SU769031A1 - Plate-type hydraulic engine - Google Patents

Description

windows 22, auxiliary windows 23 connected by channels 24 with through windows 21, blind auxiliary windows 25. Disk

18 has through windows 26, blind main windows 27, auxiliary windows 28 connected by channels 29 to through windows 26, blind auxiliary windows 30 and an annular groove 31. Windows 21 and 23 are connected to channel 19, and windows 26 and 28 to channel 20. The drainage cavity 32 around the shaft 14 is connected to the cavity 11 by a channel 12.

Between the thickened part of the plate 7 and the rotor 5 there is a cavity 33.

Windows 21, 23, 27 and 30, as well as windows 22, 25, 26 and 28, form high or low pressure cavities.

Through the housing 1, the disk 17, the stator 3, the disk 18 and the cover 2 passes the locking pin 34.

Plates 7 can be made of composite elements 35, 36 (Fig. 5).

Stepwise incision 6 can be obtained by installing a step insert 38 in a rectangular slot 37, which, like the plate 7, can be made of two parts. For radial fixation of the insert 38 relative to the rotor, a latch 39 in the form of a pin can be used. The groove 37 is made notches 40 (Fig. 6). In the drain line 41 of the hydraulic motor 42, a retaining device 43 is installed. The hydraulic motor 42 is connected to the pump 44 and the retaining device 43 through a reversing valve 45.

When the rotor is rotated counterclockwise, the windows 21 are low pressure cavities and the windows 22 are high pressure cavities, and when rotated clockwise, vice versa.

The motor operates as follows.

When the working fluid is supplied to the lid 2 through the channel 20 and the window 26, it enters the working chambers of the motor formed by the plates 7, the rotor 5, the stator 3 and the disks 17 and 18, as a result of which the shaft 14 of the motor rotates in a counterclockwise direction (as viewed from shaft side 14). From the working chambers located against the windows 21 and reducing their volume during the rotation of the rotor 5, the working fluid is drained through the windows 21, the channel

19 in the housing 1 to the drain line of the hydraulic system. When the plates 7 pass by the windows 26 of the cavity 33 are connected to the windows 28, which are connected to the windows 26 by channels 29, therefore the pressure above the plates 7 is equal to the pressure below the plates. Since the end of the thickened part 9 of the plates 7, which communicates with the windows 28, the end face of the narrow part 8, which communicates with the windows 26, a force acts on the plates 7 in the radial direction, pressing them against the stator 3 (due to the fact that with

drainage, the pressure in this cavity is approximately equal to the condition). Blank windows 22 and 25 in the disk 17 and windows 27 and 30 in the disk 18 serve to axially balance the rotor 5 with the pressure of the working fluid.

When plates 7 pass by windows 21, cavities 33 are connected to windows 23 communicating with windows 21 by channels 24, and therefore the pressure above the plates 7 is equal to the pressure below the plates and equal to the pressure on the drain from the hydraulic motor.

Thus, during operation of the hydraulic motor, the cavity 33 between the thickened part of the plates 7 and the rotor 5 alternately communicates with the high and low pressure cavities, and the groove 13 connected to the cavities 10 in the rotor 5 formed by the thickened 9 and the narrow 8 parts of the plates 7, constantly communicated with the drainage cavity.

When supplying the working fluid to the channel 19 and draining through the channel 20, the operation of the hydraulic motor is similar, but the shaft 14 rotates in the opposite direction (clockwise).

Work composite plates of elements 35, 36 as described.

When the hydraulic motor is operating, in the gap between the plates 7 and the walls of the grooves 6 of the rotor 5 there is a pressure of the working fluid (for

leakage), and the cavity 10 between the plates is permanently connected to the drainage. Thus, there is a force in the direction perpendicular to the direction of the rotor slots 6, which increase the resistance to movement in the slot of the plate 7. The notches 40 serve to reduce these forces, since they are permanently connected to the drainage cavity 11 by means of the groove 13 of the distribution disk 17.

With the help of the retaining device 43 (Fig. 6), the force of pressing the plates 7 to the stator 3 is regulated as the plates pass past the low pressure cavity. The communication of the cavity under the thickened part of the plate alternately with the high and low pressure cavities, and the grooves on the distribution disk with the drainage cavity, as well as installation of a low-pressure device in the low-pressure cavity, ensure that the hydraulic motor reverses when the plates are reliably pressed to the stator.

Making grooves or plates in the walls of the grooves communicated with the distributor disk groove reduces mechanical losses, and making plates of elements of different thickness simplifies the manufacturing technology.

Claims (4)

1. A lamellar hydraulic motor, comprising a housing with drainage cavities, high and low pressure, and a rotor with stepped plates installed in the slots of the latter, forming with their thickened and narrow portions in the rotor, communicated with a groove on the end face of the distribution disc, characterized in that in order to ensure the reversal of the hydromotor, the groove is connected to the drainage cavity, and the cavity between the thickened part of the plate and the rotor is alternately connected to the high and low pressure cavities. 2. A hydraulic motor according to claim 1, characterized in that, in order to reduce mechanical losses, grooves (or plates) are made in the walls, grooves communicated with the groove of the distribution disk. 3. Hydromotor on PP. 1 and 2, which is also distinguished by the fact that, in order to increase reliability, a retaining device is installed in the low pressure cavity. 4. Hydromotor on PP. 1 and 2, characterized in that the plates are made of composite elements of different thickness. Sources of information taken into account in the examination 1. US patent No. 3421413, cl. 418-80, publ. 1969.