RU168092U1 - DIFFERENTIAL PISTON COMPRESSOR CYLINDER - Google Patents

Abstract

The claimed technical solution relates to the field of compressor engineering and can be used in cylinder - piston units of reciprocating compressors. The technical problem, the solution of which is ensured by the implementation of the proposed technical solution, is to create a compact differential cylinder, which allows to reduce the dimensions of the reciprocating compressor and to use such a compressor in compact compressor stations. The piston compressor cylinder contains interconnected cylinder of the middle stage (1), cylinder of the junior stage (2) and cylinder of the senior stage (3). Moreover, valve seats (5, 13, 16) are made in each of the cylinders (1, 2, 3). In order to reduce the length of the differential cylinder, the middle stage cylinder (1) contains a protruding section (8) located along the axis of the cylinder (1) from the side of the first end. In this case, the protruding section (8) of the cylinder of the middle stage (1) is installed in the cylinder of the lower stage (2). In addition, the valve seats (16) of the upper stage cylinder (3) are located on the sides of the cylinder (3).

2 cp f-ls, 1 ill.

Description

The field of technology.

The claimed technical solution relates to the field of compressor engineering and can be used in cylinder - piston units of reciprocating compressors.

The level of technology.

There is, for example, a differential cylinder of the fourth, second and sixth stages of compression of a six-stage piston compressor (Plastinin P.I. Piston compressors. Volume 2. Design Basics. Designs. M: KolosS, 2008, p. 600, sheet A.2.32, [ one]). As in the claimed technical solution, said cylinder comprises a cylinder of a lower stage, a cylinder of a higher stage and a cylinder of a middle stage.

At the analogue [1], the cylinder of the middle stage is made integral with the cylinder of the lower stage. A sleeve is installed in each cylinder. At the end of the cylinder cover of the senior stage, a combined valve is installed.

A differential piston cylinder of a five-stage compressor is also known (Internet resource http://kmzv.ru/wp-content/uploacls/2014/10/5-101.jpq, 12/30/2015, 15:11, [2]). As in the claimed technical solution, the specified cylinder contains interconnected cylinder of the second stage, cylinder of the fourth stage and cylinder of the fifth stage. In this case, valve seats are made in each of the cylinders.

The specified analogue [2] is the set of essential features the closest analogue of the same purpose to the claimed technical solution. Therefore, it is adopted as a prototype.

The technical problem, the solution of which is provided by the implementation of the proposed technical solution, is to create a compact differential cylinder, which allows to reduce the size of the compressor and use such a compressor in small compressor stations.

At the analogue [1], the combined valve is installed at the end of the cover. This increases the length of the entire composite cylinder and prevents the solution of a technical problem.

The prototype [2] the connecting section of the cylinder of the second stage is connected to the flange of the cylinder of the second stage and has a large length. The shape of the cylinder cover of the fifth stage is elongated along the axis. This shape of the cover is due to the fact that a combined valve is installed at the end of the cover. The large length of the connecting section of the second stage cylinder and the elongated shape of the fifth stage cylinder cover increase the length of the entire differential cylinder. The increase in the length of the differential cylinder leads to the fact that the opposed compressor is difficult to place under the hood of a compact compressor station.

Disclosure of the essence of the claimed technical solution.

The technical result provided by the claimed technical solution is to reduce the length of the differential cylinder.

The essence of the claimed technical solution lies in the fact that the cylinder of the reciprocating compressor contains interconnected cylinder of the middle stage, the cylinder of the lower stage and the cylinder of the senior stage. In this case, valve seats are made in each of the cylinders. It differs in that:

- the cylinder of the middle stage contains a protruding portion located along the axis of the cylinder from the side of the first end;

- the protruding section of the cylinder of the middle stage is installed in the cylinder of the lower stage;

- valve seats of the upper stage cylinder are located on the sides of the cylinder.

The above essence is a combination of essential features of the claimed technical solution, ensuring the achievement of the claimed technical result "reducing the length of the differential cylinder".

In special cases, it is permissible to carry out the technical solution as follows.

The lateral surface of the protruding section of the cylinder of the middle stage is mainly made stepped. At the same time, sealing rings are installed at the end of the protruding section.

The senior stage cylinder may include a housing and an end cap. The valve seats of the upper stage cylinder are made in the end cap of the cylinder, and the axis of the valve seats are perpendicular to the axis of the cylinder.

The authors of the claimed technical solution made a prototype of this solution, the tests of which confirmed the achievement of the technical result.

A brief description of the drawings.

The figure shows a diagram of a differential cylinder.

Implementation of a technical solution.

The differential cylinder of the piston compressor (Fig.) Is part of the cylinder - piston group of the fourth, second and fifth stages of the piston compressor 2GM2.5-10 / 251. The differential cylinder contains interconnected cylinder of the middle stage (1), the cylinder of the junior stage (2) and the cylinder of the senior stage (3).

The middle stage cylinder (1) is designed for the fourth compression stage and is located on the compressor bed side. An axial hole for sealing elements, an axial hole for a sleeve, gas suction and discharge cavities, a cooling cavity (4) and valve seats (5) are made in the cylinder body of the middle stage (1).

The hole for the sealing elements and the hole for the sleeve communicated with each other. An oil seal (6) is installed in the hole for the sealing elements, which prevents leakage of compressible gas at the place where the stem exits the middle stage cylinder (1). The first sleeve (7) is installed in the hole under the sleeve, the inner surface of which is the working surface of the middle stage cylinder (1).

On the cylinder of the middle stage (1), gas inlet and outlet openings (not shown) are made. Around the above holes are fixed studs. This design allows you to simplify the connection of the gas inlet and outlet openings with communication details.

The cylinder of the middle stage (1) contains a protruding section (8) located along the axis from the side of the first end of the cylinder (1). The lateral surface of the protruding section (8) is made stepwise. The second end of the cylinder of the middle stage (1) is connected to the bed or remote lamp.

The cylinder of the junior stage (2) is intended for the second stage of compression. In order to reduce the length of the differential cylinder, a protruding section (8) of the middle stage cylinder (1) is installed in the cylinder of the lower stage (2). In this case, the end face of the cylinder of the lower stage (2) abuts against the cylinder of the middle stage (1). This configuration of the cylinders allows not to use a sleeve in the connection of the cylinders and reduces the lengths of the mating sections of the two cylinders. Due to this, the length of the entire differential cylinder is reduced. In addition, the parts are positioned with each other with greater accuracy.

A working cavity (9), gas cavities (10), first and second cooling cavities (11, 12) and valve seats (13) are made in the cylinder body of the lower stage (2).

A second sleeve (14) is installed in the working cavity (9) of the cylinder of the lower stage (2). The inner surface of the second sleeve (14) is the working surface of the cylinder of the lower stage (2).

The first cooling cavity (11) is designed to remove heat from the friction surface of the cylinder of the middle stage (1) and is formed by the lateral surface of the protruding section (8) and the inner walls of the cylinder of the lower stage (2). Due to this, the design of the cylinder of the middle stage (1) is simplified. The second cooling cavity (12) is designed to remove heat from the friction surface of the cylinder of the lower stage (2) and is formed by the inner walls of the cylinder of the lower stage (2) and the outer surface of the second sleeve (14).

The axes of the valve seats (13) are perpendicular to the axis of the lower stage cylinder

(2).

On the cylinder of the lower stage (2), gas inlet and outlet openings (not shown) are made. Around the above holes are fixed studs.

The cylinder of the senior stage (3) is designed for the fifth stage of compression and contains a housing and an end cover (15). A through axial bore hole, valve seats (16), a cooling cavity (17) and an equalization cavity (18) are made in the cylinder body of the senior stage (3). A sleeve (19) is installed in the through axial bore hole, into which the third sleeve (20) is installed. In this case, the sleeve (19) and the third sleeve (20) are made with a stepwise change in the diameters of their outer and inner surfaces, respectively.

The presence of the equalization cavity (18) provides a larger volume of gas in the sub-piston space - the space located on the back of the piston relative to the working chamber. This leads to a decrease in energy, which must be spent on the forward and reverse movement of the piston of the senior stage.

In order to reduce the length of the differential cylinder, the valve seats (16) of the upper stage cylinder (3) are located on the sides of the cylinder (3). In this case, the valve seats (16) are made in the end cover (15) of the cylinder (3), and the axis of the valve seats (16) are perpendicular to the axis of the cylinder (3).

Examples of specific performance.

Example 1. The cylinder of the senior stage (3) contains two valve seats (16), which are diametrically opposed.

Example 2. At the end of the protruding section (8) of the cylinder of the middle stage (1), grooves are made in which the sealing rings (21) are installed. In this case, the sealed end of the protruding section (8) is mated to the walls of the cylinder of the lower stage (2).

The implementation of the proposed technical solution is not limited to the above examples.

Description of use.

When using the claimed differential cylinder in the protruding section (8) of the cylinder of the middle stage (1) install the first sleeve (7). Then, the cylinder of the lower stage (2) is installed on the protruding section (8) of the cylinder of the middle stage (1) until it stops in the cylinder of the middle stage (1). After that, a second sleeve (14) is installed in the through axial bore of the lower stage cylinder (2).

After that, the cylinder of the middle stage (1) is fixed on the bed or the remote lamp of the bed.

Then, a differential piston is installed into three stages of compression inside said assembly unit.

After that, the cylinder of the senior stage (3) is fixed on the cylinder of the lower stage (2). Then, in the through axial bore of the upper stage cylinder (3), a sleeve (19) is installed, and a third sleeve (20) is installed in the sleeve (19).

After that, the end cover (15) is fixed on the cylinder of the upper stage, In the valve sockets (16) of the end cover (15), the valves (22) are fixed. In this case, one of the valves is suction, and the other is discharge.

The cooling cavities (4, 11, 12, 17) of the differential cylinder are connected to the compressor cooling system.

The differential piston at three stages of compression is driven through a rod, which is connected to a drive motor through a transmission chain.

During operation, the compressor piston performs longitudinal reciprocating movements. Alternately, the pistons of different stages move to their dead spots. Moreover, if the pistons of the lower and middle stages are at top dead center, the piston of the highest stage is at bottom dead center and vice versa.

When each compressor piston moves from top dead center to bottom dead center, gas enters the cylinder displacement through the suction valve. When the piston moves backward, the gas is compressed and exits the cylinder through the discharge valve. Next, the intake-compression cycle is repeated.

Industrial applicability.

The claimed technical solution is implemented using industrially produced devices and materials, can be assembled at any engineering company and will be widely used in the field of compressor engineering.

Claims (6)

1. A differential cylinder of a reciprocating compressor, comprising interconnected cylinder of the middle stage, cylinder of the lowest stage and cylinder of the senior stage, wherein valve seats are made in each of the cylinders, characterized in that - the cylinder of the middle stage contains a protruding portion located along the axis of the cylinder from the side of the first end; - the protruding section of the cylinder of the middle stage is installed in the cylinder of the lower stage; - valve seats of the upper stage cylinder are located on the sides of the cylinder. 2. The cylinder according to claim 1, characterized in that the lateral surface of the protruding portion is stepped, with sealing rings being installed at the end of the protruding portion. 3. The cylinder according to claim 1, characterized in that the upper stage cylinder comprises a housing and an end cover, wherein the valve seats of the upper stage cylinder are made in the end cover of the cylinder, the axis of the valve seats being perpendicular to the axis of the cylinder.