RU2383745C2 - Rotary positive-displacement machine (versions) and rotary positive-displacement machine stage - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention relates to machine building, particularly to positive-displacement rotary machines. Machine chamber comprises housing, rotor with output shaft running in said housing and having work surface concentric with its rotational axis, and at least one piston. Said work surface consists of surface inclined to rotor rotational axis and segment of sphere limited by aforesaid inclined surface. Housing and rotor work surfaces make work chamber. Rotor work surface has at least one slot arranged along rotor rotational axis. Rotor every slot accommodates piston to cover and seal work chamber and to run in slot plate. Piston represents, at least, a part of disk with at least one sealing synchronising element to interact with the housing inclined surface. Said element is coupled with piston with the help of pivot joint arranged on aforesaid sealing synchronising element. The latter represents two aligned cylindrical recesses and mating pivot joint arranged on piston to revolve relative to piston. Cylindrical ledge is arranged between aforesaid cylindrical recesses.

EFFECT: possibility to be used in multi-stage deep-well pumps.

13 cl, 20 dwg

Description

FIELD OF THE INVENTION

The invention relates to the field of engineering, namely to rotary volumetric machines, which can be used as pumps, compressors, hydraulic drives, etc., in particular in multi-stage submersible plants.

State of the art

Known volumetric rotary machine (ORM) (RU 2004133654,), which has a housing with an internal cavity of an annular shape. In this cavity, a spiral-shaped separator is installed in which the rotor is mounted. The working surface of the rotor is a surface of revolution, in which there is at least one groove along the axis of rotation of the rotor, in each of which a piston is installed that can rotate partially protruding from one side of the rotor. At the same time, the piston has at least one through-cut along the perimeter, interacting with the separator, to synchronize the rotation of the piston with the rotation of the rotor. The machine entry window and the machine exit window are spaced along the axis of the rotor and are separated from each other by a separator. The piston of such a machine rotates in one direction relative to the rotor and together with the rotor rotates relative to the housing.

Such a machine has the following advantages.

The piston is securely installed in the slot of the rotor, protruding from it by a part of about half.

The spacing of the entry and exit windows along the axis of the rotor makes it easy to combine such machines into multi-stage ones, including with a common rotor for many stages. Such machines are used in submersible installations. The common rotor allows you to remove the load from the radial, and often from the thrust bearings of the rotor due to balancing the loads of the individual stages when they are rotated relative to each other.

A significant advantage of the pump, created on the basis of such a machine, is the constant flow.

The disadvantage of such machines is the complicated shape of the separator and piston slots, which do not allow their contact over a large area, to reduce the wear of this friction pair (to reduce the ideal load on this friction pair and to increase its life).

Known ORM (GB 1458459 and similar to it DE 3206286 A1), in which the body has a cavity in the form of a segment of a sphere in which a separator is installed along the axis of symmetry of the cavity in the form of a sector of a circle overlapping the cavity; a rotor mounted rotatably in the housing, with a working surface in the form of two truncated cones, supported by vertices on a sphere from opposite sides, and on the surface of the sphere (within the working cavity), at an angle to the axis of symmetry of the rotor, there is an annular groove made with respect to to both cones. In this groove, a piston is mounted rotatably relative to the rotor, in which there is a slot capable of passing the separator. Moreover, the piston interacts with the separator through the sealing synchronizing element (SSE), made in the form of a cylinder, cut in half, with a groove starting at one end and going almost to the second end. The entrance window of the working fluid and the corresponding exit window are located on one side of the piston. On the other side of the piston there is a pair of entry and exit windows. The piston of such a machine oscillates relative to the housing, and the rotor of the machine rotates relative to the oscillating piston.

The advantages of such a machine are as follows: good contact between the piston and the housing chamber on a spherical surface, good contact between the piston, the sealing element and the separator, simple geometric shapes: a flat separator, a flat piston, etc.

ORM also has drawbacks: the inconvenience of combining such a machine into a multi-stage machine, due to the fact that the entry and exit windows are on one side of the piston, and for passage from stage to stage, it is necessary to make a channel bypassing the spherical cavity of the housing along the axis of the rotor. Disadvantages are also uneven delivery, poor piston fastening (only by the part sitting in the groove on the sphere), which also weakens the shaft due to the annular groove, unreliable fastening of the sealing force element in the piston groove (jamming with increasing load is possible).

Known ORM (DE 3146782 A1), which has a housing with a cavity in the form of a segment of a sphere, a rotor mounted for rotation, in which a through cut is made along the axis of the rotor. There is also a piston in the form of a disk mounted in the groove of the rotor with the possibility of rotation, a camera in the form of a spherical segment, partitioned by a separator in the direction of rotation of the rotor, exit and entrance windows, located before and after the separator, respectively. Moreover, the rotation of the piston is synchronized with the rotation of the rotor by means of a shaft that moves motionlessly through the rotor and the gear system, one of which is mounted on the piston. The piston of such a machine rotates in one direction relative to the rotor and together with the rotor rotates relative to the housing.

The advantages of this machine are the spherical contact of the piston and the chamber, the reliability of fastening the piston protruding on both sides of the shaft, the presence of a strong shaft (the longitudinal groove weakens it a little), the ability to withdraw (part) the entry and exit windows along the shaft to combine several steps on one shaft , independence of leaks from wear of the synchronization mechanism, the possibility of high revolutions.

The disadvantage is the unreliable synchronization mechanism, especially if you need to pass the gear shaft through several stages.

The closest analogue is ORM according to the application RU 2004133654.

Disclosure of invention

The objective of the invention is to describe and protect the site of the ORM camera ORM (KORM). It is called a camera because, due to its geometrical features, cameras are often used in pairs, although one separate camera is operable as different types of ORMs. The widespread use of KORM in multi-stage submersible pumps is assumed, therefore, the combination of two chambers in the application is called the ORM stage. In KORM, the piston mounted in the groove of the rotor rotates, but it turned out that it does not experience large inertial loads even at high RPM speeds. Because masses distributed near the line (plane), which in the middle position of the piston passes through its axis of rotation perpendicular to the axis of rotation of the rotor, perform these oscillations, largely due to the action of centrifugal forces arising from the rotation of the piston together with the rotor. Those. the natural period of oscillation of the piston is close to the period of revolution of the rotor. Installation on the piston, near the indicated line (plane), of additional sealing synchronizing elements (SSE) also practically does not increase the inertial load on it, improving the conditions for its interaction (contact and sliding) with the flat surface of the housing. Moreover, there are KORM configurations in which the piston closes the working chamber and creates a pressure drop during its stay near the extreme points of oscillation, i.e. then, when its speed relative to the rotor is minimal, which means that friction and wear losses are minimal. The result was an ORM with high specific characteristics (the ratio of power to size and weight, feed to size), with potentially large resource and reliability, geometrically simple working surfaces (plane on a plane, sphere on a sphere).

The objective of the invention is achieved in that in the chamber of a volumetric rotary machine comprising a housing, a rotor with an output shaft mounted rotatably in the housing having a working surface concentric with its axis of rotation, at least one piston,

moreover, the working surface of the housing is a surface inclined to the rotor axis of rotation and the sphere segment bounded by the inclined surface, the working surfaces of the housing and rotor form a working cavity, at least one groove is made on the working surface of the rotor along its rotation axis,

a piston is installed in each groove of the rotor with the possibility of overlapping and sealing the working cavity and performing rotational vibrations in the groove plane, the piston being made in the form of at least a part of the disk with at least one sealing synchronizing element for interacting with the inclined surface of the housing, a hinge connected to the piston, consisting of a hinge connector on the sealing synchronizing element in the form of two coaxial cylindrical recesses between which a cylindrical protrusion is located coaxially with them, and him by an articulation socket on a piston mounted to commit rotational oscillations relative to the piston.

The task is achieved in that the inclined surface of the housing is made flat.

The task is achieved in that the working surface of the rotor is made in the form of two coaxial surfaces of a truncated cone, supported by a truncated part on a sphere.

The task is achieved in that the surface of the truncated cone of the rotor interacts with the inclined surface of the housing along its generatrix.

The task is achieved by the fact that at one end of the piston is made at least one through passage on the opposite side of the piston.

The objective is achieved in that in the chamber of a volumetric rotary machine comprising a housing, a rotor with an output shaft mounted rotatably in the housing, having a working surface concentric with its axis of rotation, at least one piston, the working surface of the housing being inclined to the axis of rotation rotor surface and a sphere segment bounded by an inclined surface, working surfaces of the housing and rotor form a working cavity, at least one groove is made on the working surface of the rotor along its axis of rotation, each rotor groove has a piston installed with the possibility of overlapping (sealing) the working cavity and performing rotational vibrations in the groove plane, the piston being made in the form of at least a part of the disk with at least one sealing synchronizing element for interacting with the inclined surface of the housing, a hinge connected to the piston, consisting of a hinge connector on the sealing synchronizing element in the form of a tube, and a hinge connector mating on the piston, mounted with the possibility of making a rotator oscillations relative to the piston.

The task is achieved in that the sealing synchronizing element is made in the form of a tube with a plate.

The task is achieved by the fact that in the step of a volumetric rotary machine, consisting of two chambers, each of which contains a rotor with an output shaft, mounted in the housing with the possibility of rotation, having a working surface concentric to its axis of rotation, at least one piston, with a working surface the casing is a surface inclined to the axis of rotation of the rotor and a sphere segment bounded by an inclined surface, the working surfaces of the casing and the rotor form a working cavity, at least at least one of the working surface of the rotor is made one groove along its axis of rotation,

a piston is installed in each groove of the rotor with the possibility of overlapping and sealing the working cavity and performing rotational vibrations in the groove plane, the piston being made in the form of at least part of the disk, the chambers having a common geometric axis of rotation of the rotors and facing each other with inclined surfaces of the housings moreover, between the chambers there is a passage for the working fluid from one chamber to another in the form of several passages, with the possibility of overlapping a separate passage with a piston or sealing synchronizing element, why the step has windows of entry and exit of the working fluid.

The task is achieved in that at the stage, at least two chambers are deployed relative to the axis of rotation of the rotors at such an angle at which they work in antiphase.

The task is achieved by the fact that at the stage, at least two chambers, the inclined surfaces of the housings are parallel.

The task is achieved in that at the step the centers of the segments of the sphere of at least two chambers coincide.

The task is achieved in that at the stage, at least one piston from two different chambers is made stationary relative to each other.

The task is achieved in that at the stage, at least one sealing synchronizing element of two different chambers is installed on one common axis.

The invention is illustrated using the drawings.

Figure 1 presents in isometry the chamber of a volumetric rotary machine (KORM) with one piston with the removed part of the body. Further, in all figures, the rotor rotates clockwise when viewed from above.

Figure 2 presents in isometric three parts of the housing of the KORM in figure 1.

Figure 3 presents isometric rotor KORM in figure 1.

In Fig. 4, a piston and its two sealing synchronizing elements (SSEs) of the KORM in Fig. 1 are shown in exploded perspective.

Figure 5 presents in isometric KORM similar to KORM in figure 1 but with two pistons with the removed part of the body.

In Fig.6 is represented in isometric KORM, similar to KORM in Fig.2, but with a smaller exit window with the removed part of the body and the rotor removed (to show the chambers and the intersection of the pistons).

Figure 7 presents in isometric another variant of the intersection of the pistons.

On Fig presented in isometric exploded view of another version of the piston and SSE.

Figure 9 presents in isometric disassembled form a piston with SSE in the form of rollers.

Figure 10 presents in isometric piston with relief.

Figure 11 presents in isometry with the removed part of the housing KORM with the supply of the working fluid along the shaft. Hereinafter, the removed near part of the body unfolds half a turn and is placed on the figure on the right, and if the far part of the body is removed, then it moves to the right.

On Fig presented in isometric disassembled form of the rotor, part of the housing, the piston and SSE KORM of Fig.11.

On Fig presented in isometric stage ORM, consisting of two KORM on the same shaft, connected hydraulically, simultaneously working in antiphase with the removed halves of the body.

On Fig presents in isometric partially disassembled form (to show the relative position of the pistons) the rotor stage ORM in Fig.13 and part of the housing is a separator.

On Fig presented in isometric stage ORM, consisting of two KORM on one shaft, connected hydraulically, simultaneously working in close phases with the passage of the working fluid along the separator with the halves of the housing removed.

On Fig presents in isometric stage ORM, consisting of two KORM on one shaft, connected hydraulically, in parallel working in phase with the passage of the working fluid bypassing the working cavity through the channels between the pipe and the housing with the halves of the housing removed.

On Fig presents in isometric partially disassembled state of the assembly of two pistons with SSE having additional axes, coaxial axis of a flat inclined surface of the housing.

On Fig presents in isometric stage ORM, consisting of two KORM on one shaft, connected hydraulically, working in phase in parallel with the passage of the working fluid bypassing the working cavity through the channels between the pipe and the housing with the half of the housing removed, with a common piston.

On Fig presents in isometric common piston stage ORM in Fig. 18.

On Fig presented in isometric exploded view of the node consisting of a rotor, a common piston, and SSE stage ORM on Fig.

In all figures, elements of the same function are denoted by the same numbers, where

1 - housing;

2 - rotor;

3 - output shaft;

4 - the piston;

5 - sealing synchronizing element (SSE);

6 - the internal cavity of the housing;

7 - spherical surface of the housing;

8 - (flat) surface of the housing;

9 - a cylindrical hole for the output of the shaft;

10 - spherical recess on a flat surface of the housing;

11 - a cylindrical hole for the output of the shaft;

12 - the Central sphere of the rotor;

13 - truncated cone of the rotor;

14 - segment of the sphere of the rotor;

15 - geometric axis of rotation of the rotor;

16 - through groove in the rotor;

17 - recess in the rotor under the SSE;

18 - recess on a flat surface of the housing;

19 - spherical side surface of the piston;

20 - end surfaces of the piston;

21 - hinged connectors on the piston;

22 - spherical platforms on the piston;

23 - geometric axis of the rotational vibrations of the piston;

24 - flat face SSE;

25 - concave spherical face of the SSE;

26 - convex spherical face of the SSE;

27 - hinge connector SSE;

28 - coaxial cylindrical protrusions on the piston;

29 - a cylindrical recess on the piston;

30 - coaxial cylindrical recesses on the SSE;

31 - cylindrical protrusion on the SSE;

32 - axis of the piston swivel connectors - SSE;

33 - input window of the working fluid;

34 - exit window of the working fluid;

35 - pipe supply of the working fluid;

36 - pipe outlet of the working fluid;

37 - working cavity;

38 - working area;

39 - suction chamber;

40 - discharge chamber;

41 - pre-compression chamber;

42 - cut in the middle of the piston in the form of a sector;

43 - spherical (cylindrical) cutout in the center of the piston;

44 - arc;

45 - wide angle cut in the form of a sector;

46 - hole for the axis;

47 - axis protruding from the piston;

48 - tube;

49 - hole in the center of the piston;

50 - axis (pin);

51 - roller;

52 - relief in the form of a selection of material;

53 - channel for supplying a working fluid;

54 - channel removal of the working fluid;

55 - mounting holes;

56 - groove to prevent mashing of mechanical impurities;

57 - through holes on the piston;

58 - sealing element;

59 - the upper chamber ORM (KORM);

60 - downward section;

61 - ascending section;

62 - lower feed;

63 - passage for the working fluid from one feed to another;

64 - a small passage in angular extent;

65 - narrowing of the SSE;

66 - separator;

67 - an inclined groove under the separator;

68 - low pressure passage;

69 - passage of high pressure;

70 - pipe;

71 - rib;

72 - additional axis of SSE;

73 - additional axis with an arc;

74 - common axis of SSE;

75 - common axis with an arc;

76 - arc in the middle of the axis;

77 - a groove on the piston under the insert;

78 - insert into the piston;

79 - retractable piston seal;

80 - groove on the piston under the sliding seal;

81 - a slot on the piston under the separator;

82 - integral axis with SSE.

Description of the best model of the machine

The chamber of a volumetric rotary machine (KORM) (Fig. 1) consists of a housing 1, a rotor 2 with an output shaft 3 and a piston 4, which includes a synchronizing sealing element (SSE) 5. Housing 1 has an internal cavity 6 from which a cylindrical the hole 9 for the output of the shaft 3 of the rotor 2. The axis of the hole 9 is the geometrical axis of the KORM and the axis of rotation of the rotor 2. The cavity 6 is bounded by a spherical surface 7, coaxial hole 9, and, in general, a curved surface 8 made at an angle (on average ) to axis 15. In this version, turn The tail 8 is made flat. Near the center of the surface 8 there is a spherical recess 10 (figure 2), from which there is also a cylindrical hole 11 for the output of the shaft 3 of the rotor 2, coaxial with the cylindrical hole 9. The rotor 2 is made in the form of a set of coaxial elements (figure 1, 3): the central sphere 12, supported on it by the smaller base of the truncated cone 13, bounded by the segment of the sphere 14, concentric with the central sphere 12 and having a larger radius approximately equal to the radius of the spherical surface 7 of the housing 1, and adjacent to the listed parts from opposite sides m cylindrical ends of the output shaft 3. Along the diameter of the rotor 2 and the geometric axis 15 of rotation of the rotor 2, through the surface of the central sphere 12, cone 13 and the segment of the sphere 14, a through groove 16 is made to accommodate the piston 4. At the junction of the through groove 16 with the cone 13 there is recess 17 under SSE 5, made in the form of a chamfer. The rotor 2 is installed in the housing 1 with the possibility of rotation around its geometric axis 15. In this case, the centers of the spherical surfaces 7, 12 and 14 approximately (accurate to play, tolerances, wear) coincide. In this embodiment, the conical surface 13 of the rotor 2 interacts with the flat surface 8 of the housing 1. At the point of contact, it is allowed (more often useful) to have a small recess 18 (FIG. 2). Before the point of contact, for the removal of the abrasive, it is desirable to have a groove (not shown). The piston 4 (Figs. 1, 4) is made in the form of a disk with a spherical lateral surface 19, a smaller part of which is cut off by a chord. The radius of the surface 19 is approximately equal to the radius of the surface 7 for the possibility of rotation of the piston in the housing when creating a seal between the surfaces 7 and 19. The end surfaces 20 of the piston 4, in this design, are flat and parallel to each other. In the spherical lateral surface 19 symmetrical with respect to the plane of symmetry, perpendicular to the end surface 20, opposite parts of the piston 4, there are elements interacting with the surface 8. In this design, these are hinge connectors 21 (similar connectors are used in door hinges) with SSE 5 installed on them. K spherical platforms 22, concentric surfaces 19 adjoin the connectors 21, for contact with the spherical recess 10 of the housing 1. The piston 4 is installed in the through groove 16 of the rotor 2 with the possibility of making a rotator oscillations in the plane of the groove 16 relative to the geometrical axis 23, passing approximately (with accuracy to play, tolerances, wear) through the center of the central sphere 12 of the rotor 2 (relative to the center of the surface 19). The thickness of the piston 4 is approximately equal to the width of the groove 16 for sealing by the piston 4 of the groove 16. SSE 5 (Figs. 1, 4) has one flat face 24 for contact with the flat surface 8 of the housing 1, one concave spherical face 25 for contact with the central sphere 12 of the rotor 2, one convex spherical face 26 for contact with the spherical surface 7 of the housing 1, and on another face there is a hinge connector 27 corresponding to the hinge connector 21 of the piston 4. The hinge connector 21 on the piston 4 consists of two coaxial cylindrical protrusions 28, between which is coaxial they have a cylindrical recess 29. The hinge connector 27 on the SSE 5 consists of two coaxial cylindrical recesses 30, between which the cylindrical protrusion 31 is coaxially located. The protrusion 31 holds the SSE 5 mainly from displacement perpendicular to the flat face 24 and fastens the two halves of the SSE 5, and the recesses hold the SSE 5, mainly, from moving along a flat face 24 and from turning in the plane of this face. For this version, a rather important feature is that both hinge connectors 21 are located on the same axis 32 and the axis 32 of the hinge connectors 21 and 27 intersects (to the extent of backlash, wear tolerances) the axis 23 of the rotational vibrations of the piston 4. Due to this fact, the face 24 SSE 5 may be in constant contact with the flat surface 8 of the housing 1. In this case, the axis 32 is in the inner cavity 6 above the flat surface 8 and approximately parallel to it. The windows of the inlet 33 and the outlet 34 of the working fluid (FIGS. 1, 2) are located on a flat surface 8 and are adjacent on different sides to the point of contact of this surface with the cone 13 of the rotor 2. The ORM has a supply pipe 35 and a branch pipe 36 of the working fluid. The working cavity 37 KORM is limited by the spherical surface 7 of the housing 1, the conical surface 13 and the central sphere of the rotor 2. The working surface of the rotor 2, i.e. the surface bounding the working cavity 37 and interacting with the housing 1 for sealing the chamber consists of surfaces 12 and 13. The working chamber 37 is sealed by the surface 14 of the rotor 2 along the surface 7 of the housing 1, the surface (recess) of the housing 10 along the surface 12 of the rotor 2, surface 13 rotor 2 along surface 8 of housing 1, surface 20 of piston 4 along surface of groove 16 of rotor 2, surface 19 of piston 4 along surface 7 of housing 1, surface 24 of SSE 5 along surface 8 of housing 1 and, between parts of the piston, surfaces of connectors 21 and 27.

In this ORM (Fig. 1), the pistons 4 create a pressure drop only passing through the working section 38 located between the inlet window 33 and the exit window 34 at a place where the cross-sectional area (passing along axis 15 of rotor 2) of the working cavity is close to its maximum value. There they divide the working cavity 37 into suction chambers (during operation their volume increases) 39 and discharge chambers (during operation their volume decreases) 40. There are several advantages to this: maximum feed of ORM, minimal friction losses, because the speed of the piston 4 relative to the rotor 2 is close to zero, the maximum seal between the piston 4, SSE 5 and the housing 1 due to inertia. On the working section 38, the left part, where the working chamber 37 begins to narrow, is more preferable for working from the point of view of compaction the piston 4 is additionally pressed against the surface 8 due to friction in the groove 16 of the rotor 2.

The supply of such ORM is all the more constant, the shorter the working section 38, i.e. the angular dimensions of the windows 33 and 34 are larger. If the working section 38 has a large angular extent (smaller windows 33 and 34), then the feed of the ORM becomes less uniform.

To increase the pressure and uniformity of the supply of ORM in it, you can install several pistons 4, for example two (figure 5). To do this, in the rotor 2 made two through grooves 16.

When reducing the angular (around the axis of rotation of the rotor 15) size of the exit window 34 (Fig.6) between two pistons 4 on the working section 38 of the working chamber 37, a pre-compression chamber 41 of the working fluid is formed. Only after reducing the volume of the chamber 41 to a predetermined number (by the position of the exit window 34) the pre-compression chamber 41 is connected to the exit window 34. That is, OPM can be used as a compressor having a pre-compression chamber. Figure 6 shows the overlap of the pistons 4 inside the rotor 2, in which they can perform rotational vibrations at a fairly large angle. To do this, in the middle of one of the pistons 4, a cutout 42 is made in the form of a sector facing the spherical surface 19, and toward the center of the piston extends beyond the radius of the central sphere 12 of the rotor 2 and the spherical (cylindrical) cutout 43 in the center, so that two the halves of the piston 4 were joined by an arc 44. And in the middle of the other piston 4, the same cutout 42 is made in the form of a sector, which extends onto a spherical surface 19, which, with its lower part, extends into a wider angle cutout 45 in the form of a disk sector located along the radius of the disk n and the level of the arc 44 of the first piston 4.

A simpler but more robust design of the pistons 4, shown in Fig.7, allows them to swing at a smaller angle. On the first piston, a cutout 43 is made in the center, and on the second, a cutout in the form of sector 42. Moreover, they are easily inserted in turn into the through grooves 16 of the rotor 2 during assembly. A hole 46 can be made in the connector 21 for additional fixing of the SSE 5. The same hole (not shown) is also made on the SSE 5. Then the SSE 5 can additionally be mounted with the possibility of rotation by an axis (pin) (not shown) passed through the hole 46. If the hole is made through the entire piston, then two SSEs 5 may appear on a common physical axis. In one feed, you can use a larger number of pistons 4, choosing as an additional piston 4, the piston 4 with the arc 44 (Fig.6) and spacing the arcs 44 connecting the two halves of the pistons 4, along the radius. In this case, the cutouts 42 serve as a good relief of the piston 4, because the displacement of the mass of the piston 4 to the axis 23 reduces the inertial load of the piston during its oscillations (masses concentrated along axis 23 have the same period of natural vibrations in the field of centrifugal forces as the period of oscillation of the piston 4).

Pistons 4 can be used both with SSE 5 of various types and without SSE 5. Fig. 8 shows an example of SSE 5 swinging on an axis 47 protruding from a piston 4. Axis 47 can be part of a piston 4 (a stronger connection, but more difficult manufacturing), and can be inserted into the hole in the piston 4 either motionless or with the possibility of rotation. In each case, this is determined by materials, loads, required strength. SSE 5 is made in the form of a tube 48 with a flat plate. It has the same functional surfaces: the flat face of the SSE 24, the concave spherical face of the SSE 25, the convex spherical face of the SSE 26, as in the previous SSE 5. The tube 48 is put on axis 47 or stationary (then axis 47 rotates in piston 4), either rotatable. When the hole 49 is made in the center of the piston 4, it can be fixed in the rotor 2 by means of an axis (pin) 50, which can be pressed into the hole 49 or be able to rotate in it. In this case, a hole for the axis 50 is also made on the central sphere 12 of the rotor 2.

Figure 9 shows an example of SSE 5, made in the form of a roller 51, worn on an axis 47, protruding from the piston 4. As a roller 51, for example, carbide, plastic or rubber sleeve can be used. The roller 51 can be mounted on the axis 47 with the possibility of rotation or motionless.

Relief of the piston 4 can be performed in the form of a sample 52 of the material (Fig. 10) at its front end 20 in the direction of rotation of the rotor. The sample 52 is shifted to the right. The same sample 52 (it is not visible) was made on the face 20 facing us (in the figure on the left) symmetrically with respect to the axis of symmetry of the piston 4. The samples can be filled with lighter material. In this case, the samples 52 may be located on the rear (acting as a sliding bearing) end 20.

In some systems, the working fluid needs to be driven through a rotating shaft (for example, in cooling systems). Then it may be convenient to arrange one or both windows of the entrance 33 and the exit 34 of the working fluid on the rotor 2 (Fig.11). The rotor 2 of such a KORM is similar to the rotor 2 of Fig. 1, except that the diameter of the upper output shaft 3 is larger and in one of the recesses 17 under the SSE 5 an entry window 33 is made to the right of the through groove 16 and an exit window 34 to the left of the groove 16. Windows 33 and 34 are connected with the channels inside the rotor 2 running along its axis 15 on different sides of the groove 16 of the supply 53 and the outlet 54 of the working fluid, respectively. The body of such a feed is made of three parts. The two parts of the body are the same and represent a longitudinal half from the cylinder with a through cylindrical hole 9, coaxial to the side of the cylinder. A spherical cavity 6 is made inside the cylinder with a center on the axis of the hole 9. The third part of the body is a ball whose diameter is equal to the diameter of the spherical cavity 6 with a through cylindrical hole 11. The upper (slightly larger) part of the ball is cut off by a plane passing at an angle to the axis of the cylindrical hole 11. The slice forms a flat surface 8. In the center of the ball a spherical cavity 10 is made, the diameter of which is equal to the diameter of the central sphere 12 of the rotor 2. For attaching two identical halves of the body to each other and is mounted The third part of the casing is attached to them with fixing holes 55 for screws. The rotor is inserted into the third part of the housing due to the fact that the cylindrical hole 11 has a larger diameter than the diameter of the lower part of the output shaft 3. Tightness is ensured by the contact of the sphere 12 along the spherical cavity 10. The gap between the output shaft and the hole 11 is used to install a bearing (not shown) . On the surface 8, in the place of its contact with the conical surface 13 of the rotor 2, to increase the contact area there is a recess 18 corresponding to the surface 13. Immediately before (in the direction of rotation of the rotor 2) the recess 18 is made a groove 56, which serves to prevent overwriting (tightening) of solid particles of mechanical impurities in an acute angle between surfaces 8 and 13. A feature of this KORM variant is the presence of through holes 57 (Fig. 12) on one of the piston 4 parts protruding from the rotor 2. Only a KORM constant pressure differential is required one of the rotor 2 projecting portion of the piston 4. The second part of the piston 4 is used only to synchronize it with the surface 8 via SSE 5 or directly. In order not to connect the channels of supply 53 and removal 54 of the working fluid, at the time of passage of the SSE 5 through the contact area of the conical surface 13 of the rotor 2 with the surface 8 (recess 18), this SSE 5 should fit tightly into the recess 18, blocking the windows 33 and / or 34 at the time of passage. In the profile groove on the spherical surface 19 of the piston 4, a sealing element 58 is installed, which can be performed, for example, from rubber, plastic, hard alloy, depending on the working medium. Such an element 58 can improve the friction conditions and select gaps on several surfaces at once: piston 4 — surface 7 of housing 1, piston — SSE 5, SSE 5 — surface 8 of housing 1.

In connection with the design features (the inclination of the surface 8 to the axis of rotation 15 of the rotor 2), the use of a pair of KORM is very promising. Two feed, located on the same shaft, can form a series or parallel hydraulic connection. Such associations unload the common shaft from radial or axial hydraulic and dynamic loads, equalize the ORM supply, and allow a greater ratio of the ORM power to its size to be obtained. Given the prospect of using ORM as a multi-stage submersible high-pressure pump, it is logical to call this combination of two KORM as an ORM stage.

On Fig depicts the stage of ORM with a parallel connection of KORM, working in antiphase with each other. The top of the KORM 59 to create pressure uses the entire working section 38 of the working chamber 37, on which its cross-sectional area increases - the descending section 60 (named in the direction of the piston 4), and captures part of the working chamber 37 with a decreasing section - the beginning of the ascending section 61. And the lower KORM 62 for creating pressure uses a part of its working chamber 37 with a close to maximum, but still increasing cross-section (end of ascending section 61) and the entire section of the working chamber 37, on which its cross-sectional area I decreased (downward section 60). On the remaining sections of the chambers 37, the windows of the entrance 33 and exit 34 (bypass zone) are located or their dimensions are simply increased to reduce the tightness. The surface 8 of the housing of each KORM is parallel to each other, and the passage 63 for the working fluid from one KORM to another is made in the form of several small angular lengths of passages 64 located on the descending section 60. When the piston 4 passes the exit to the surface 8 of the housing 1 of the passage 64 the output is blocked by a piston 4 or SSE 5. The windows of the inlet 33 and the outlet 34 of the working fluid are located on the upstream part 46 of the KORM on the spherical surface 7 of housing 1. With a small distance between the surfaces 8 of the adjacent KORM (to reduce the length of the steps ) The central sphere 12 different FODDER can partially go into the next fed. So that this does not interfere with the movement of the SSE 5, on it, from the side facing the rotor 2 (instead of the concave spherical face 25), a narrowing 65 is made. The flow of this stage is constant, the pressure drop is provided throughout the cycle. If there is sufficient tightness of the stage (precise manufacturing or good sealing or a small pressure drop) in a multi-stage machine, the efficiency of the ORM stage can be increased and its wear reduced by eliminating part of the descending section 60, where the piston 4 relative to rotor 2 is at its maximum speed. This can be done, for example, by increasing the angular dimensions of the aisles 64 or by combining them into one large aisle 63. The third part of the body, containing the surfaces 8 of both KORM 59 and 62, can be called a separator 66. For its fixation in the longitudinal cylindrical halves of the body 1, there is an inclined groove 67. It is sometimes convenient to divide the cylindrical part of the housing into halves by a plane along its axis perpendicular to the division shown. With a separate rotor of each stage, it is more convenient to divide by a transverse plane. If the SSE 5 is made narrowing 65 or the piston 4 is used without the SSE 5, then to strengthen the rotor 2, the two central spheres 12 can be joined by a cylindrical section (not shown) or, in general, instead of two spheres 12, make one cylinder. True, this will slightly increase internal overflows.

To increase the feed rate of the stage, KORM are connected in parallel, using only working sections 38 to create a differential pressure, where the cross section of the working chambers 37 is close to its maximum value (Fig. 15). Moreover, to create a smooth low-pressure passage 68 from the rarefaction chamber 39 of the lower KORM 62 to the rarefaction chamber 39 of the upper KORM 59 and the high-pressure passage 69 from the compression chamber 40 of the lower KORM 62 to the compression chamber 40 of the upper KORM 59 through the separator 66 of the surface 8 of different KORM 59 and 62 due to their rotation relative to the axis 15 are located at an angle to each other. The passages 68 and 69 are similar in shape (one of them is clearly visible in FIG. 15) and are separated from each other by an inclined rib. In the passage 68, the working fluid enters the rarefaction chamber 39 of the upper KORM 59, first passing through the rarefaction chamber 39 of the lower KORM 62. And in the passage 69, the working fluid leaves the compression chamber 40 of the lower KORM 62, first passing through the compression chamber 40 of the upper KORM 59. using several pistons 4 in each KORM 59 and 62, sections of the common rotor 2 in different KORM 59 and 62 can be deployed relative to the axis 15 for phase separation (Fig. 15). For example, when the piston 4 passes the upper KORM 59 of the maximum cross section at its working section 38, the piston 4 of the lower KORM 62 passes a smaller cross section of the working chamber 37 at the working section 38. This smooths the feed of the stage. To increase the support area of the SSE 5 and for more uniform wear, the output of the passages 68 and 69 between the KORM 59 and 62 on the surface 8 can be made in the form of a set of holes, as in Fig. 12. At high feeds, to increase the passages 68 and 69, they can go to the surface of the housing 1 (Fig. 15) (in multi-stage submersible pumps, the housing is usually located in the pipe).

The passages 68 and 69 of the working fluid from the lower KORM 62 to the upper KORM 59 through the separator 66 are needed so as not to occupy a place along the diameter of the step, i.e. if the task is to pump the maximum amount of fluid through an opening (well) of a certain diameter, or, conversely, to drill a minimum diameter well for a specific fluid supply. If there is no such or similar task, then the passages 68 and 69 can be bypassed the separator 66, through the windows of the entrance 33 and exit 34 located on the spherical surface 7 of the housing 1, and choose the KORM 62 and 59 turn, such as in Fig. 12, for maximum unloading of the rotor 2 and reducing the length of the stage. The feed of the step of FIG. 15 is close to constant. Placed in a pipe with an internal diameter of 90 mm (5A overall), this stage, working at 3000 rpm, can produce up to 1500 m ³ / day.

Another way to increase the supply of a multi-stage submersible pump is to allocate a place along the diameter of the pipe 70, which includes the steps, under the passages 68 and 69 of the working fluid, bypassing the spherical cavities 6 (Fig. 16). In this case, between the pipe 70 and the passages 68 and 69 there may still be a wall of the housing, or you can, to save space, use the pipe 70 as one of the walls of the passage 68, 69. If the passages 68 and 69 are separated in the pipe only by ribs 71, then the steps can be inserted into the pipe with a slight interference created by the deformation of the pipe 70. The interference will increase even more when the ORM is operating, as internal pressure tends to make pipe 70 round. This solves the problem of leakages between passages 68 and 69. When allocating space for passages 68 and 69, the diameter of the working chamber 37 is smaller. But it is possible to connect in parallel (or sequentially) several KORM (for example, similar KORM in Fig. 5, but with windows on the surface 7) from several stages, receiving in each stage complete unloading of the rotor by connecting two KORM with parallel surfaces 8, at least least of radial force. The supply of such ORM should be determined only by how much space we allocated in the pipe 70 for passages 68 and 69. And the fee for this is to reduce the supply of each individual feed and, as a result, increase the required number of steps and increase the share of internal overflows in the supply of ORM (decrease volumetric efficiency at the same pressure per stage). Such parallel sets of steps can then be connected in series with each other to increase pressure, blocking, for example, passage 68 and connecting passage 69 to passage 68 of the next set. The same approach of parallel and serial connection of KORM is suitable for KORM with the supply of the working fluid along the shaft (11).

When using KORM separately (Fig. 5), more complex SSE 5 with additional axes 72 and 73 (Fig. 17) can increase its efficiency and resource. The axis 72 is attached perpendicular to the middle of the common axis 74 of the two SSEs 5. The common axis 75 of the other two SSEs 5 has a middle in the form of an arc 76 to bypass the axis 74. The axis 73, made in the form of a tube, is attached to the arc 76. In the piston, in the hole 46, SSE 5 on the axes are inserted through the grooves 77 and fixed by inserts 78. The axes 72 and 73 exit the rotor 2 through the hole in place of one (lower) of the output shafts, perpendicular to surface 8, into the hole in the housing, which they have the ability to rotate around their geometric axis. The axes 72 and 73 hold the faces 24 of the SSE 5 parallel to the surface 8, and if they are fixed in the housing from axial movement, they can provide a small guaranteed clearance between the faces 24 and the surface 8 - between the parts with maximum relative speeds. This can be important, for example, when using FOOD as a dry compressor.

In a two-stage system supplying the working fluid along the shaft along its axis, four KORMs work in parallel. The FEED of each step is in one phase, and both the FEED of the other step are in the opposite phase. This makes it possible to unload the rotor sections of each stage from radial and axial loads.

If the distance between the centers of the spherical surfaces 7, 12, 14 of the two KORM along the axis 15 of the rotor 2 is chosen equal to zero, then the pistons 4 of different KORM can be combined into one piston 4 (Fig.15). This reduces the load on the common piston 4, but due to the fact that the axes 32 of the SSE 5 of both KORM cannot simultaneously pass through the center of the piston 4, being parallel to the surface 8, measures must be taken to maintain the contact seal of the piston 4 (SSE 5) - surface 8. I will give some of them. Passing through the center of the piston 4 axles 32 of only one of the two KORM (asymmetric piston 4) and placing the main load on them to synchronize the piston 4. Design SSE 5, in which SSE 5 selects the gap between the piston 4 and surface 8 (Fig. 16). The introduction of a small deviation from the flatness of the surface 8 on one of the surfaces 8 (reduces manufacturability, the resource of the friction pair). Pressing (for example, a pressure drop) to the surface 8 of only the side of the piston 4, which creates a pressure drop (a backlash appears in the system). The combination on the common axis 32, passing through the center of the piston 4 SSE 5, different KORM (increases the thickness of the piston, complicates the design).

The ORM stage (Figs. 18-20) consists of two KORM 59 and 62 with a common rotor 2. The housing of the 1 stage is made in the form of a cylinder consisting of two longitudinal (plane of the connector along the axis 15) halves. Inside the housing there is one spherical cavity in which, under the flange to the axis 15, a groove 67 is made for installing a separator 66, which divides this spherical cavity into two cavities 6. The upper cavity 6 contains the center of the spherical cavity. The spacer is like a flat washer. Its upper surface is the surface 8 of the upper KORM 59, and the lower surface is the surface 8 of the lower KORM 62. The inner hole of the separator 66 is spherical and is a recess 10 of both KORM 59 and 62 at the same time. The lower side of the separator 66 is also flat in this design and is the surface 8 lower FOOD 62. The separator 66 is made up of two "c" -shaped parts. The connector between them is needed only so that the separator is put on the rotor, and can pass anywhere, for example, perpendicular to the connector of the housing 1. Two cylindrical openings 9 for the output shaft 3 extend from the cavities 6 coaxially to the axis 15. Rotor 2 is made in the form of a set of coaxial elements (Fig. 20): a central sphere 12 resting on it with a smaller base of two truncated cones 13, each of which is limited by its segment of the sphere 14, concentric to the central sphere 12 and having a larger radius approximately equal to the radius of the sph through the diameter of the rotor 2 and the geometric axis 15 of rotation of the rotor 2, through the surface of the central sphere 12, cones 13 and segments of the sphere 14, a through groove 16 is made for placing the piston 4. At the junction of the through groove 16 and the upper cone 13 there is a recess 17 under the SSE 5, made in the form of a chamfer. The rotor 2 is installed in the housing 1 with the possibility of rotation around its geometric axis 15. In this case, the centers of the spherical surfaces 7, 12 and 14 approximately (accurate to play, tolerances, wear) coincide. In this embodiment, the conical surfaces 13 of the rotor 2 interact with the flat surfaces 8 of the housing 1. At the point of contact, it is allowed (more often useful) to have a small recess 18 (not shown). Before the point of contact, for the removal of the abrasive, it is desirable to have a groove (not shown). The piston 4 (Fig.19, 20) is made in the form of a disk with a spherical side surface 19. The radius of the surface 19 is approximately equal to the radius of the surface 7 for the possibility of rotation of the piston in the housing when creating a seal between surfaces 7 and 19. The end surfaces 20 of the piston 4 in this design flat and parallel to each other. In the spherical lateral surface 19 symmetrical with respect to the plane of symmetry, perpendicular to the end surface 20, opposite parts of the piston 4, there are grooves 81 under the separator 66, in which there are elements interacting with the surface 8. In this design, in the upper KORM 59 is the axis surface and a cylindrical hole 83 into the piston 4. The bottom of the slot is made in the form of a spherical platform 22, concentric surface 19, for contact with the spherical recess 10 of the housing 1. In the lower chamber is a sealing element 79 installed in the groove 80 with the ability to extend from it and select the gap between the lower lateral side of the slot 81 of the piston 4 and the surface 8 of the lower feed. The piston 4 is installed in the through groove 16 of the rotor 2 with the possibility of performing rotational vibrations in the plane of the groove 16 relative to the geometric axis 23, passing approximately (with accuracy to the backlash, tolerances, wear) through the center of the central sphere 12 of the rotor 2 (relative to the center of the surface 19). The thickness of the piston 4 is approximately equal to the width of the groove 16 for sealing by the piston 4 of the groove 16. The SSE 5 (Fig. 19, 20) has its own axis 82, which enters the hole 83 in the piston 4, one flat face 24 for contact with the flat surface 8 of the housing 1, one concave spherical face 25 for contact with the Central sphere 12 of the rotor 2, one convex spherical face 26 for contact with the spherical surface 7 of the housing 1, and on another face there is a sector of a cylindrical surface, coaxial to the axis 82. The axis 82 enters the piston bore 4 and keeps SSE 5 from skew, leaving increasing rotational degree of freedom. For this version, a rather important feature is that both axes 82 of the SSE of the upper KORM 59 are located on the same axis 32 and the axis 32 intersects (up to backlash, tolerances, wear) the axis 23 of the rotational vibrations of the piston 4. It is thanks to this fact that face 24 of the SSE 5 can be in constant contact with the flat surface 8 of the upper KORM 59, taking on the load to synchronize the oscillations of the piston 4. The axis 32 is in the inner cavity 6 above the flat surface 8 and approximately parallel to it. The windows of the inlet 33 and the outlet 34 of the working fluid (Fig. 18) are located on both halves of the housing 1 on the surfaces 7 and are adjacent on different sides to the contact points of these surfaces with the cones 13 of the rotor 2. The windows of the inlet 33 and the outlet 34 lead to the channels 53 and 54 respectively, as with the step of FIG. 16. The lower surface of the separator can be made curved, tracking the lower side of the slot 81. Then you can do without a sealing element 79. In another embodiment, in the lower chamber, any of the previously described SSE types 5 can be used. But its face 24 is better to make slightly curved, with convex sections. The combination of the pistons of the two KORM described here can be used in all the types of connection of the two KORM described above, except, perhaps, for the stage in Fig. 15 (the separator is too thin to allow flows through it).

Feed Work

FOOD in figure 1 works as follows. In figure 1, the piston 4 is located on the working section 38 in the state of its maximum deviation (at the extreme swing point) in the region of the maximum cross section of the working chamber 37, blocking its passage. The camera 37 is not closed in the ring, because behind the rotor 2 it is blocked by the contact point of the conical surface 13 of the rotor 2 with the flat surface 8 of the housing 1 — the recess 17. As a result, the piston 4 divides the chamber 37 into two cavities — the rarefaction chamber 39 (to the right of the piston 4) and the compression chamber 40 (to the left of the piston four). SSE 5 improves the contact of the piston 4 with the flat surface 8. When the rotor 2 is rotated clockwise when viewed from above, the size of the rarefaction chamber 39 increases and the working fluid enters through the inlet window 33. The size of the compression chamber 40 decreases, and the working the body leaves it through the exit window 34. Further, due to the inclination of the flat surface 8, the cross section of the working chamber 37, when moving the part of the piston 4 closest to us, begins to decrease. In this case, the piston 4 is forced to begin to turn so that the proximal part of the piston 4 is shifted upwards and away from us. When the back of the SSE 5 runs into the exit window 34, the overlapping of the working cavity 37 by the piston 4 is stopped. Temporarily the KORM does not create a pressure drop (in fact, a small drop remains, as with fan-type machines). The movement of the working fluid in the highway at this time should be supported either by the inertia of its movement, or by other sequentially established KORM. By reducing the size of the windows 33 and / or 34 or increasing the size of the SSE 5, this section of the cycle can be eliminated, but then the feed will become forcibly pulsating and the feed will be lost, the efficiency will decrease due to the load on the piston 4 when it moves relative to the rotor 2. After some time, the leading edge SSE 5 of the second end of the piston 4 slides off the inlet window 33 and bumps into the working platform 38. Now this end of the piston 4 overlaps the cross section of the working chamber 37, pushing the working medium through it from the inlet window 33 to the exit window 34.

KORM according to figure 5 works similarly to KORM according to figure 1. The difference is that it has more 4 (two) pistons and the pressure drop is maintained throughout the cycle. At site 38, the pistons are constantly replacing each other. Another difference is that the cutouts 42 and 45 on the pistons 4 shift the center of mass of each piston 4 to its axis 32, thereby significantly reducing the piston's pressing against the surfaces of the housing 7 and 8 by inertia.

KORM according to Fig.6 works similarly to KORM according to Fig.5. The difference is that it has a smaller exit window and for some time two pistons 4 are located on the working platform 38. The volume of the working fluid (gas or gas-liquid mixture) is cut off between them, i.e. a pre-compression chamber 41 is formed, which begins to compress as the pistons 4 move to the left. When the rear limit of the SSE 5 of the front piston 4 of the exit window 34 reaches, the cut-off volume (chamber 41) is connected to the compression chamber 40. It is desirable that at this moment the pressure of the working fluid in chamber 41 is approximately equal to the pressure in chamber 40. And so, to the suction chamber all the time the working fluid continuously enters from the inlet window 33. The working fluid exits continuously from the displacement chamber through the exit window 34. Pre-compression chambers periodically appear and disappear between them. The gap (volume) between the recess 17 of the rotor 2 and the SSE 5 depends on whether a part of the compressed working fluid will be lost when the SSE 5 leaves the compression chamber 40. It is better to minimize the gap for the compressor. Consumption and supply of FOOD by the compressor of the working fluid is almost constant and continuous.

FOOD in Fig.11 works as follows. One end of the piston 4, all the while in the working chamber 37, divides it into two parts - the rarefaction chamber 39 (behind, in the direction of rotation of the rotor, behind this end of the piston 4) and the compression chamber 40 (before this end of the piston). Since the input window 33 of the working fluid is immediately behind the end of the piston 4, and the output window 34 is immediately before this end of the piston 4, they are almost always connected with the chambers of rarefaction 39 and pressure 40, respectively. The exception is the moment of passage through the entrance window 33 or exit window 34 of the platform 17. At this point, the feed is minimal, and the input and output windows 33 and / or exit 34 overlap SSE 5, eliminating the possibility of overflow of the working fluid between them. The other end of the piston 4 does not overlap the working chamber 37, because at least one through passage 57 is made on it. This end of the piston 4 is used only for centering the piston on the surface 19, to provide oscillations due to the SSE 5 of this end of the piston 4 and as a counterweight to the working end of the piston 4. Supply of one such feed pulsating from zero to maximum. When using a stage of two such KORM installed on the same shaft for operation in antiphase, hydraulically connected in parallel by common channels 53 and 54, the feed becomes almost constant. When using two stages, each of which consists of two such KORM installed on the same shaft for operation in one phase, and the stages are in antiphase and connected hydraulically in parallel with common channels 53 and 54, the feed becomes practically constant and the rotors of each stage are unloaded from radial and axial loads.

Work steps

The step of FIG. 13 works as follows. When the parts of the pistons 4 of both KORM 59 and 62 protruding into the working chamber 37 go along the descending section 60 of the separator 66 or further along the section of the chamber 37 adjacent to its maximum section (i.e., along the pressure section), they break the chamber 37 into the suction chamber 39 and a compression chamber 40. If two pairs of pistons are located in these areas, another chamber of constant volume is formed between them. When the pistons move, the working fluid enters the suction chamber 39 through the window 33 from the supply channel of the working fluid 53 and leaves the compression chamber 40 through the window 34 into the channel of the withdrawal of the working fluid 54. On the pressure section there are 2-3 pairs of pistons 4, so the creation process the pressure step is continuous. The supply of such a stage is almost constant. When the pistons pass the bypass section - the ascending section 61 without its very beginning, they create a small pressure drop, working only as fan blades.

The operation of the stage of FIG. 15 can be considered as the operation of two parallel SORMs of FIG. 5. The difference is only in the mixed arrangement of windows - on surfaces 7 and 8 and the passage of the working fluid through the passages 68 and 69 of the separator 66. When the piston 4 moves along the working section 38 of the lower KORM 62 they break its working cavity 37 into two parts - an increasing rarefaction chamber 39, where from the supply channel 53 of the working fluid through the inlet window 33 the working fluid enters, and a decreasing compression chamber 40, from where the working fluid exits first into the high-pressure passage 69, and then out of it through the compression chamber 40 of the upper KORM 59 to its exit window 34 and further 54 working channels of the body. When the piston 4 moves along the working section 38 of the upper KORM 59, they break its working cavity 37 into two parts - an increasing rarefaction chamber 39, where first from the inlet channel 53 of the working fluid first through the inlet window 33 of the lower KORM 62, then through the channel of the high pressure passage 68 the working fluid, and a decreasing compression chamber 40, from where the working fluid enters the exit window 34 and further into the channel 54 of the working fluid. The phases of the feed are divorced to compensate for the uneven supply of each of them. When the piston divides the working cavity 37 of one of the KORM 59/62 in the maximum section at its working section 38, the working cavity 37 of the other KORM 59/62 shares its piston 4 at the minimum section of its working section 38.

The operation of the stage in Fig.16 can be considered as the work of two parallel SORM in Fig.5. The difference is only in the location of the windows - on the surfaces 7. When the piston 4 moves along the working section 38 of the lower KORM 62 they break its working cavity 37 into two parts - an expanding rarefaction chamber 39, where the working fluid enters from the supply channel 53 of the working fluid through the input window 33 , and a decreasing compression chamber 40, from where the working fluid exits to the exit window 34 and further to the exhaust channel 54 of the working fluid. When the piston 4 moves along the working section 38 of the upper KORM 59, they break its working cavity 37 into two parts — an increasing rarefaction chamber 39, where a working fluid enters from the supply channel 53 of the working fluid through the inlet window 33, and a decreasing compression chamber 40, from where the working fluid leaves the exit window 34 and then into the channel 54 of the working fluid. KORM phases 59 and 62 coincide to balance the common rotor 2.

The operation of the stage of FIG. 18 is similar to the operation of the stage of FIG. 16

Claims (13)

1. The chamber of a volumetric rotary machine, comprising a housing, a rotor with an output shaft mounted rotatably in the housing, having a working surface concentric with its axis of rotation, at least one piston, the working surface of the housing being a surface and a segment inclined to the axis of rotation of the rotor spheres bounded by an inclined surface, the working surfaces of the housing and the rotor form a working cavity, at least one groove is made on the working surface of the rotor along its axis of rotation, in each groove of the rotor is installed a piston with the possibility of overlapping and sealing the working cavity and performing rotational vibrations in the plane of the groove, the piston is made in the form of at least part of the disk with at least one sealing synchronizing element for interacting with an inclined surface of the housing associated with the piston hinge consisting of a hinge connector on a sealing synchronizing element in the form of two coaxial cylindrical recesses between which a cylindrical protrusion is coaxially located, and a reciprocal hinge connector on the piston mounted with the possibility of performing rotational vibrations relative to the piston. 2. The camera according to claim 1, in which the inclined surface of the housing is made flat. 3. The chamber according to claim 1, in which the working surface of the rotor is made in the form of two coaxial surfaces of a truncated cone, resting the truncated part on a sphere. 4. The chamber according to claim 3, in which the surface of the truncated cone of the rotor interacts with the inclined surface of the housing along its generatrix. 5. The chamber according to claim 1, in which at one end of the piston is made at least one through passage on the opposite side of the piston. 6. The chamber of a volumetric rotary machine, comprising a housing, a rotor with an output shaft mounted rotatably in the housing, having a working surface concentric with its axis of rotation, at least one piston, the working surface of the housing being a surface and a segment inclined to the axis of rotation of the rotor spheres bounded by an inclined surface, the working surfaces of the housing and the rotor form a working cavity, at least one groove is made on the working surface of the rotor along its axis of rotation, in each groove of the rotor is installed a piston with the possibility of overlapping (sealing) the working cavity and performing rotational vibrations in the plane of the groove, the piston is made in the form of at least a portion of the disk with at least one sealing synchronizing element for interaction with the inclined surface of the housing associated with the piston a hinge consisting of a hinge connector on the sealing synchronizing element in the form of a tube, and a reciprocal hinge connector on the piston mounted with the possibility of performing rotational vibrations relative to piston. 7. The camera according to claim 6, characterized in that the sealing synchronizing element is made in the form of a tube with a plate. 8. The step of a volumetric rotary machine, consisting of two chambers, each of which contains a rotor with an output shaft, mounted in the housing rotatably, having a working surface concentric with its axis of rotation, at least one piston, the working surface of the housing being inclined to the axis of rotation of the rotor, the surface and the segment of the sphere bounded by an inclined surface, the working surfaces of the housing and the rotor form a working cavity, at least one groove is made on the working surface of the rotor along its axis of rotation In each rotor groove, a piston is installed with the possibility of overlapping and sealing the working cavity and performing rotational vibrations in the groove plane, the piston being made in the form of at least a part of the disk, the chambers having a common geometric axis of rotation of the rotors and tilting towards each other the surfaces of the housings, while between the chambers there is a passage 63 for the working fluid from one chamber to another in the form of several passages 64 with the possibility of blocking the passage 64 with a piston or a sealing synchronizing element, what stage has the entrance and exit windows of the working fluid. 9. The stage of claim 8, in which at least two chambers are deployed relative to the axis of rotation of the rotors at such an angle at which they work in antiphase. 10. The stage of claim 8, in which at least two chambers of the inclined surfaces of the housings are parallel. 11. The stage of claim 8, in which the centers of the segments of the sphere of at least two cameras coincide. 12. The stage of claim 8, in which at least one piston from two different chambers is made stationary relative to each other. 13. The stage of claim 8, in which at least one sealing synchronizing element of two different chambers are installed on one common axis.

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