RU144785U1 - REVERSIBLE HYDRODYNAMIC BEARING - Google Patents

Abstract

Reversible hydrodynamic bearing, containing segmented inserts with spherical holes, located in the housing uniformly around the circumference and mounted on hinged spherical bearings with the possibility of self-alignment, characterized in that the spherical bearings are made in the form of hollow pins plugged with screws connected to a high pressure source and mounted on the housing with the help of rings and screws, while the pins are located relative to each other at an angle of 120 °, and the segmented inserts with spherical holes are made symmetrically ary relative to the pin axis.

Description

The utility model relates to the field of machine tools and can be used in spindle bearings of precision machine tools.

A known design of a radial single row roller bearing (AS No. 1784776, IPC F16C 33/46, publ. 12/30/1992, bull. No. 48], containing the outer and inner rings, one of which has extreme sides of the same height, rollers and The sockets for rolling elements are made alternately open from the side of different ends and from the input side of the rollers with conical sections.

The disadvantage of this design is the low range of operating speeds, due to the rapid wear of rubbing surfaces.

A known design of a radial segment bearing (AS No. 1493810, IPC F16C 27/02, publ. 07/15/89, bull. No. 26), containing liners located in the housing evenly around the circumference, resting on the spherical ends of the rods through thrust bearings with cavities, connected through channels to a low pressure source.

A design disadvantage of this radial segmented bearing is the limitation of the technological applicability of the reverse mode.

The objective of the claimed utility model is to expand the technological capabilities of a hydrodynamic bearing, by providing a reverse mode of operation.

This problem is solved due to the fact that the reversible hydrodynamic bearing contains segmented inserts with spherical holes located in the housing evenly around the circumference and mounted on articulated spherical bearings with the possibility of self-alignment. In this case, the spherical supports are made in the form of hollow pins that are plugged with screws, connected to a high pressure source and fixed to the housing with rings and screws, while the pins are located relative to each other at an angle of 120 °, and the segmented inserts with spherical holes are made symmetrical about the axis of the pin .

The technical result provided by the claimed combination of features is achieved by using symmetrical liners and consists in ensuring a uniform gap between the spindle and the segment liner relative to the axis of the pin, which makes it possible to apply a reverse mode of operation of the hydrodynamic bearing.

The utility model is illustrated by drawings, where in FIG. 1 shows a reversible hydrodynamic bearing in section, and in FIG. 2 - the location of the reversible hydrodynamic bearing on the spindle of the machine.

The reversible hydrodynamic bearing comprises segmented liners 2 located in the housing 1 with spherical holes located uniformly around the circumference of the housing and mounted on hinged spherical bearings 3 with the possibility of self-installation. In this case, the spherical supports are made in the form of hollow pins plugged with screws 4, connected to a high pressure source and fixed to the housing with rings 5 and screws 6, while the pins are located relative to each other at an angle α = 120 °, and the segmented inserts 2 with spherical the holes are made symmetrical about the axis of the pin.

In the radial hole of the lid 7, there is a fitting 8 for supplying oil to the groove K (not shown in the figures), through which oil enters the end openings of the lid. In the end openings of the cover 7 of the bearing housing 1, throttling screwdrivers 9 are installed to ensure the mounting gap Δ _P , due to which the oil pressure in the closed pockets of the segmented inserts 2 will be adjusted.

Reversible hydrodynamic bearing operates as follows. The installation clearance is pre-set for the formation of an oil wedge using rings 5 and screws 6. When assembling by grinding the thickness of the rings 5 into a pre-measured size, the position of the axis of the spindle 10 relative to the axis of the base hole of the spindle system of the machine, and the radial installation clearance Δ _M between the working surfaces of the segmented liners 2 and the spindle 10, which is necessary for the formation of an oil wedge during rotation of the spindle.

The oil is supplied into closed pockets from the pump of the hydraulic power station under pressure and through the nozzle 8 it enters the groove K (not shown in the figures) of the cover 7, in which the oil pressure is regulated by throttling screw-drivers 9. Then the oil enters the holes of the spherical bearings 3 through which it enters into the pockets of the segmented liners 2. Hydrostatic pressure prevents the friction of the surface of the segmented liners on the spindle surface when the spindle starts to rotate.

When the spindle 10 rotates in the gap between the segmented liners 2 and the spindle 10, a low pressure region is formed, as a result of which the segmented liners 2 rotate through an angle to form an oil wedge. Due to the oil wedge, the spindle self-centers.

Claims (1)

Reversible hydrodynamic bearing, containing segmented inserts with spherical holes, located in the housing uniformly around the circumference and mounted on hinged spherical bearings with the possibility of self-alignment, characterized in that the spherical bearings are made in the form of hollow pins plugged with screws connected to a high pressure source and mounted on the housing with the help of rings and screws, while the pins are located relative to each other at an angle of 120 °, and the segmented inserts with spherical holes are made symmetrically ary relative to the pin axis.