RU125268U1 - COMPRESSOR PISTON OPPOZITNY DOUBLE RANGE FIVE-STEPPED - Google Patents

Abstract

The inventive reciprocating compressor piston opposed two-row five-stage is designed to compress gas, mainly air, used as an energy carrier in various industries. Achieving minimum dimensions of the compressor while maintaining ease of installation and maintenance. The two-row piston opposed two-row compressor contains a base, a cylinder group, a piston group, interstage gas coolers (13, 16, 19, 23) and operating valves. At the same time in the first row are placed the first-stage cylinder (6) and the third-stage cylinder (7), and in the second row are placed the fourth-stage cylinder (8), the second-stage cylinder (9) and the fifth-stage cylinder (10). In this case: - the first stage gas cooler (13) is located above the first stage cylinder (6) and the second stage cylinder (9); - the second stage gas cooler (16), the third stage gas cooler (19) and the fourth stage gas cooler (23) are located in one horizontal plane above the first stage gas cooler (13); - each of the cylinders (6, 7, 8, 9, 10) contains at least one gas inlet and at least one gas outlet, while the gas inlet (24) of the fifth stage cylinder (10) is located in the upper or lower part of the above cylinder (10), and the gas outlet (25) of the fifth-stage cylinder (10) is located on the side, at right angles to the gas inlet (24). 11 hp, 4 ill.

Description

The field of technology.

The claimed utility model relates to the field of engineering, namely compressor engineering. The inventive reciprocating compressor piston opposed two-row five-stage is designed to compress gas, mainly air, used as an energy carrier in various industries.

Prior art.

Known, for example, is a reciprocating double-row piston compressor containing a base, a cylinder-piston group, operating valves and interstage gas coolers-oil-oil separators. In this case, the compressor is made five-stage and has one cylinder in each stage. In addition, the cylinder block of the first and third stages consists of interconnected cylinders of the first and third stages. In this case, the block of cylinders of the second, fourth and fifth stages consists of fourth, second and fifth stages of cylinders connected to each other (RF patent №111208 for a utility model, IPC F04B 25/00, 2011 [1]).

The disadvantage of this analogue [1] is that with an arbitrary placement of gas coolers, moisture and oil separators relative to the base frame increase the size of the compressor. This complicates access to the repaired units, such as the crankshaft base, cylinders, rods and pistons. In addition, the constructive arrangement of the gas inlets and outlets at the cylinders is complicated, since it depends on the arrangement of the refrigerators. This, in turn, leads to the fact that the gas pipelines that lead to the cylinders and which lead away from the cylinders prevent the installation and disassembly of valves. In addition, the material consumption of the compressor increases, as the dimensions of the above pipelines increase.

Disclosure of the utility model.

The technical result provided by the inventive compressor piston opposed two-row five-stage, is to ensure the minimum dimensions of the compressor while maintaining ease of installation and maintenance.

The essence of the utility model is that a reciprocating two-row five-stage reciprocating compressor contains a base, a cylinder group, a piston group, interstage coolers and operating valves. At the same time in the first row are placed the first-stage cylinder and the third-stage cylinder, and in the second row are placed the fourth-stage cylinder, second-stage cylinder and fifth-stage cylinder. Wherein:

- the first stage gas cooler is located above the first stage cylinder and the second stage cylinder;

- the second stage gas cooler, the third stage gas cooler and the fourth stage gas cooler are located in the same horizontal plane above the first stage gas cooler;

- each cylinder contains at least one gas inlet and at least one gas outlet, while the gas inlet of the fifth-stage cylinder is located in the upper or lower part of the above-mentioned cylinder, and the gas outlet of the fifth-stage cylinder is located on the side at right angles to the gas inlet .

The gas outlet of the fifth-stage cylinder is preferably connected to an end gas cooler.

The end gas cooler can be made coil.

The second stage gas cooler, the third stage gas cooler and the fourth stage gas cooler are predominantly mounted on a rigid support.

The output of the gas cooler of the third stage is preferably connected to the gas inlet of the cylinder of the fourth stage through the dehumidifier of the third stage. At the same time, the output of the fourth stage gas cooler is connected to the gas inlet of the fifth stage cylinder through a fourth stage hydraulic oil separator.

The third-stage moisture-oil separator and the fourth-stage moisture-oil separator are preferably arranged vertically.

Each of the cylinders advantageously comprises a suction cavity and a discharge cavity. At the same time, the gas inlet of each cylinder is made in the suction cavity, and the gas outlet of each cylinder is made in the discharge cavity, the gas inlet and outlet being arranged so that their axes intersect the axes of the cylinders.

The gas inlet and gas outlet of the first-stage cylinder are preferably located in its lower and upper parts, respectively. In this case, the gas inlet and gas outlet of the second-stage cylinder are located respectively in its upper and lower parts. In this case, the gas inlet and gas outlet of the third-stage cylinder are located respectively in its lower and upper parts. In this case, the gas inlet and gas outlet of the fourth-stage cylinder are located on the sides of the above-mentioned cylinder.

The compressor preferably contains a cooling system, a lubrication system and a control cabinet.

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

Brief description of the drawings.

The figure 1 shows the execution scheme of the piston opposed two-row five-stage compressor; figure 2 - layout of the gas coolers relative to the frame (top view); figure 3 - layout of the gas coolers relative to the frame (type A); figure 4 - layout of the gas coolers relative to the frame (type B).

Implementation of the utility model.

The two-row piston opposed two-row compressor (figure 1) contains a power actuator (1), a base, a cylinder group, a piston group, interstage gas coolers, operating valves, a cooling system, a lubrication system, and a 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 (3) of the compressor.

The base of the compressor contains a frame (2), a crankshaft (3), connecting rods (4) and crossheads (5).

The cylinder group contains the cylinder block of the first and third stages, and the cylinder block of the fourth, second and fifth stages. In this case, the cylinder block of the first and third stages is located in the first row and contains the cylinder of the first stage (6) and the cylinder of the third stage (7). At the same time, the block of cylinders of the fourth, second and fifth stages of the stages is located in the second row and contains the cylinder of the fourth stage (8), the second stage cylinder (9) and the third stage cylinder (10).

Each of the above cylinders (6, 7, 8, 9, 10) contains a working cavity, windows for operating valves, a water cavity, a suction cavity, an injection cavity, at least one gas inlet, and at least one gas outlet.

In the water cavities of the cylinders (6, 7, 8, 9, 10) cooling water flows through the cylinders.

The gas inlet of each cylinder is made in the suction cavity, and the gas outlet of each cylinder is made in the discharge cavity. The gas inlet and outlet are preferably arranged in such a way that their axes intersect the axes of the cylinders (6, 7, 8, 9, 10).

The gas inlet (11) and the gas outlet (12) of the cylinder of the first stage (6) are located respectively in the lower and upper parts of the above-mentioned cylinder (6) (FIG. 3). At the same time, the gas outlet (12) of the first stage cylinder (6) is connected to the inlet of the first stage gas cooler (13).

The gas inlet (14) and the gas outlet (15) of the second-stage cylinder (9) are located in the upper and lower parts of the above-mentioned cylinder (9), respectively (Fig. 4). The gas inlet (14) of the second-stage cylinder (9) is connected to the gas-cooler outlet of the first stage (13), and the gas output (15) of the above-mentioned cylinder (9) is connected to the gas-cooler inlet of the second stage (16).

The gas inlet (17) and the gas outlet (18) of the third-stage cylinder (7) are located respectively in the lower and upper parts of the above-mentioned cylinder (7). The gas inlet (17) of the aforementioned cylinder (7) is connected to the outlet of the interstage second-stage gas cooler (16), and the gas outlet (18) of the above-mentioned cylinder (7) is connected to the inlet of the third stage gas cooler (19).

The gas inlet (20) and the gas outlet (21) of the fourth-stage cylinder (8) are located on the sides of the above-mentioned cylinder (8). In this case, the gas inlet (20) of the fourth-stage cylinder (8) is connected to the outlet of the third-stage gas cooler (19) via a third-stage moisture-oil separator (22). The third stage moisture and oil separator (22) is located vertically and is designed to remove friction products, mechanical impurities, drip liquids and oil from the gas cooled in the gas cooler (19). The gas outlet (21) of the fourth stage cylinder (8) is connected to the inlet of the fourth stage gas cooler (23).

The gas inlet (24) of the fifth-stage cylinder (10) is located at the top or part of the above-mentioned cylinder (10), and the gas outlet (25) is located at the side, at right angles to the gas inlet (24). In this case, the gas inlet (24) of the fifth-stage cylinder (10) is connected to the fourth-stage gas-cooler outlet (23) through the fourth-stage moisture and oil separator (26). The fourth-stage moisture-oil separator (26) is located vertically and is designed to remove friction products, mechanical impurities, drip liquids and oil from the gas cooled in the gas cooler (23).

The above arrangement of gas inlets and outlets is due to the location of interstage gas coolers (13, 16, 19, 23). Gas coolers of the first, second, third and fourth stages (13, 16, 19, 23) are designed to cool the gas between the compression stages, smooth its pulsations and separate the condensate.

The first stage gas cooler (13) is located above the first stage cylinder (6) and the second stage cylinder (9). The second stage gas cooler (16), the third stage gas cooler (19) and the fourth stage gas cooler (23) are located in the same horizontal plane above the first stage gas cooler (13). Moreover, the above gas coolers (16, 19, 23) are fixed on a rigid support.

The piston group of the inventive compressor includes a differential piston of the first and third stages (27) and a differential piston of the fourth, second and fifth stages (28).

Working valves (not shown) contain suction and discharge valves. Suction valves are designed to allow gas to flow into the working cavities of cylinders (6, 7, 8, 9, 10) in one direction at certain periods of time, and not to allow it to flow in the opposite direction during the rest of the operating cycle. The injection valves are designed to pass gas from the working cavity of each of the cylinders (6, 7, 8, 9, 10) into the discharge cavity during the discharge period and not to let it out of the discharge cavity into the working cavity.

The compressor is lubricated by two independent systems: the circulating lubrication system for the movement mechanisms and the lubrication system for the cylinders and oil seals.

The lubrication system of cylinders and seals is made of a forced, dosed from the lubricant multivend station.

The lubrication system of the movement mechanism is designed to lubricate the rubbing surfaces of the movement mechanism, namely, the crankshaft (3), connecting rods (4) and crossheads (5). The aforementioned lubrication system is circulating, from a gear pump (not shown).

The compressor cooling system (not shown) is made liquid and is designed to remove heat released during air compression from the cylinders (6, 7, 8, 9, 10) and gas coolers (13, 16, 19, 23).

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

Examples of specific performance.

Example 1. In order to cool the compressed gas coming from the compressed gas outlet of the compressor to the network, the gas outlet (25) of the fifth-stage cylinder (10) is connected to an end gas cooler (not shown). In this case, the end gas cooler is coil.

Example 2. In order to ensure compressor performance equal to 7 ÷ 11 m ³ / min during its operation with initial atmospheric pressure, the main dimensions and parameters of the compressor are the following values (Table 1)

Table 1 Main parameters and characteristics of the compressor Parameter name Value Power consumption at the compressor shaft, kW, not more 140 Crankshaft speed (3), rpm 1350 Absorption temperature, not more than, ° С -25 ÷ + 40 Discharge temperature, not more than, ° С 170 The diameter of the cylinder of the first stage (6), mm 330 The diameter of the cylinder second stage (9), mm 200 The diameter of the third stage cylinder (7), mm 115 The diameter of the fourth stage cylinder (8), mm 80 The diameter of the cylinder of the fifth stage (10), mm 40 Final discharge pressure, kgf / cm ² 220

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

Description of work.

The gas to be compressed enters through the gas inlet (11) of the first-stage cylinder (6) into the suction cavity of the above-mentioned cylinder (6). Then, gas through the open suction working valves enters the working cavity of the first-stage cylinder (6), where it is compressed. The compressed gas is pushed through the working pressure valves into the cavity of the first stage cylinder (6), and then through the gas outlet (12) enters the first stage gas cooler (13). In the first stage gas cooler (13) the gas is cooled. Then the cooled gas is directed sequentially to the second and third stages of compression. In this case, the gas is cooled between the second and third stages in the second stage gas cooler (21). After compression in the third stage and subsequent cooling in the third stage gas cooler (19), the gas enters the third stage water-oil separator (22), where it is cleaned from drip liquids and oils. Then, the cooled and purified gas enters the fourth and fifth compression stages, while cooling between the stages in the fourth stage gas cooler (23) and being cleaned of drip liquids and oils in the fourth stage moisture separator (26). In the fifth stage of compression, the gas is compressed to the final pressure and supplied to the consumer through an end cooler.

Thus, from the above, it follows that in the inventive compressor piston opposed two-row five-step claimed technical result: "ensuring compact and convenient for installation and servicing of placement of gas coolers" is achieved due to the fact that the compressor piston opposed two-row five-step contains a base, cylinder group, piston group , interstage gas coolers and operating valves. At the same time in the first row are placed the first-stage cylinder and the third-stage cylinder, and in the second row are placed the fourth-stage cylinder, second-stage cylinder and fifth-stage cylinder. Wherein:

- the first stage gas cooler is located above the first stage cylinder and the second stage cylinder;

- the second stage gas cooler, the third stage gas cooler and the fourth stage gas cooler are located in the same horizontal plane above the first stage gas cooler;

- each cylinder contains at least one gas inlet and at least one gas outlet, while the gas inlet of the fifth-stage cylinder is located in the upper or lower part of the above-mentioned cylinder, and the gas outlet of the fifth-stage cylinder is located on the side at right angles to the gas inlet .

Industrial Applicability.

The author of the utility model has manufactured a prototype of the claimed two-row piston opposed two-row compressor, the tests of which confirmed the achievement of a technical result.

The inventive reciprocating compressor piston opposed two-row five-stage is implemented using industrially manufactured devices and materials, can be assembled at any engineering enterprise and will find wide application in the fields of production, processing, transportation and marketing of oil and gas products.

INFORMATION SOURCES.

1. RF patent №111208 for a utility model, IPC F04B 25/00, publ. 2011

Claims (12)

1. A reciprocating two-row piston opposite five-stage compressor, containing a base, a cylinder group, a piston group, interstage gas coolers, operating valves, with the first stage cylinder and the third stage cylinder in the first row, and the fourth stage cylinder, the second stage cylinder and cylinder fifth stage, characterized in that - the first stage gas cooler is located above the first stage cylinder and the second stage cylinder; - the second stage gas cooler, the third stage gas cooler and the fourth stage gas cooler are located in the same horizontal plane above the first stage gas cooler; - each cylinder contains at least one gas inlet and at least one gas outlet, while the gas inlet of the fifth-stage cylinder is located in the upper or lower part of the above-mentioned cylinder, and the gas outlet of the fifth-stage cylinder is located on the side at right angles to the gas inlet . 2. The compressor according to claim 1, characterized in that the gas outlet of the fifth-stage cylinder is connected to the end gas cooler. 3. The compressor according to claim 2, characterized in that the end gas cooler is coil. 4. The compressor according to claim 1, characterized in that the gas cooler of the second stage, the gas cooler of the third stage and the gas cooler of the fourth stage are fixed on a rigid support. 5. The compressor according to claim 1, wherein the third stage gas cooler outlet is connected to the fourth stage cylinder gas inlet via a third stage moisture oil separator, while the fourth stage gas cooler outlet is connected to the fifth stage cylinder gas inlet through a fourth stage moisture oil separator. 6. The compressor according to claim 5, characterized in that the water-oil separator of the third and the water-oil separator of the fourth stage are arranged vertically. 7. The compressor according to claim 1, characterized in that each of the cylinders contains a suction cavity and an injection cavity, wherein the gas inlet of each cylinder is made in the suction cavity, and the gas outlet of each cylinder is made in the discharge cavity, the gas inlet and outlet being that their axes intersect the axes of the cylinders. 8. The compressor according to claim 1, characterized in that the gas inlet and the gas outlet of the first stage cylinder are located respectively in its lower and upper parts, while the gas inlet and gas outlet of the second stage cylinder are located respectively in its upper and lower parts, while the gas inlet and gas outlet of the third-stage cylinder are located respectively in its lower and upper parts, while the gas inlet and gas outlet of the fourth-stage cylinder are located on the sides of the above-mentioned cylinder. 9. The compressor according to claim 1, characterized in that it contains a cooling system. 10. The compressor according to claim 1, characterized in that it contains a lubrication system. 11. The compressor according to claim 1, characterized in that it contains a control cabinet. 12. 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 compressor shaft.

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