RU2573730C2 - Double action cylinder - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: double action cylinder contains a casing 1 in which connected with each other gland cavity 12 and valve holes 13, 14 are made. On the body 1 side surface the alternating along the casing 1 rib sections 8 and smooth sections 9 are made. The smooth sections 9 have plat surfaces. Hole 16 for the sealing chambers is located in the rib section of the casing 8. The valve holes 13, 14 are made in smooth sections 9.

EFFECT: uniform cylinder cooling, simple design and reduced cylinder weight.

4 cl, 5 dwg

Description

The field of technology.

The claimed technical solution relates to the field of compressor engineering and is intended for use in cylinder piston assemblies of reciprocating compressors.

The prior art.

Among the cylinders of reciprocating compressors, for example, cylinders of the first and second stages of a two-stage opposed compressor company Neumann & Esser are known (G. Pospelov and other Volumetric compressors. Atlas of designs. M .: Engineering, 1994, S. 39 , sheet 28, [2]). As in the claimed technical solution, each of these cylinders is made of double action and contains a housing in which the gland cavity, the working cavity and valve openings interconnected are made.

Each of these cylinders also contains cooling cavities in which the cooling cylinder flows water. The first cooling cavity is located between the walls of the valve openings and is designed to cool the working cavity. The second cooling cavity has common walls with the seal cavity through which heat exchange between the cavities takes place.

The body of each cylinder is made in the form of a cast part of a cylindrical shape. On the side surface of the housing, under each pair of valve openings, a common tide is made.

The disadvantage of this analogue is that the cylinder is made with water cooling. Firstly, this complicates the design of the cylinder and leads to the need for casting, since the design of the cylinder is multi-walled and in the spaces between the walls of the cylinder it is necessary to perform cooling cavities. Moreover, the presence of cooling cavities leads to an increase in the size of the part and its material consumption. Secondly, when water cooling the cylinder, it is necessary to use mechanisms of forced circulation of the liquid, for example pumps.

Disclosure of the claimed technical solution.

The technical problem to which the claimed technical solution is directed is to ensure effective cooling of the double-acting cylinder, as well as improving manufacturability and reducing the weight of the cylinder.

The technical result provided by the claimed technical solution is the uniform cooling of the cylinder, as well as simplifying the design and reducing the mass of the cylinder.

The essence of the claimed technical solution lies in the fact that the double-acting cylinder contains a housing in which the gland cavity, the working cavity and valve openings interconnected are made. It differs in that:

- on the side surface of the housing, finned sections and smooth sections alternating along the body are made, while the smooth sections have flat surfaces;

- the hole for the sealing chamber is located in the ribbed section of the housing;

- valve openings are made in smooth areas.

The above essence is a combination of essential features of the claimed technical solution, ensuring the achievement of the claimed technical result "uniform cooling of the cylinder, as well as simplifying the design and reducing the mass of the cylinder."

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

The fin sections are preferably cylindrical.

The valve openings for the suction valves are advantageously located on one side of the side surface of the housing, and the valve openings for the discharge valves are located on the opposite side.

It is advisable to arrange the ribs radially.

The author 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 1 shows a perspective view of a double-acting cylinder assembly; figure 2 is a longitudinal section of a double-acting cylinder with a plane passing through the axis of the valve holes; figure 3 is a longitudinal section of a double-acting cylinder with a plane perpendicular to the axes of the valve openings; figure 4 is a view of the first end of the double-acting cylinder; figure 5 is a view of the second end of the double-acting cylinder.

Implementation of a technical solution.

The double-acting cylinder (Fig. 1) is intended for use in lubricated compressors and contains a housing (1), a sleeve (2) and a cover (3).

The housing (1) (Figs. 2, 3) is a one-piece turned part made mainly of high-quality high-grade steel grade 45 Steel GOST 1050-88. The housing (1) can be made of steel 40X, or steel 50, or steel 50G2.

On the side of the first end of the housing (1), a flange (4) is made, designed to interface the inventive cylinder with a bed or a remote lamp. The cross-sectional area of the flange (4) is larger than the cross-sectional area of other structural elements of the cylinder, which allows to increase the strength of the connection between the cylinder and the bed or the remote lamp, and not to use the support. The flange (4) is provided with a chamfer (5) from the side opposite to the first end of the cylinder. The presence of the chamfer (5) facilitates the mass of the cylinder and does not affect the strength characteristics of the flange (4).

A shoulder (7) and blind threaded holes (6) are made at the first end of the housing (1) (Fig. 4). Blind threaded holes (6) are equidistant from the axis of the housing (1) and are intended for installation of studs in them, by which the cylinder is fixed on a bed or a remote lamp. Burt (7) is designed to center the cylinder relative to the mating surface.

On the side surface of the housing (1), finned sections (8) and smooth sections (9) alternating along the body (1) are made, which ensures uniform cooling of the cylinder.

The fin sections (8) have a cylindrical shape. The ribs in these areas increase the cooling effect, and they are performed by cutting grooves at an equal distance from each other. In this case, the ribs are arranged radially.

Smooth sections (9) have flat surfaces. The implementation of sections (9) with smooth and flat surfaces simplifies the design of the cylinder and reduces its mass. The flat surfaces of the sections (9) are performed by milling the side surface of the housing (1) in the vertical and horizontal planes, until, for example, a rectangle of the required dimensions is obtained in a longitudinal section.

At the second end of the housing (1), a seating surface (10) is made under the cover (3) (Fig. 5). On the landing surface (10) under the cover (3), a recess (11) and blind threaded holes are made. The recess (11) is designed to place gaskets between the cover (3) and the end of the housing (1), in order to ensure the tightness of the connection between the housing (1) and the cover (3). Blind threaded holes are designed to install studs in them and are equidistant from the axis of the housing (1).

Inside the housing (1), the gland cavity, the working cavity (12) and valve openings (13, 14) communicated to each other are made.

The gland cavity contains adjacent and interconnected axial bore (15) for the gland flange and a bore (16) for the sealing chambers.

The hole (15) for the gland flange is made at the first end of the housing (1) and is designed to secure the gland flange in it, which reduces the length of the cylinder. On the end surface of the hole (15) for the gland flange, blind threaded holes (17) are made, which are designed to install studs in them, with which they fix the gland flange. The diameter of the hole (15) for the packing flange is larger than the diameter of the opening (16) for the sealing chambers, since the packing flange secures the sealing chambers in the cylinder and its diameter is larger than the diameter of the set of sealing chambers.

The hole (16) for the sealing chambers is made in the ribbed section (8) of the housing (1), with the aim of more intensive heat removal from the stuffing box

The working cavity (12) is an axial stepped cylindrical hole and is in communication with the seal cavity with an opening (18) for the passage of the rod. On the surface of the working cavity (12), the first section (19) is made for the piston part to exit the sleeve, the seating surface (20) under the sleeve and the second section (21) is for the piston part to exit the sleeve. In this case, the landing surface (20) under the sleeve is located between the sections (19, 21) for the piston to exit the sleeve. The first section (19) for the piston part to extend beyond the sleeve is made from the side of the stuffing box cavity and has a diameter less than the diameter of the section (20) under the sleeve. In the first section (19), for the part of the piston to leave the sleeve, valve openings (13, 14) are made for the suction and discharge valves. The diameter of the second section (21) for the part of the piston to go beyond the sleeve is equal to the diameter of the section (20) under the sleeve. The diameter of the second section (21) for the part of the piston to go beyond the sleeve may be larger than the diameter of the section (20) under the sleeve. This simplifies the installation of the sleeve, since during installation its surface is not deformed. In the second section (21), for the part of the piston to go beyond the sleeve, valve openings (13, 14) are also made for the suction and discharge valves. The execution on the walls of the working cavity (12) of sections (19, 21) for the piston to exit the sleeve allows to simplify the design and increase the reliability of the sleeve, since there is no need to make valve holes on the sleeve. In addition, by changing the diameters and lengths of the above sections (19, 21), it is possible to adjust the amount of dead space in the cylinder.

The sleeve (2) is installed in the working cavity (12) and abuts against the step of changing the diameter between the seating surface (20) under the sleeve and the first section (19) for the piston to exit the sleeve. In the housing (1) and the sleeve (2), matching holes are made for the grease fitting. The holes are located in the middle of the working surface of the sleeve (2) and their axes intersect with the axis of the housing (1). At the same time, the hole for the body lubrication supply fitting (1) is threaded.

Valve holes (13, 14) are made on smooth sections (9) of the housing (1). Since the inventive cylinder is made of double action, i.e. with two working cavities, the valve openings (13) for the suction valves are located on one side of the side surface of the housing (1), and the valve openings (14) for the discharge valves are located on the other side, preferably the opposite.

In each valve hole (13, 14), a fitting (23) with a thread on the end is detachably fixed.

A flange is made on the side surface of the fitting (23), designed to connect the fitting to the body. At the same time, on the body (1) around each valve hole (13, 14), mounting holes are made for fixing the aforementioned flange. The thread at the end of the fitting (23) is made external. Threading at the end of the fitting (23) simplifies the installation of gas pipelines on the cylinder. The opposite end of the fitting (23) is designed to center the fitting in the valve hole (13, 14) and presses the valve with the necessary force.

On the inner surface of the fitting (23), conical surfaces (24) are made at its ends.

A nipple (25) is installed in the hole of the fitting (23). A collar (26) is made on the lateral side surface of the nipple (25), and the end of the nipple (25) is conical. In this case, the conical end of the nipple (25) abuts against the conical surface (24) of the end of the fitting (23). A union nut (27) with a flange is screwed onto the thread of the fitting (23), which fastens the fitting (23) with a nipple (25). In this case, the flanging of the nut (27) abuts against the shoulder (26) of the nipple (25). The connection of the fitting (23), nipple (25) and nut (27) described above is tight and prevents gas leakage.

The cover (3) is mounted on the second end of the housing (1) and has a convex part, which is placed in the working cavity (12).

The order of use.

A sleeve (2) is installed in the working cavity (12) from the side of the second end of the housing (1). In this case, the sleeve (2) abuts against the step of changing the diameter between the seating surface (20) under the sleeve and the first section (19) to leave the piston for the sleeve. The stuffing box chambers are installed in the hole (16) under the sealing chambers, and in the hole (15) under the stuffing box flange, the stuffing box flange is fixed with studs. In this case, a gasket is placed between the gland flange and the end surface of the landing hole (15) under the flange.

Valves are installed in the valve openings (13, 14). Then, a fitting (23) is fixed in each valve hole, which presses the valve. A nipple (25) is installed in the hole of the fitting (23), and then the fitting (23) is fixed with the nipple (25) with a nut (27).

The resulting assembly unit is fastened with a flange (4) to the bed lamp or the remote lamp. In this case, studs are screwed into the threaded holes (6) of the first end of the housing (1), and then the cylinder is mounted with studs in the mating holes on the mating surface. In this case, the housing (1) is centered on the shoulder (7).

Then, inside the working cavity (12) with a sleeve (2), a connecting rod-piston group assembly is installed.

After that, on the landing surface (10) under the cover fasten the cover (3).

The connecting rod-piston group is driven through a transmission chain from a drive motor. Gas compression is carried out by both sides of the piston, respectively, in two working cavities of the cylinder. The gas compressed in the cylinder enters the compressor communication.

Industrial applicability.

The claimed technical solution is implemented using industrially produced devices and materials, can be manufactured at any engineering enterprise and will find wide application in the field of compressor engineering.

Claims (4)

1. A double-acting cylinder, comprising a housing in which a gland cavity, a working cavity and valve openings, interconnected, are made, characterized in that
- on the side surface of the housing, finned sections and smooth sections alternating along the body are made, while the smooth sections have flat surfaces;
- the hole for the sealing chamber is located in the ribbed section of the housing;
- valve openings are made in smooth areas. 2. The cylinder according to claim 1, characterized in that the finned sections are cylindrical in shape. 3. The cylinder according to claim 1, characterized in that the valve openings for the suction valves are located on one side of the side surface of the housing, and the valve openings for the discharge valves are located on the opposite side. 4. The cylinder according to claim 1, characterized in that the ribs are arranged radially.

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