WO2013073982A1 - Diametric positive-displacement machine (variants) - Google Patents

Abstract

The invention relates to mechanical engineering and can be used in hydraulic machines, pumps, compressors and internal combustion engines. The technical problem of the invention consists in providing a novel design for a diametric positive-displacement machine having a high degree of efficiency of the delivery of working medium at high pressures and a wide field of use.

Description

 DIAMETER VOLUME MACHINE (OPTIONS)

The invention relates to mechanical engineering and can be used in hydraulic machines, pumps and compressors.

 5 A well-known vane pump containing a housing, inside of which a sleeve with suction and discharge windows is rigidly fixed, and in the inner cavity of the sleeve there is a rotor with radial grooves and plates placed in them, interacting with contactors (RF patent 1M? 40406 for utility model, class F04C2 / 344, publ. 09/10/2004).

 The disadvantages of the known vane pump are the design complexity, low reliability due to the large number of friction pairs, as well as low efficiency of pumping the working medium.

 15 A plate machine is known containing a rotor eccentrically mounted in the stator cavity, in the radial grooves of which are movable plates resting on a cylindrical guide element eccentrically placed in the rotor bore (RF patent N? 2011013

20 invention, cl. F04C2 / 344, publ. 04/15/1994).

 The disadvantages of the known plate machine are the complexity of the design, the rapid wear of the movable plates and the low efficiency of pumping the working medium.

 Known pump, consisting of a housing in which there is

25 cavity with inlet and outlet openings, a rotor that is eccentrically mounted in the cavity, blades diametrically passing through the rotor and having a working fit relative to the walls of the cavity, dividing it into many working chambers, the cross section of the cavity is a combination of two circular arcs of different radii, each of them being smaller half a circle, and two adjacent curved sections, which are complementary sections of the Archimedean spiral with common foci; the ends of such curved sections are directed tangentially to the aforementioned

5 circular arcs at the points of intersection with them, each of the blades moving along a non-circular portion of the cavity, passing through the rotor, moves at a constant speed while the rotor rotates at a constant angular velocity, and the rotor corresponds to a circular arc of a smaller radius (US patent 2260888 A, 10.28.1941, F04C2 / 344). Each pump blade is installed in the rotor with the possibility of its free longitudinal movement relative to the axis of the rotor, and the value of its longitudinal movement is limited by three parameters: the size of the groove on the surface of the blade, the eccentricity of the axis

15 of the rotor relative to the axis of the internal cavity of the housing and the shape of the cross section of the cavity of the housing. In the known pump, the trajectory of the ends of the blades sets the cross-sectional shape of the cavity of the housing.

 The disadvantages of the known pump are complexity

20 designs, fast wear of moving blades and low efficiency of pumping the working medium.

 Known rotary machine, consisting of a stator and a rotor, and the stator is a cylindrical body, the inner surface of which is formed in such a way that

25 has a cross-sectional shape of a cardioid, with the exception of a wall portion having a longitudinal arc recess; the rotor contains a cylindrical connecting rod and a blade, while the connecting rod is mounted to rotate in the housing so that part of it enters the recess; the connecting rod has a longitudinal diametrical slot, in which a blade is installed, moving in it in transverse direction and having such a length that its edge during rotation is in contact with the inner surface of the housing; the housing has openings for fluid inlet and outlet, the width of each of which is equal to the thickness of the blade and which are located 5 on both sides of the recess, while there are devices for controlling the movement of the blade, independent of the connecting rod and allowing the edge of the blade to pass along the inner surface of the housing (patent US 2373656 And on the invention, 04.17.1945, F04C2 / 344).

The disadvantages of the known rotary machines are:

 - low efficiency of pumping the working environment;

 - narrow scope due to the cardioid shape of the cross section of the inner surface of the housing and the width of the inlet and outlet openings limited by the thickness of the working blade.

 15 The closest to the invention in terms of technical nature and the task is a plate machine containing a body with inlet and outlet channels, in the cylindrical cavity of which an eccentric rotor is installed, made in the form of an end face plate, on the opposite face face plate

20 of the housing is mounted rotatably a guide cylinder with end diametric channels made open from the side of the faceplate, working elements mounted on the faceplate with the ability to move in the channels of the guide cylinder during its rotation (RF patent

25 N ° 2317417 on the invention, cl. F01C1 / 344, F04C2 / 344, publ.

 02/20/2008 - prototype).

 The disadvantages of the known plate machine are:

 - low efficiency of pumping the working medium at high pressures;

- narrow scope due to the impossibility of pumping from the working medium at high pressures. An object of the invention is the creation of a new design of a diametrical volumetric machine with a high efficiency of pumping a working medium at high pressures and a wide scope.

 5 The technical task posed is solved in the first embodiment of a diametrical volumetric machine, comprising a housing with inlet and outlet channels, a rotor arranged inside the cylindrical cavity of the housing, made in the form of an end cylindrical face plate, a guide cylinder installed rotatably and with eccentricity relative to the face of the face plate and having on the end surface from the face of the faceplate open diametrical channels, and working elements mounted on the faceplate with the ability to move in the channels on ravlyaetsya cylinder at its

15, according to the invention, in the housing cavity in the area of the inlet and outlet channels, the inlet and outlet cavities are not connected to each other, the guide cylinder is made with an outer diameter equal to the diameter of the body cavity and has end walls in each diametrical channel or

20 end walls with holes, while the end surfaces of the body cavity, the faceplate and the guide cylinder are in contact and form working chambers in the channels of the guide cylinder, which are alternately connected to the inlet or outlet cavities, directly or through an opening in the end

25 walls of the diametric channels, when the guide cylinders are rotated, while the working elements are fixed on the faceplate and made in the form of a finger, or a sleeve mounted on the finger with rotation, or a plunger mounted on the finger with the possibility of rotation around the center of its longitudinal axis, at this work item has a sliding fit in the channel the guide cylinder, and the stroke length of the working element is limited by the length of the corresponding channel of the guide cylinder, and the radius of the position of the finger on the faceplate is in the ratio L = 4R at a ratio of speeds

5 rotation of the faceplate and the guide cylinder Vnui = 2Vpi4, where L is the stroke length of the working element in the guide cylinder, R is the radius of the finger on the faceplate equal to the eccentricity of the axis of rotation of the guide cylinder relative to the axis of rotation of the faceplate, Vniu is the speed of rotation of the faceplate, and Vpu is the speed rotation of the guide cylinder.

 In such a diametrical volumetric machine according to the first embodiment, it is preferable:

 - the fingers of the working elements are rigidly fixed to the faceplate;

 - the fingers of the working elements are fixed on the faceplate with 15 rotational possibilities;

 - working elements and channels of the guide cylinder have a conjugate shape in cross section;

 the working element has a round, or square, or triangular shape in cross section.

 20 Since in the inventive diametrical volumetric machine according to the first embodiment, an alternative embodiment of its individual parts takes place, in particular, the guide cylinder has end walls or end walls with holes in each diametrical channel, and also the working elements are fixed on

25 faceplate and made in the form of a finger, or a sleeve mounted on the finger with the possibility of rotation, or a plunger mounted on the finger with the possibility of rotation around the center of its longitudinal axis, it should be noted that any combination of alternative elements of the machine ensures achievement of the claimed technical result. The implementation of the guide cylinder with the presence in each diametrical channel of the end walls with holes, and the execution of the working elements mounted on the faceplate in the form of a finger provides the application of the claimed invention in

5 hydraulic machines and pumps for pumping viscous fluids without mechanical impurities, such as oils, fuel oils.

 The implementation of the guide cylinder with the presence in each diametrical channel of the end walls with holes, and the execution of the working elements mounted on the faceplate in the form of a sleeve mounted on a finger with the possibility of rotation, ensures the application of the claimed invention in hydraulic machines and pumps when pumping viscous working media with mechanical inclusions, for example pastes, gels.

 The implementation of the guide cylinder with the presence in each is a diametrical channel of the end walls with holes, and the implementation of the working elements mounted on the faceplate, in the form of a plunger mounted on a finger with the possibility of rotation around the center of its longitudinal axis, provides the application of the invention in hydraulic machines and pumps

20 when pumping high-pressure viscous fluids without mechanical impurities, such as oil.

 The implementation of the guide cylinder with the presence in each diametrical channel of the end walls, and the implementation of the working elements mounted on the faceplate, in the form of a finger

25 provides the application of the claimed invention in compressors, hydraulic machines and pumps when pumping inviscid working fluids without mechanical impurities, such as gases, water.

The implementation of the guide cylinder with the presence in each diametrical channel of the end walls with holes, and for the execution of working elements mounted on the faceplate, the form of a sleeve mounted on a finger with the possibility of rotation, provides the application of the claimed invention in compressors, hydraulic machines and pumps when pumping inviscid working fluids with mechanical impurities, such as smoke,

5 water mixtures.

 The implementation of the guide cylinder with the presence in each diametrical channel of the end walls, and the execution of the working elements mounted on the faceplate, in the form of a plunger mounted on a finger with the possibility of rotation around the center of its longitudinal axis, provides the application of the invention in compressors, hydraulic machines and pumps during pumping under high pressure of inviscid fluids without mechanical impurities, such as gases, water.

 The technical task is solved in the second

15 embodiment of a diametrical volumetric machine comprising a housing with inlet and outlet channels, a rotor arranged in the form of a leading end cylindrical face plate, a guide cylinder mounted for rotation and with

20 with an eccentricity with respect to the axis of the driving faceplate and having diametral channels on the side of the leading faceplate and working elements mounted on the leading faceplate with the possibility of movement in the channels of the guide cylinder during its rotation, according to the invention, in the housing cavity in the zone

25 of the inlet and outlet channels, the inlet and outlet cavities are not connected to each other, the guide cylinder is made with an outer diameter equal to the diameter of the body cavity, and the diametrical channels of the guide cylinder are made through with respect to the axis of rotation of the guide zo cylinder and have end walls or end walls with holes, while on the other opposite leading faceplate, the sides of the guide cylinder with equal eccentricity are mounted in the housing with the possibility of rotation of the support faceplate, on the end surface of which are fixed

5 the ends of the fingers of the working elements, while the end surfaces of the body cavity and the end surfaces of the driving and supporting faceplates are in contact with the corresponding end surfaces of the guide cylinder, forming working chambers in the channels of the guide cylinder, which are alternately connected to the inlet or outlet cavities, directly or via holes in the end walls of the diametric channels during rotation of the guide cylinder, while the working elements mounted on the leading and supporting faceplates, filled in the form of a finger, or sleeve mounted on a finger with

15 the possibility of rotation, or a plunger mounted on the finger with the possibility of rotation around the center of its longitudinal axis, while the working element has a sliding fit in the channel of the guide cylinder, and the stroke length of the working element is limited by the length of the corresponding channel of the guide

20 of the cylinder, and the radius of the finger position on the leading and supporting plates is in the ratio L = 4R with the ratio of the rotational speeds of the leading and supporting plates and the guide cylinder Vnuu = 2Vpu, where L is the stroke length of the working element, R is the radius of the position of the finger on the leading and

25 supporting plates, equal to the eccentricity of the axis of rotation of the guide cylinder relative to the axis of rotation of the leading and supporting plates, Vnui is the speed of rotation of the leading and supporting plates, Vpi4 is the speed of rotation of the guide cylinder.

In such a diametrical volumetric machine according to the second embodiment, it is preferable: - the guide cylinder is installed in the housing on a sliding bearing;

 - the fingers of the working elements are rigidly fixed to the leading faceplate;

- the fingers of the working elements are mounted on the leading faceplate with the possibility of rotation;

 - working elements and channels of the guide cylinder have a conjugate shape in cross section;

 the working element has a round, or square, or triangular shape in cross section;

 - the fingers of the working elements are rigidly fixed to the support plate;

 - the fingers of the working elements are mounted on the support plate with the possibility of rotation.

 Due to the fact that in the inventive diametrical volumetric machine according to the second embodiment, there is an alternative embodiment of its individual parts, in particular, the presence of end walls or end walls with holes in the diametrical channels, as well as working elements fixed to the leading and supporting plates, made in the form of a finger, or a sleeve mounted on the finger with the possibility of rotation, or a plunger mounted on the finger with the possibility of rotation around the center of its longitudinal axis, it should be noted that any alternative use nenie elements provides achievement of the claimed technical result.

The implementation of diametrical channels with end walls with holes, and the working elements mounted on the leading and supporting plates, in the form of a finger provides the application of the claimed invention in compressors, hydraulic machines and pumps when pumping high-pressure viscous fluids without mechanical impurities, such as oils, fuel oils.

 The implementation of diametrical channels with end walls with holes, and working elements mounted on the leading and

5 supporting plates, in the form of a sleeve mounted on a finger with the possibility of rotation, provides the application of the claimed invention in compressors, hydraulic machines and pumps when pumping under high pressure viscous or non-viscous working fluids with mechanical impurities, such as oils, fuel oils, water, air, gases .

 The implementation of diametric channels with end walls, and the working elements mounted on the leading and supporting faceplates, in the form of a plunger mounted on a finger with the possibility of rotation around the center of its longitudinal axis,

15 provides the use of the claimed invention in compressors, hydraulic machines and pumps when pumping under high pressure viscous working fluids without mechanical impurities, such as oils, fuel oils, water, air, gases.

 The listed alternative executions of individual

20 parts of the inventive diametrical volumetric machine according to both options ensure the achievement of a technical result in various units (compressors, pumps, hydraulic machines) when pumping various working media under different high pressures, including those with mechanical inclusions.

25 In the inventive diametric volumetric machine according to the first embodiment, the radius of the finger position on the faceplate is in the ratio L = 4R with the ratio of the rotational speeds of the faceplate and the guide cylinder Vnui = 2Vpt |, according to the second option, the radius of the position of the finger on the leading and supporting side plates is in the ratio L = 4R at the ratio rotational speeds of the leading and supporting faceplates and guide cylinder Vnm = 2

 The above ratios for both variants of the diametrical volumetric machine were obtained empirically in the 5th way in the manufacture of prototypes of machines and varying the sizes of these parts and their relative positions at different speeds of rotation.

 Variants of the claimed invention is illustrated by drawings: figure 1 shows a longitudinal section of a first embodiment of a diametrical volumetric machine with a working element in the form of a cylindrical plunger; figure 2 is a cross section of the first variant of the diametrical volumetric machine with a working element in the form of a cylindrical plunger; in FIG. 3 is a longitudinal section through a second embodiment of a diametrical volumetric machine with a working

15 element in the form of a sleeve; in FIG. 4 is a cross section of a second embodiment of a diametrical volumetric machine with a working element in the form of a sleeve; in FIG. 5 is a schematic illustration of the interaction of moving elements of a diametrical volumetric machine.

 20 The diametrical volumetric machine according to the first embodiment comprises a housing 1 with an inlet 2 and an outlet 3 channels, located inside the cylindrical cavity 4 of the housing 1, a rotor made in the form of an end cylindrical faceplate 5, a guide cylinder 6, mounted with the possibility

25 rotation and with an eccentricity relative to the axis of the faceplate 5 and having open diametrical channels 7 on the end face from the face of faceplate 5 and working elements 9 mounted on the faceplate 5 with the possibility of movement in the channels 7 of the guide cylinder 6 during its rotation, while in the cavity 4 housing 1 in the area of inlet 2 and outlet 3 channels the inlet 10 and the outlet 11 of the cavity are not connected to each other, the guide cylinder 6 is made with an outer diameter equal to the diameter of the cavity 4 of the housing 1 and has end walls 12 or end walls in each diametrical channel 7

5 12 with holes 8, while the end surfaces of the cavity 4 of the housing 1, the faceplate 5 and the guide cylinder 6 are in contact and form working chambers in the channels 7 of the guide cylinder 6, which are alternately connected to the inlet 10 or outlet 11 cavities, directly or through the hole The 8th end walls of the 12 channels 7, when the guide cylinder 6 is rotated, while the working elements 9 are mounted on the faceplate 5 and are made in the form of a finger, or a sleeve mounted on the finger with the possibility of rotation, or a plunger mounted on the finger e rotatable around the center

15 of its longitudinal axis, while the working element 9 has a sliding fit in the channel 7 of the guide cylinder 6, and the stroke length of the working element 9 is limited by the length of the corresponding channel 7 of the guide cylinder b, and the radius of the position of the finger on the faceplate 5 is

20 to the ratio L = 4R with the ratio of the rotational speeds of the faceplate 5 and the guide cylinder 6 Vnui = 2 Urts, where L is the stroke length of the working element 9 in the guide cylinder 6, R is the radius of the finger position on the faceplate 5, equal to the eccentricity of the axis of rotation of the guide cylinder 6 relative to the axis

25 rotation of the faceplate 5, Vnuu - speed of rotation of the faceplate 5, Vpi4 - speed of rotation of the guide cylinder 6.

 In such a diametrical volumetric machine, it is preferable:

- the fingers of the working elements 9 are rigidly fixed to the faceplate 5;

- the fingers of the working elements 9 are mounted on the faceplate 5 with the possibility of rotation; - working elements 9 and channels 7 of the guide cylinder 6 have a conjugate shape in cross section;

 - the working element 9 has a round, or square, or triangular shape in cross section.

 5 The diametric volumetric machine according to the second embodiment comprises a housing 1 with an inlet 2 and an outlet 3 channels, located inside the cylindrical cavity 4 of the housing 1, a rotor made in the form of a leading end cylindrical faceplate 5, a guiding cylinder 6, mounted for rotation and with an eccentricity about the axis the leading faceplate 5 and having diametral channels 7 from the side of the leading face 5 and working elements 9 mounted on the leading face 5 with the possibility of movement in the channels 7 of the guide cylinder 6 when it is in growth, while in the cavity 4

15 of the housing 1 in the area of the inlet 2 and the outlet 3 channels, the inlet 10 and the outlet 11 of the cavity are not connected to each other, the guide cylinder 6 is made with an outer diameter equal to the diameter of the cavity 4 of the housing 1, and the diametrical channels 7 of the guide cylinder 6 are made through with respect to

20 of the axis of rotation of the guide cylinder 6 and have end walls 12 or end walls 12 with holes 8, while on the other opposite leading faceplate 5, the sides of the guide cylinder 6 with equal eccentricity are mounted in the housing 1 with the possibility of rotation

25 faceplate 13, on the end surface of which the ends of the fingers of the working elements 9 are fixed, while the end surfaces of the cavity 4 of the housing 1 and the end surfaces of the drive 5 and the support 13 of the face plates are in contact with the corresponding end surfaces of the guide cylinder 6, forming in the channels 7 of the guide cylinder 6 working chambers that alternately connected to the inlet 10 or outlet 11 cavity directly or through holes 8 of the end walls 12 in the channel 7, when the guide cylinder 6 is rotated, while the working elements 9, mounted on the leading 5 and supporting 13 5 faceplates, are made in the form of a finger or sleeve mounted on the finger with the possibility of rotation, or a plunger mounted on the finger with the possibility of rotation around the center of its longitudinal axis, while the working element 9 has a sliding fit in the channel 7 of the guide cylinder 6, and the stroke length of the working element 9 about ourselves to a length corresponding to the channel 7 of the guide cylinder 6, wherein the finger position on the radius of leading support 5 and faceplate 13 is in a ratio L = 4R at a ratio of rotational velocities of the leading 5, the support 13 and the guide chucks

15 of the cylinder 6 Vniii = 2Vpi4, where L is the stroke length of the working element 9, R is the radius of the finger on the leading 5, supporting 13 faceplates, equal to the eccentricity of the axis of rotation of the guide cylinder 6 relative to the axis of rotation of the leading 5, supporting 13 faceplates, Vrnu is the rotation speed leading 5 and

20 supporting 13 faceplates, Vpq - rotation speed of the guide cylinder 6.

 In such a diametrical volumetric machine, it is preferable:

- the guide cylinder 6 is installed in the housing on a sliding bearing;

 25 - the fingers of the working elements 9 are rigidly fixed to the leading faceplate 5;

 - the fingers of the working elements 9 are mounted on the leading faceplate 5 with the possibility of rotation;

- working elements 9 and channels 7 of the guide cylinder 6 have a mating shape in cross section; - the working element 9 has a round, or square, or triangular shape in cross section;

 - the fingers of the working elements are rigidly fixed to the support plate 13;

 5 - the fingers of the working elements 9 are mounted on the support plate 13 with the possibility of rotation.

 Diametric volumetric machine according to the first embodiment works as follows.

 When the rotor 5, made in the form of an end cylindrical faceplate, rotates, the working elements 9, moving along the corresponding diametrical channels 7 of the guide cylinder 6, rotate the guide cylinder 6 with a rotation speed half that of the faceplate 5 (Fig. 5). The radius of the finger on the faceplate 5 is equal to

15 the eccentricity of the axis of rotation of the guide cylinder 6 relative to the axis of rotation of the faceplate 5. In the working chamber formed by the end surfaces of the cavity 4 of the housing 1, the faceplate 5 and the guide cylinder 6 by the working element 9, a vacuum is created from the inlet cavity 10 of the inlet

20 channel 2 of the housing 1, and the working medium enters the working chamber.

 The process of suction of the working medium into the working chamber ends when the guiding cylinder 6, turning, overlaps the inlet cavity 10 of the housing 1, and the working element 9 moves to the intersection of the working chambers (center axis

25 rotation of the guide cylinder), where the working chambers are interconnected. At the same time, in the initial stage of the machine operation process, the working chambers are gradually filled. With further rotation of the guide cylinder 6 and the coincidence of the opposite end hole of the working chamber zo with the exhaust cavity 11, the working element 9 moves to the opposite side of the working chamber and the working medium moves into the exhaust cavity 11 with its subsequent entry into the exhaust channel 3 of the housing 1. Then the working element 9 reaches the “dead center” when the working element 9 changes the direction of translational movement along the diametrical channel 7 of the guide cylinder 6, and the process repeats. Similar movements occur in turn with all the working elements 9 in the corresponding diametrical channels 7 of the guide cylinder 6.

 In contrast to the first embodiment, the diametrical volumetric machine according to the second embodiment contains an additional support plate 13 on which the ends of the working elements 9 are attached. An additional support for the working elements 9 is created, which allows pumping the working medium at higher pressures. The working chambers are formed, in contrast to the first embodiment, with the end surfaces of the cavity 4 of the housing 1 and the end surfaces of the guide cylinder 6, the leading 5 and the supporting plate 13.

 The above ratios obtained experimentally provide the inventive plate machine with a high efficiency of pumping a working medium at high pressures.

Claims

CLAIM 1. Diametric volumetric machine, comprising a housing with inlet and outlet channels located inside 5 of the cylindrical cavity of the casing, a rotor made in the form of an end cylindrical faceplate, a guide cylinder mounted rotatably and with eccentricity relative to the axis of the faceplate and having open diametrical channels on the end face of the faceplate and working elements mounted on the faceplate with the ability to move to channels of the guide cylinder during its rotation, characterized in that in the cavity of the housing in the area of the inlet and outlet channels are made inlet not connected to each other and the outlet chamber, guide cylinder 15 is made with an outer diameter equal to the diameter of the body cavity and has end walls or end walls with holes in each diametrical channel, while the end surfaces of the body cavity, face plate and guide cylinder are in contact and form in the channels of the guide cylinder 20 working chambers, which are alternately connected to the inlet or outlet cavity directly or through an opening in the end wall of the diametric channel when the guide cylinder is rotated, while the working elements are mounted on the faceplate and made in the form of a finger, or a sleeve mounted on a finger with 25 the possibility of rotation, or a plunger mounted on the finger with the possibility of rotation around the center of its longitudinal axis, while the working element has a sliding fit in the channel of the guide cylinder, and the stroke length of the working element is limited by the length of the corresponding channel of the guide zo cylinder, and the radius of the finger on the faceplate is in the ratio L = 4R with the ratio of the speeds of rotation of the faceplate and the guide cylinder Vnm = 2Vpu, where L is the stroke length of the working element in the guide cylinder, R is the radius of the finger position on the faceplate equal to the eccentricity 5 of the axis of rotation of the guide cylinder relative to the axis of rotation of the faceplate, Vnui - the speed of rotation of the faceplate, Vpi4 - the speed of rotation of the guide cylinder. 2. The diametrical volumetric machine according to claim 1, characterized in that the u fingers of the working elements are rigidly fixed to the faceplate. 3. The diametrical volumetric machine according to claim 1, characterized in that the fingers of the working elements are mounted on the faceplate with the possibility of rotation.  fifteen  4. The diametrical volumetric machine according to claim 1, characterized in that the working elements and channels of the guide cylinder have a conjugate cross-sectional shape. 20 5. The diametrical volumetric machine according to claim 1, characterized in that the working element has a round, or square, or triangular shape in cross section. 6. A diametrical volumetric machine comprising a housing with 25 inlet and outlet channels, a rotor arranged inside the cylindrical cavity of the housing, made in the form of a leading end cylindrical face plate, a guide cylinder mounted for rotation and with an eccentricity relative to the axis of the leading face plate and having from the leading side face plates diametrical channels, and working elements mounted on the leading faceplate with the ability to move in the channels of the guide cylinder during its rotation, characterized in that in the body cavity in the area of the inlet and outlet channels are made not connected to each other 5, the inlet and outlet cavities, the guide cylinder is made with an outer diameter equal to the diameter of the body cavity, and the diametral channels of the guide cylinder are made through with respect to the axis of rotation of the guide cylinder and have end walls or end walls with its holes, while on the other side of the guide plate opposite the guide plate a cylinder with equal eccentricity is mounted in the housing with the possibility of rotation of the support plate, on the end surface of which the ends of the fingers of the worker are fixed x elements, wherein the end surfaces 15 body cavities and end surfaces of the driving and supporting faceplates are in contact with the corresponding end surfaces of the guide cylinder, forming working chambers in the channels of the guide cylinder, which are alternately connected to the inlet or outlet cavity 20 directly or through holes in the end wall of the diametrical channel during rotation of the guide cylinder, while the working elements mounted on the leading and supporting faceplates are made in the form of a finger, or a sleeve mounted on the finger for rotation, or a plunger mounted on the finger 25 with the possibility of rotation around the center of its longitudinal axis, while the working element has a sliding fit in the channel of the guide cylinder, and the stroke length of the working element is limited by the length of the corresponding channel of the guide cylinder, and the radius of the position of the finger on the leading and supporting zo faceplates is in the ratio L = 4R with the ratio rotational speeds of the leading and supporting plates and the guide cylinder Vniii = 2Vpi4, where L is the stroke length of the working element, R is the radius of the finger position on the leading and supporting plates, equal to the eccentricity of the axis of rotation 5 of the guide cylinder relative to the axis of rotation of the leading and supporting plates, Vnuj is the speed rotation of the leading and supporting faceplates, Urz - the speed of rotation of the guide cylinder. 7. The diametrical volumetric machine according to claim 6, characterized in that the guiding cylinder is installed in the housing on a sliding bearing. 8. The diametrical volumetric machine according to claim 6, characterized in that the fingers of the working elements are rigidly fixed to the leading plate. 9. The diametrical volumetric machine according to claim 6, characterized in that the fingers of the working elements are mounted on the leading faceplate for rotation.  twenty  10. The diametrical volumetric machine according to claim 6, characterized in that the working elements and channels of the guide cylinder have a conjugate cross-sectional shape. 25 11. The diametrical volumetric machine according to claim 6, characterized in that the working element has a round, or square, or triangular shape in cross section. 12. The diametrical volumetric machine according to claim 6, characterized in that the fingers of the working elements are rigidly fixed to the support plate. 13. The diametrical volumetric machine according to claim 6, characterized in that the fingers of the working elements are mounted on the supporting plate with the possibility of rotation.