RU144564U1 - STOCK OF COMPONENT DIFFERENTIAL PISTON - Google Patents

Abstract

1. The rod of the composite differential piston of the reciprocating compressor, which is a rod, at one end of which a connecting section is made, and at the other end there is a section with an external thread, between which a shoulder is made, characterized in that - on the first end of the rod from the side of its connecting section made a blind threaded central hole for securing the end of the rod of the previous stage; - at least two are made at the edge of the connecting section from the side opposite to the first end of the rod e flats that are parallel to each other. 2. The stem according to claim 1, characterized in that the flats are equidistant from the axis of the stem. The stem according to claim 1, characterized in that the cross-sectional area of the connecting section is larger than the cross-sectional area of the other structural elements of the rod. The rod according to claim 1, characterized in that between the connecting section and the shoulder made a free section.

Description

The field of technology.

The claimed technical solution relates to the field of compressor engineering and is intended to connect the piston of the highest compression stage with the piston group of the lower compression stage.

The prior art.

Among the rods of differential pistons, for example, the rod of a differential piston of the sixth stage of a compressor is known (Strakhovich K.I., Frenkel M.I., I.K. Kondryakov, V.F. Fig. Compressor machines. M.: State publishing house of commercial literature , 1961.P. 140, Fig. 53). As in the claimed technical solution, this analogue is a rod, at one end of which a connecting section is made, and at the other end there is a section with an external thread, between which a shoulder is made.

At the indicated analogue, the connecting section is fixed in the piston of the previous stage, has a cylindrical lateral surface, and its end is provided with an external thread. Burt has a smooth cylindrical side surface.

The disadvantage of this analogue is that in the case of a threaded connection of the connecting section of the rod and the piston of the previous stage, the rod rotates when it is tightened with a wrench.

Disclosure of the claimed technical solution.

The technical problem to which the claimed technical solution is directed is to provide the possibility of tightening the rod on the rod of the previous stage.

The technical result provided by the claimed technical solution is the exception of the rotation of the rod when it is tightened with a wrench on the rod of the previous stage.

The essence of the claimed technical solution lies in the fact that the rod of the composite differential piston of the reciprocating compressor is a rod, at one end of which a connecting section is made, and at the other end a section with an external thread is made. It differs in that:

- at the first end of the rod from the side of its connecting section, a blind threaded central hole is made to secure the end of the rod of the previous stage;

- at the edge of the connecting section from the side opposite the first end of the rod, at least two flats are made that are parallel to each other.

The above essence is a combination of essential features of the claimed technical solution, ensuring the achievement of the claimed technical result "the exception of the rotation of the rod when it is tightened with the key on the rod of the previous stage".

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

The flats are preferably equidistant from the axis of the stem.

The cross-sectional area of the connecting section is predominantly larger than the cross-sectional area of the other structural elements of the stem.

Between the connecting section and the shoulder, preferably a free section is made.

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 the stem of a composite differential piston of a reciprocating compressor; in FIG. 2 is a section A-A of FIG. one; in FIG. 3 is a view B of FIG. one; FIG. 4 - locking rod during its implementation according to example 1; FIG. 5 - locking rod during its implementation according to example 2; FIG. 6 - locking rod during its implementation according to example 3; FIG. 7 - rod assembly with the remaining structural elements of the differential piston.

Implementation of a technical solution.

The rod of the composite differential piston (Fig. 1) is a rod, at one end of which a connecting section (1) with internal thread is made, and at the other end there is a section with external thread (2), between which a collar (3) is made.

At the first end of the rod from the side of its connecting section (1), a blind threaded central hole (4) is made in which the end of the rod of the previous stage is fixed. At the bottom of the aforementioned hole (4), a groove (5) is made for the exit of the cutting tool.

The cross-sectional area of the connecting section (1) is larger than the cross-sectional area of the other structural elements of the rod. At the edge of the connecting section (1) from the side opposite to the first end of the rod, at least two flats (6) are made (Fig. 2). The flats (6) are designed to eliminate the rotation of the rod when it is tightened with the key on the rod of the previous stage. The flats (6) are equidistant from the axis of the rod and parallel to each other.

The connecting section (1) is provided with at least one means of locking against self-unscrewing. The connecting section can be equipped with two means of locking from self-unscrewing, made in the form of two flat sections (7) (Fig. 3). Flat sections (7) are located symmetrically relative to the axis of the rod, while the surface of each flat section (7) is located at an acute angle to the axis of the rod. Flat sections (7) are used to ensure the possibility of fixing the inventive rod on the rod of the previous stage.

Burt (3) is designed to hold against axial movement of the piston parts located on the rod. Between the connecting section (1) and the shoulder (3) a free section (8) is made, which is not mated with other parts.

The section with an external thread (2) is designed for interfacing with a nut that secures the piston parts located on the rod. Section (2) with an external thread contains at least one through radial hole (9), which serves to install a cotter pin.

Between the section with the external thread (2) and the shoulder (3), a seating surface (10) is made for the first spherical washer and a seating surface (11 is for the second spherical washer, between which the surface (12) covered with a gap is made.

Landing surfaces (10, 11) under the first and second spherical washers are designed to interface with spherical washers, in which one end has a flat surface and the other is spherical.

Between the seating surface (10) under the first spherical washer and the shoulder (3), the seating surface (15) is made for the expansion ring. In order to avoid crushing of the expansion ring, the flat surface of the shoulder (3) from the side of the seating surface (15) under the expansion ring is ground, for example, with a roughness of 0.4, and is perpendicular to the axis of the rod.

The diameter of the seating surface (10) under the first spherical washer is larger than the diameter of the seating surface (11) under the second spherical washer. The diameter of the seating surface (11) under the second spherical washer is larger than the diameter of the portion with an external thread (2).

The diameter of the surface covered with a gap (12) is equal to the diameter of the seating surface (11) under the second spherical washer. The surface covered with a gap (12) has a relatively high roughness, the parameters of which are:

R _a = 6.3, R _z = 30,

where R _a is the arithmetic mean deviation of the profile, microns;

R _z - the height of the irregularities of the profile at ten points, microns.

Between the section with the external thread (2) and the seating surface (11) under the second spherical washer, an annular groove (13) is made for the output of the cutting tool when threading.

Examples of specific performance:

Example 1. The locking means from self-unscrewing is a cylindrical recess (29), made on the first end of the rod (Fig. 4). The cylindrical recess (29) is designed to accommodate the tabs of the lock washer.

Example 2. The means of locking from self-unscrewing is a longitudinal groove (30) made on the side surface of the connecting section (1) (Fig. 5). The longitudinal groove (30) is designed to accommodate the tabs of the lock washer.

Example 3. The locking means from self-unscrewing is a through radial conical hole (31), which is designed to install a pin in it (Fig. 6).

The order of use.

When using the inventive rod of a composite differential piston, in the blind threaded central hole (4) of the first end of the rod, the end of the rod of the previous stage is equipped with an external thread (Fig. 7). In order to fix the rods relative to each other on the threaded end of the rod of the previous stage, a retaining ring (14) equipped with folding legs is pre-installed. A part of the tabs of the retaining ring (14) is folded into flat sections of the first piston ring (15) of the piston of the previous stage (16). The first locating ring (15) is screwed onto the rod of the previous stage and fixed with a pin (17) against angular displacement relative to the piston of the previous stage (16). In turn, the piston of the previous stage (16) is fixed relative to the rod by the second mounting ring (18) with a pin (19).

Then, on the flats (6) of the connecting section (1) of the inventive rod, a key is put on and the inventive rod is screwed onto the threaded end of the rod of the previous stage. The flats (6) exclude the rotation of the rod when it is tightened with the key on the rod of the previous stage.

The inventive rod is screwed onto the rod of the previous stage until it stops in the circlip (14), after which part of the tabs of the circlip (14) are bent into flat sections (7) of the inventive rod. Thus, flat sections (7) provide the ability to lock the threaded connection of two rods. Performing flat sections (7) at an acute angle to the axis of the rod reduces the bending angle of the tabs of the retaining ring (14), which eliminates the possibility of breakage.

If the inventive rod is made according to example 1, then it is locked with a washer with a foot. In this case, the first locating ring (15) is provided with a flat. The washer foot is bent into a cylindrical recess (29) of the first end of the rod, and the edge of the washer is bent on the flats of the first locating ring (15).

If the inventive rod is made according to example 2, then the tab of the washer is bent into the longitudinal groove (30) of the side surface of the connecting section (1) of the inventive rod, and the edge of the washer is folded to the flange of the mounting ring (15).

If the inventive rod is made according to example 3, then it is locked with a conical pin, which is installed in the through conical radial hole (31) of the connecting section (1) of the inventive rod and the through radial hole of the end of the second rod.

After fixing the rod on the seating surface (15), a compensating ring (20) is installed under the expansion ring, which is made flat and metal, for example, from 30X13 steel.

Then, on the landing surface (10), under the first spherical washer, a first spherical washer (21) is placed, which is concave. The first spherical washer (21) is placed so that its flat end is in contact with the expansion ring (20).

After that, a third spherical washer (22), a sleeve (23) and a fourth spherical washer (24) are sequentially placed on the surface covered with a gap (12). The third and fourth spherical washers (22, 24) are made convex. The third and fourth spherical washers (22, 24) are placed so that their flat ends are in contact with the flat ends of the sleeve (23).

Then, on the landing surface (11), a second spherical washer (25) is placed under the second spherical washer, which is concave. The second spherical washer (25) is placed so that its concave end is in contact with the convex end of the fourth spherical washer (24).

After that, a flat washer (26) is installed in the area with the external thread (2) until it stops in the step of changing the diameter between the seating surface (11) under the second spherical washer and the area with the external thread (2). The flat washer (26) serves as a stop for the second spherical washer (25).

Then, a castellated nut (27) is screwed onto the end of the external thread section (2). After one of the nut grooves coincides with the through radial hole (9) of the rod, a cotter pin is installed in the above groove and hole (9). Then the ends of the cotter pin are bred and bent on the verge of a nut.

The outer surface of the sleeve (23) is provided with a thread through which a piston (28) is screwed onto the sleeve (23). The radial clearance in the connection of the rod with the washers (21, 22, 24, 25) and the sleeve (23) allows the piston to perform radial movements, and due to the set of spherical washers (21, 22, 24, 25), the piston can make angular movements.

For the normal operation of each pair of adjacent spherical washers (21, 22) and (24, 25), it is necessary that the movement of the third and fourth spherical washers (22, 24) relative to the first and second (21, 25) be easy and free. For this, between the flat washer (26) placed on the rod and the set of spherical washers (21, 22, 24, 25) with the sleeve (23), an axial clearance K is made, the value of which is not more than 0.05 mm. The increase in the gap occurs when the spherical washers (21, 22) and (24, 25) are abraded against each other during operation of the piston. To create the optimal axial clearance K, a compensating ring (20) is installed between the first spherical washer (22) and the shoulder (3). The axial size of the expansion ring (20) compensates for the total deviation of the axial dimensions of the spherical washers (21, 22, 24, 25) and the sleeve (23), when installed on the rod, and provides the required clearance K. When the clearance K increases, the expansion ring (20 ) can be replaced with a new one, while there is no need to replace all spherical washers (21, 22, 24, 25). The flat surface of the shoulder (3) from the side of the seating surface (15) under the expansion ring should not have a high roughness, otherwise the surface of the expansion ring (20) is crushed and needs to be replaced more often. For this, the flat surface of the shoulder (3) from the side of the landing surface (15) under the expansion ring (20) is ground and perpendicular to the axis of the rod.

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. The rod of the composite differential piston of the reciprocating compressor, which is a rod, at one end of which a connecting section is made, and at the other end is a section with an external thread, between which a shoulder is made, characterized in that - at the first end of the rod from the side of its connecting section, a blind threaded central hole is made to secure the end of the rod of the previous stage; - at the edge of the connecting section from the side opposite the first end of the rod, at least two flats are made that are parallel to each other. 2. The stem according to claim 1, characterized in that the flats are equidistant from the axis of the stem. 3. The rod according to claim 1, characterized in that the cross-sectional area of the connecting section is larger than the cross-sectional area of other structural elements of the rod. 4. The rod according to claim 1, characterized in that between the connecting section and the shoulder made a free section.