SU110316A1 - Differential automatic hydraulic transmission - Google Patents

Description

FHGs are stepless differential automatic hydraulic transmissions whose pump casing is simultaneously a rotorol of a vane hydraulic engine, allowing for the possibility of hoosening of the hydraulic transmission blocking, turning it into a hydraulic coupling at zero eccentricity of the hydraulic engine.

However, these volumetric hydraulic transmissions have a low efficiency, and they provide a continuous progressive change in the transmission ratio, provided that the performance of the hydraulic pump or displacement of the hydraulic engine is varied.

A feature of the described hydraulic transmission, free from the above disadvantages, is the use of a hydraulic cylinder equipped with a spool device with a spring pressure regulator of the working fluid of the hydraulic cylinder, the piston of which is coupled with the outer movable body of the hydraulic engine. The principle of operation of the hydraulic transmission, according to the invention, is based on hydrocoupling, in which instead of

The DRS.Slei is supplied with a variable propel motor.

FIG. shows a longitudinal section of the transmission; in fig. 2 is a section along AA in FIG. one; in fig. 3-channel layout inside the transmission and spool device.

On the drive shaft 1 / the gear pinion 2 is fixed, in engagement with which there are driven gears 3 located in the sockets of the housing 4. The trunnions of the end plates 5 and 6 of the hydraulic pump are threaded onto the bearings 7.

The outer housing 1 of the drive motor consists of two flanges 8 and a cylindrical sleeve 9. along the inner surface of which the blades 10 are mounted, which are installed in the grooves of the hydraulic pump housing; the outer case is mounted with its axles in bearings //, which are fixed in the eyes of the earring 12, hingedly suspended from the transmission body on the axles 13.

In the end plate 5 of the hydraulic pump housing there are six radial channels 14 for supplying fluid to the working cavity of the hydraulic engine and inclined channels 15, which communicate the working cavities of the pinhole pumps from the full hydraulic engine. To separate the injection and discharge cavities of the pump and the hydraulic engine, a spool 16 is used, the axial channel of which is designed to divert the working fluid from the injection cavity to the automatic control system.

The automatic control system consists of a piston 17 with IUTOKOM 18, placed into the hydraulic cylinder 19 and connected to the link 12 of the suspension of the outer housing of the hydraulic engine. The flow of the working fluid into one or another cavity of the cylinder is controlled by the spool 20. When the load on the follower changes, the pressure in the system changes, while the spool 20, compressing the spring 21, moves and opens the connecting channels 22. The working fluid enters the cylinder 19, moving the piston 17 and thus changing the value of the eccentricity of the outer casing and the rotor of the hydraulic engine, which in its

the turn causes a change in torque on the driven shaft. A manometer 23 serves to monitor the pressure in the system.

PREd. M e invented and

A stepless differential automatic hydraulic transmission, the pump casing of which is simultaneously a rotor of a vane hydraulic motor, allows the ability to block the hydraulic transmission, turning it into a hydraulic coupling at zero eccentricity of the hydraulic motor, which is different in that for the automatic torque change on the shaft of the shaft, the shaft of the hydraulic shaft will be automatically changed by the shaft shaft. from the load, while maintaining a given constant torque on the drive shaft, a spring-loaded spool device is used. regulator working fluid pressure hydraulic cylinder, the piston of which is articulated to the outer movable body hydromotor. --- M-TSTSHTB .1l. .:.