RU2843U1 - HYDRAULIC MACHINE - Google Patents

Abstract

A hydraulic machine with an adjustable displacement, comprising a housing with a cylindrical chamber mounted eccentrically with a possibility of displacement relative to the housing of the rotor with plates in radial grooves and a regulator for changing the position of the rotor relative to the housing, characterized in that the rotor is mounted in the chamber with axial movement, disk pistons are mounted at its ends to rotate, adjacent by an outer edge to the surface of the chamber, working cavities are formed between the pistons and the ends of the chamber, connected through the fluid supply and drain holes to the regulator, a rotary disk-separator with radial grooves for the plates coaxial to the rotor is installed in the housing with rotation, and seals are pressed in the grooves of the separator ring pressed to the outer ends of the plates.

Description

HYDRAULIC MACHINE.

This utility model relates to volumetric hydraulic machines / pumps, compressors and hydraulic motors / with variable displacement and is a rotary or plate adjustable hydraulic machine.

Known hydraulic machines with adjustable displacement, comprising a housing with a cylindrical chamber, mounted ex-centrically with the possibility of displacement relative to the housing of the rotor with plates in radial grooves and a regulator for changing the position of the rotor relative to the housing / see USSR author's certificate J 1689659, CL R 04C 5 / 00.1989, g. /. In such machines, the casing design is extremely complicated. In addition, it is difficult to ensure the stability of the working volume in the given position of the regulator, since even the smallest change in the eccentricity of the rotor due to the instability of the position of the regulatory body leads to a significant change in the working volume.

In this utility model, these drawbacks are eliminated by the fact that the rotor is mounted in the chamber with the possibility of axial movement, disk porches are mounted on its ends, rotatable with an outer edge to the surface of the chamber, working cavities are formed between the pistons and the ends of the chamber, connected through the feed openings and draining the liquid to the regulator, a rotary disc separator with radial grooves for the plates coaxial to the rotor is installed in the housing with rotation, and seals are placed in the grooves of the separator ring.

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/ 5 / F 04 C 5/00, P 04 C 18/844 P 01 C I / 344

prtted to the outer end faces of the plates.

On Fig I presents a General view of the hydraulic machine with a section along aa.

The hydraulic machine has a housing I with a cylindrical chamber 2 shown in dashed cross section nA. In the chamber 2 with an eccentricity e, a rotor 3 with radial grooves 4 and plates 5 placed in them is installed. The rotor 3 is mounted in the chamber 2 with the possibility of axial movement, and 6.7 disc gusses are mounted on its ends with the possibility of rotation, the outer edges of which are adjacent to the inner surface of the chamber 2. The disks 6.7 are connected to the rotor. For example, elastic rings 8.9, which fix the pistons from axial movement relative to the rotor Z. B groove Ah, on the rim of the pistons 6,7, sealing rings 10,11 are installed, sealing the gap between the Porn 6,7 and the chamber 2. Between the pistons 6,7 and the ends of the cage 2, working cavities 12, 18 are formed. Bores 14,15 are made in the walls of the housing I which the cavities 12,13 communicate with not shown in FIG. volume control The plates 5 are pressed against the inner surface of the chamber 2 by the springs 16. The housing I is rotatably mounted with a disk separator 17 with radial grooves 18 for the plates 5. The grooves 18 are equipped with seals 19, which are pressed against the outer ends of the plates 5 by the springs 20. Application of the springs 20 not necessary if the seals 19 are made of a material having sufficient elasticity and completely filling the grooves 18.

The hydraulic machine operates as follows.

In the pump mode, the liquid is supplied to the interplate region of the rotor and transferred to the injection zone with a higher pressure. The inlet and outlet channels in FIG. are not shown and can be executed 1 in any known manner. In the position shown in FIG., only the rotor frequency that is located to the left of the separator disk 17 is operated. To the right of the separator disk, the liquid circulates in the interplate rotor cavities and channels of the housing. Non-working and working Hour and rotor are separated by a ring, which rotates together with rotor Z. In this case, plates 5 move both in the grooves of rotor 3 and in the grooves of ring 18, 17. Seals 19 prevent fluid from flowing from the idle to the working one and vice versa. valo the engine is not shown; by the Anna in Fig. a spline coupling that allows longitudinal movement of the rotor Z. If it is necessary to increase the working volume, the regulator through the hole 14 delivers the liquid under pressure into the right working cavity 12, communicating with the drain the left working cavity 13. In this case, the rotor 8 is displaced to the left. The length of the working part of the rotor 3 and, consequently, the working volume of the pump increase. When communicating with the discharge of the cavity 12, and with the source of high pressure of the cavity 13 in the same way decreases. working volume of the pump. The working volume in the hydraulic motor mode is similarly regulated. This design of the hydraulic machine allows it to regulate its working volume over a wide range, ensuring its stability in every position. Moreover, the design of the hydraulic machine elements, especially the housing, is about flocking / simple and reliable.

Claims (1)

A hydraulic machine with an adjustable displacement, comprising a housing with a cylindrical chamber mounted eccentrically with a possibility of displacement relative to the housing of the rotor with plates in radial grooves and a regulator for changing the position of the rotor relative to the housing, characterized in that the rotor is mounted in the chamber with axial movement, disk pistons are mounted at its ends to rotate, adjacent by an outer edge to the surface of the chamber, working cavities are formed between the pistons and the ends of the chamber, connected through the fluid supply and drain holes to the regulator, a rotary disk-separator with radial grooves for the plates coaxial to the rotor is installed in the housing with rotation, and seals are pressed in the grooves of the separator ring pressed to the outer ends of the plates.