system of the movement mechanism. In this case, the cylinder of the first stage is placed in the first row, and the cylinder of the second stage is placed in the second row. In addition, the gas outlet of the cylinder of the first stage is connected to the gas inlet of the interstage cooler, the gas outlet of which is connected to the gas inlet of the cylinder of the second stage (Plastinin P.I. Piston compressors. Volume 2. Design fundamentals. .515, 586, sheet A.2.18, [1]).

The disadvantage of the analogue [1] is its relatively large metal consumption. The reason for this is the inequality of the reciprocating masses and large dynamic loads on the crankshaft. Increased dynamic loads on the crankshaft lead to an increase in the size and mass of all parts, and unbalanced inertia forces are transferred to the foundation, which increases the requirements for it.

Disclosure of a utility model.

The technical result provided by the claimed utility model is to reduce the metal consumption of the compressor. A complete balancing of the reciprocating masses and dynamic loads in the opposite rows is also achieved.

The essence of the utility model consists in the fact that the two-stage piston opposed compression booster compressor contains the first cylinder of the first stage, the first cylinder of the second stage and the first interstage gas cooler. In this case, the first cylinder of the first stage is placed in the first row, and the first cylinder of the second stage is placed in the second row. In this case, the gas outlet of the first cylinder of the first stage is connected to the gas inlet of the first interstage gas cooler, the gas outlet of which is connected to the gas inlet of the first cylinder of the second stage. Wherein:

- in the first row there is a second cylinder of the second stage, forming with the first cylinder of the first stage a differential cylinder block, while the first cylinder of the first stage is placed on the side of the bed;

- in the second row from the bed side there is a second cylinder of the first stage, forming a differential cylinder block with the first cylinder of the second stage;

- the gas outlet of the second cylinder of the first stage is connected to the inlet of the second interstage gas cooler, the gas outlet of which is connected to the gas inlet of the second cylinder of the second stage;

- the compressor contains a manifold, the first inlet of which is connected to the gas outlet of the first cylinder of the second stage, and the second inlet is connected to the gas outlet of the second cylinder of the second stage, while the outlet of the manifold is connected to the inlet of the end gas cooler.

The cylinders are predominantly single-acting.

The compressor comprises a bed with lanterns, wherein a first distance lamp is preferably installed between the first lamp of the bed and the first cylinder of the first stage, and a second distance lamp is installed between the second lamp of the bed and the second cylinder of the first stage.

The compressor contains pistons and rods, which are preferably made of anticorrosive material, while in the cavities of the cylinders are installed sleeves made of anticorrosive material.

The compressor contains pistons on which support and sealing piston rings are installed, made of self-lubricating material based on fluoroplastic.

The interstage and end gas coolers are preferably located on a frame located near the compressor.

The compressor desirably comprises a branched inlet conduit, the inlet of which is connected to the receiver. In this case, the first outlet of the pipeline is connected to the gas inlet of the first cylinder of the first stage, and the second outlet of the pipeline is connected to the gas inlet of the second cylinder of the first stage.

The input of a branched inlet pipe can be connected to the receiver through a filter.

The compressor mainly contains a power drive made in the form of an electric motor, the rotor of which is mounted on the crankshaft of the compressor.

The compressor preferably comprises a motion lubrication system, a liquid cooling system and a control cabinet.

A brief description of the drawings.

The figure shows a diagram of a two-stage piston opposing booster compressor.

Implementation of a utility model.

The two-stage opposing booster piston compressor is preferably made without lubrication of the cylinders and gaskets, in order to supply compressed gas to the consumer without turning on the oil. The inventive compressor contains a power drive (1), a base, first and second cylinder-piston groups, first and second remote lights (15, 16), suction and discharge valves, a branch pipe (17), a receiver (18), a filter (19) , the first interstage gas cooler (24), the second interstage gas cooler (25), the collector (26), the end gas cooler (31), the lubrication mechanism of the movement mechanism, the cooling system and the control cabinet.

The power drive (1) is designed to drive the compressor and is made in the form of an electric motor, the rotor of which is mounted on the crankshaft (4) of the compressor.

The compressor base contains a bed (2) with the first and second lights (not shown), a crankshaft (4), connecting rods (5) and crossheads (6). The crankshaft (4) is installed in the bearings (3). The first and second lights are located on two sides of the frame (2) and are preferably integrally formed with it.

The first cylinder-piston group comprises a first cylinder of the first stage (7), a second cylinder of the second stage (12), a first differential piston of the first and second stages (9) and a piston rod (10). The second cylinder-piston group comprises a second cylinder of the first stage (11), a first cylinder of the second stage (8), a second differential piston of the first and second stages (13), and a piston rod (14).

Cylinders (7, 8, 11, 12) are single-acting and liners (not shown) made of anticorrosive material are installed in their bodies. The first cylinder of the first stage (7) is placed in the first row from the bed side (2), and the second cylinder of the first stage (11) is placed in the second row from the side of the bed (2). The first cylinder of the second stage (8) is placed in the second row and forms a differential cylinder block with the second cylinder of the first stage (11). The second cylinder of the second stage (12) is placed in the first row and forms a differential cylinder block with the first cylinder of the first stage (7).

Pistons (9, 13) and rods (10, 14) are made of anticorrosive material. Such a choice of material for liners, pistons (9, 13) and rods (10, 14) is due to the fact that moisture can be present in the compressible gas, part of which settles on the above parts and, in the absence of lubrication, causes their corrosion. Supporting and sealing piston rings (not shown) made of self-lubricating material based on fluoroplastic are installed on the pistons (9, 13). Piston rings are designed to seal the gaps between the pistons (9, 13) and the cylinders (7, 8, 11, 12).

Between the first cylinder of the first stage (7) and the first lamp of the frame (2), the first remote lamp (15) is installed, and between the second cylinder of the first stage (11) and the second lamp of the frame (2) a second remote lamp (16) is installed. The first and second remote lights (15, 16) are designed to prevent oil from entering the frame into the working cavities of the cylinders of the first and second stages (7, 8, 11, 12). For this purpose, in each of the remote lanterns (15, 16) an oil-lubricating gland and an oil separator (not shown) are placed.

Suction valves (not shown) are designed to pass gas into the working cavities of the cylinders of the first and second stages (7, 8, 11, 12) at certain periods of time, and not to let it pass in the opposite direction during the rest of the working cycle. Pressure valves (not shown) are designed to pass gas from the working cavities of the cylinders (7, 8, 11, 12) into the pressure cavity and not to let it pass from the pressure cavities to the working cavities.

The branched inlet pipe (17) is designed to supply gas to the first and second cylinders of the first stage (7, 11) and is common to these cylinders. The inlet of the branched inlet pipe (17) is connected to the receiver (18), designed to accumulate gas and smooth out pressure fluctuations. The first outlet (20) of the branched pipeline (17) is connected to the gas inlet (21) of the first cylinder of the first stage (7), and the second outlet (22) of the pipeline (17) is connected to the gas inlet (23) of the second cylinder of the first stage (11).

The first and second interstage gas coolers (24, 25) are designed to cool the gas between the first and second compression stages. The gas inlet of the first interstage gas cooler (24) is connected to the gas outlet of the first cylinder of the first stage (7), and the gas outlet of the first interstage gas cooler (24) is connected to the gas inlet of the first cylinder of the second stage (8). The gas inlet of the second interstage gas cooler (25) is connected to the gas outlet of the second cylinder of the first stage (11), and the gas outlet of the second interstage gas cooler (25) is connected to the gas inlet of the second cylinder of the second stage (12).

The collector (26) is branched and designed to collect compressed gas from the first and second cylinders of the second stage (8, 12). The first inlet (27) of the manifold (26) is connected to the gas outlet (28) of the first cylinder of the second stage (8), and the second inlet (29) is connected to the gas outlet (30) of the second cylinder of the second stage (12). The output of the collector (26) is connected to the input of the end gas cooler (31).

The end gas cooler (31) is designed to cool the gas after the second compression stage.

The lubrication system of the movement mechanism (not shown) is designed to lubricate the rubbing surfaces of the movement mechanism, namely the crankshaft (4), connecting rods (5) and crossheads (6). The aforementioned lubrication system is circulated from a gear pump (not shown).

The cooling system (not shown) is designed to remove heat released during gas compression from the first and second cylinders of the first stage (7, 11), the first and second cylinders of the second stage (8, 12), the first and second interstage gas coolers (24, 25), and end gas cooler (31).

A control cabinet (not shown) is designed to control the operation of the compressor.

Examples of specific performance.

Example 1. Interstage gas coolers (24, 25) and end gas coolers (31) are placed on a frame located near the compressor.

Example 2. For the purpose of preliminary purification of gas from mechanical impurities, the inlet of the branched inlet pipe (17) is connected to the receiver (18) through a filter (19).

Example 3. In order to ensure the compressor capacity of 4.5-5.5 m ³ / min under suction conditions and a final pressure of 2.1 MPa (21 kgf / cm ² ), the main dimensions and parameters of the compressor are as follows (table. one).

Table 1 The main parameters and characteristics of the compressor Parameter Name Value Suction pressure, kgf / cm ² 0.8-1.8 Suction temperature, ° С -25- + 35 Volumetric productivity, m ³ / min, reduced to normal conditions 6.5 Temperature after the end gas cooler (31), no more, ° С 60 Power consumption on the crankshaft (4) of the compressor, kW, no more 60 Compressor rotation frequency (4) of the compressor, rpm, nom. 740 Motor type Explosion Proof Asynchronous

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

Work description.

Natural gas under excess pressure enters through a branched inlet pipe (17) into the first cylinder of the first stage (7) and the second cylinder of the first stage (11). In the first and second cylinders of the first stage (7, 11), the gas is compressed. Then, compressed gas from the first cylinder of the first stage (7) enters the first interstage gas cooler (24), and compressed gas from the second cylinder of the first stage (11) enters the second interstage gas cooler (25). In the first and second interstage gas coolers (24, 25), the gas is cooled. Then, the cooled gas from the first interstage gas cooler (24) enters the first cylinder of the second stage (8), and the cooled gas from the second interstage gas cooler (25) enters the second cylinder of the second stage (12). In the first and second cylinders of the second stage (8, 12), the gas is compressed to a final pressure. Then, the stream of compressed gas from the first cylinder of the second stage (8) and the stream of compressed gas from the second cylinder of the second stage (12) are combined in a manifold (26) into a single stream, which then enters the terminal gas cooler (31). In the end gas cooler (31), the compressed gas is cooled and then supplied to the consumer.

Thus, from the foregoing, it follows that in the inventive compressor of a reciprocating opposed reciprocating two-stage compressing machine, the claimed technical results: “reducing the metal consumption of the compressor” and “full balancing of the reciprocating masses and dynamic loads in the opposite rows” are achieved due to the fact that the reciprocating piston opposed compressing compressors are two-stage comprising a first cylinder of a first stage, a first cylinder of a second stage and a first interstage gas cooler. In this case, the first cylinder of the first stage is placed in the first row, and the first cylinder of the second stage is placed in the second row. In this case, the gas outlet of the first cylinder of the first stage is connected to the gas inlet of the first interstage gas cooler, the gas outlet of which is connected to the gas inlet of the first cylinder of the second stage. Wherein:

- in the first row there is a second cylinder of the second stage, forming with the first cylinder of the first stage a differential cylinder block, while the first cylinder of the first stage is placed on the side of the bed;

- in the second row from the bed side there is a second cylinder of the first stage, forming a differential cylinder block with the first cylinder of the second stage;

- the gas outlet of the second cylinder of the first stage is connected to the inlet of the second interstage gas cooler, the gas outlet of which is connected to the gas inlet of the second cylinder of the second stage;

- the compressor contains a manifold, the first inlet of which is connected to the gas outlet of the first cylinder of the second stage, and the second inlet is connected to the gas outlet of the second cylinder of the second stage, while the outlet of the manifold is connected to the inlet of the end gas cooler.

The inventive compressor has a lower mass compared to the analogue [1], since the above arrangement of the cylinders (7, 8, 11, 12) and pistons (9, 13) in the opposite rows of the compressor allows you to balance the reciprocating moving masses and dynamic loads on the crankshaft shaft (4). This, in turn, reduces the size of rods (10, 14), connecting rods (5), C4 crankshaft) and reduces the foundation requirements for a compressor. At the same time, interstage and end gas coolers (24, 25, 31) are necessary for safe operation of the compressor and provide heat removal from the compressible gas.

Industrial applicability.

The author of the utility model has made a prototype of the claimed two-stage compression piston compression booster compressor.

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

INFORMATION SOURCES.

1. Plastinin P.I. Piston compressors. Volume 2. Basics of design. Constructions. M .: KolosS, 2006.

Claims (12)

1. A two-stage opposing reciprocating compressor compressor comprising a first cylinder of a first stage, a first cylinder of a second stage and a first interstage gas cooler, wherein the first cylinder of the first stage is placed in the first row and the first cylinder of the second stage is placed in the second row, wherein the gas outlet of the first cylinder the first stage is connected to the gas inlet of the first interstage gas cooler, the gas outlet of which is connected to the gas inlet of the first cylinder of the second stage, characterized in that - in the first row there is a second cylinder of the second stage, forming with the first cylinder of the first stage a differential cylinder block, while the first cylinder of the first stage is placed on the side of the bed; - in the second row from the bed side there is a second cylinder of the first stage, forming a differential cylinder block with the first cylinder of the second stage; - the gas outlet of the second cylinder of the first stage is connected to the inlet of the second interstage gas cooler, the gas outlet of which is connected to the gas inlet of the second cylinder of the second stage; - contains a collector, the first inlet of which is connected to the gas outlet of the first cylinder of the second stage, and the second inlet is connected to the gas outlet of the second cylinder of the second stage, while the outlet of the manifold is connected to the inlet of the end gas cooler. 2. The compressor according to claim 1, characterized in that the cylinders are single acting. 3. The compressor according to claim 1, characterized in that it contains a frame with lights, while the first remote lamp is installed between the first lamp of the frame and the first cylinder of the first stage, and the second remote lamp is installed between the second lamp of the frame and the second cylinder of the first stage. 4. The compressor according to claim 1, characterized in that it contains pistons and rods that are made of anticorrosive material, while in the cavities of the cylinders are installed sleeves made of anticorrosive material. 5. The compressor according to claim 1, characterized in that it contains pistons on which support and sealing piston rings are mounted made of a self-lubricating material based on fluoroplastic. 6. The compressor according to claim 1, characterized in that the interstage and end gas coolers are placed on a frame located near the compressor. 7. The compressor according to claim 1, characterized in that it contains a branched inlet pipe, the input of which is connected to the receiver, the first outlet of the pipeline connected to the gas inlet of the first cylinder of the first stage, and the second outlet of the pipeline connected to the gas inlet of the second cylinder of the first stage. 8. The compressor according to claim 7, characterized in that the input of the branched inlet pipe is connected to the receiver through a filter. 9. The compressor according to claim 1, characterized in that it contains a power drive made in the form of an electric motor, the rotor of which is mounted on the crankshaft of the compressor. 10. The compressor according to claim 1, characterized in that it contains a lubrication system of the movement mechanism. 11. The compressor according to claim 1, characterized in that it contains a liquid cooling system. 12. The compressor according to claim 1, characterized in that it comprises a control cabinet.

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