SU1710890A1 - Hydrostatic worm-rack transmission with automatically maintained mesh clearances - Google Patents

Abstract

The invention relates to a machine tool industry, in particular to mechanical gears that are used in machine tools. The purpose of the invention is to increase reliability by increasing transmission stability with changing load characteristics. As the load on the rail 2 increases, the gap between one of the sides of the screw 3 and the rail 2 decreases. The pressure in this working gap and the corresponding cavity of the hydraulic cylinder 6 increase. Under the action of the pressure difference in the cavity of the hydraulic cylinder 6, the plunger 7 is displaced relative to the radial hole 11 for supplying oil. The length of the helical groove 12 from hole 11 to the high pressure cavity decreases, and to the low pressure cavity increases. As a result of the change in the resistance of the helical groove sections 12, the flow of the supplied oil is redistributed, which leads to the restoration of the worm clearance to the rail. Thus; In this way, the oil distributor 1 automatically maintains the gap in the mesh when changing the load characteristics. 1 il. SO with

Description

The invention relates to machine tool industry, in particular to mechanical gears that are used in metal cutting machines.

Known transmission screw-nut fluid friction with a constant or adjustable clearance in the thread, containing channels of the lubricating system, designed to reduce friction, and the sides of the thread profile of the nut are made with chambers that are connected to the channels in the body of the nut to supply oil to the chambers, and at the entrance to the channels, chokes or regulators are installed that support the specified rigidity of the oil layer. However, the presence of two independent regulators in this device used to control one object - a table, causes so difficult to set up and complicates the design, which reduces reliability.

The closest solution to the invention is a hydrostatic worm gear with automatic maintenance of the gaps in engagement, containing an oil distributor, a rail, a worm interacting with it, on the side surfaces of which are made pocket and channels communicating with the oil distributor, the oil distributor being made in the form of two covers and membranes fastened together, a strap installed between the covers and connected to the membranes of at least two tubes of elastic material communicated with m the distributor and located between the facing surfaces of the bar and covers and one interchangeable spacer installed between the membranes and designed to control the cross section of the tubes.

'A disadvantage of the known design is the low reliability, due to _λ low transmission stability when changing load characteristics due to the inability to control the stiffness of the elastic tubes during operation of the device. In addition, in the hydrostatic worm, in the engagement of the turn with the rail during rotation, an even or odd number of supply channels enters. In this case, the resistance to oil flow at the exit of the worm periodically changes, which entails periodic pressure fluctuations. Thus, the presence of membranes in the device determines a high sensitivity to such vibrations, contributing to the occurrence of self-oscillations in the machine.

The aim of the invention is to increase reliability by increasing transmission stability when changing load characteristics. ...

This goal is achieved by the fact that in a hydrostatic worm-rack and pinion with automatic maintenance of gaps in the engagement, containing an oil distributor, a rail and a worm interacting with it, on the side surfaces of the turns of which pockets and channels communicating with the corresponding oil distributor cavities are made, the oil distributor is made in the form a hydraulic cylinder, in the cylindrical part of which there is a radial hole for supplying oil, the axis of which is equidistant from the ends of the hydraulic cylinder, and the plunger has a helical groove on a cylindrical surface in communication with a radial hole and spring-loaded with two springs of adjustable stiffness, abutted at one end to the corresponding ends of the plunger.

The invention is characterized in that the oil distributor is made in the form of a hydraulic cylinder, in the cylindrical part of which there is a radial hole for oil supply, the axis of which is equidistant from the ends of the hydraulic cylinder, and the plunger has a helical groove on the cylindrical surface, in communication with the radial hole and spring-loaded with two springs of adjustable stiffness, abutted one ends to the corresponding ends of the plunger.

The drawing shows a hydrostatic worm-rack gear, section.

The hydrostatic worm-rack transmission contains an oil distributor 1 for supplying lubricant, a rail 2 and a worm 3 interacting with it, pockets 4 are made on the lateral surfaces of the coils of the coil, connected by channels 5 to the oil distributor 1. The oil distributor is made in the form of a hydraulic cylinder 6, inside which a plunger 7 is installed spring-loaded from the ends 8 by the springs 9. The stiffness of the springs 9 is adjusted using screws 10. The plunger 7 divides the cavity of the hydraulic cylinder 6 into two separate cavities connected by channels 5 to the corresponding chervyaka.Z pockets. In the cylindrical part of the hydraulic cylinder 6 there is a radial hole 11 for supplying oil, the axis of which is equidistant from the ends of the hydraulic cylinder 6. On the cylindrical surface of the plunger 7, a through helical groove 12 is made, communicating with the radial hole 11.

The transfer works as follows.

Lubricating fluid through the radial hole 11 is fed into the oil distributor 1 and then through the channels 5 into the pockets 4 of the worm 3. With uniform loads on both sides of the turn of the worm 3, the plunger 7 is in the neutral position, i.e. its ends 8 are located at equal distance from the radial hole 11, through which fluid is supplied, and the pressure in both cavities of the hydraulic cylinder 6 is the same.

When the load on the rack 2 changes, the pressure changes in the engagement of the worm rack. For example, with an increase in the load on the rail 2, the gap between one side of the turn of the worm 3 and the rail 2 will decrease, respectively, the pressure in this working gap will increase. The pressure also increases in the corresponding cavity of the hydraulic cylinder 6, under the action of more pressure, the plunger 7 moves to the side / Cavity with low pressure, shifting relative to the radial hole 11. The length of the section of the plunger 7, and therefore the groove 12 from the side of the low pressure cavity to the inlet radial hole 11 will be more, and from the side of the high-pressure cavity - less.

Reducing the length of the helical groove communicating with the high-pressure cavity leads to a decrease in the resistance of a given section of the helical groove, and increasing the length of the helical groove communicating with the low-pressure cavity leads to an increase in the resistance of this section of the groove. As a result of changes in the resistance of the sections of the helical groove leading the mablo to the cavities of the hydraulic cylinder 6, the flow rate of the supplied oil is redistributed, i.e. the oil supply decreases into the cavity with low pressure, and increases into the cavity with high pressure. Consequently, the oil consumption on the loaded side of the worm coil increases, which leads to the restoration of the initial clearance of the worm rack, changed by the loading of the gear.

The movement of the plunger 7 in the hydraulic cylinder 6 stops as soon as the entire system is again in a state of equilibrium and the clearances in the engagement of the worm are restored. The stiffness of the springs 9 is adjusted using screws 10. It is slightly more stiff than the springs, i.e. the more they are compressed by screws 10, the lower the sensitivity of the plunger 7 to a change in pressure on it, and vice versa. Thus, by adjusting the stiffness of the springs with 9 screws 10, the sensitivity of the plunger to pressure changes in the worm gear mesh is reduced or increased depending on the load during operation. ι

Claims (1)

Claim A hydrostatic worm-rack and pinion gear with automatic maintenance of clearance in engagement, containing an oil distributor, a rail and a worm interacting with it, on the side surfaces of the turns of which pockets and channels are made, communicating with the corresponding oil distributor cavities, which is characterized by the fact that, in order to increase reliability by increasing transmission stability when changing load characteristics, the oil distributor is made in the form of a hydraulic cylinder, in the cylindrical part of which there is a radial an oil supply hole, the axis of which is equidistant from the ends of the hydraulic cylinder, and the plunger has a helical groove on the cylindrical surface in communication with the radial hole, and is spring-loaded with two springs of adjustable stiffness, abutted at one end to the corresponding ends of the plunger. , 50 ₍ Compiled by L. Reisbich