SU1314159A1 - Elastic bearing - Google Patents

Abstract

The invention relates to the field of mechanical engineering and can be used in elastic bearing supports of rotary machines. The goal of retreat is to increase the vibration resistance of the elastic support. This goal is achieved by the fact that, to an elastic sleeve with external and internal stiffness parts connected by elastic elements formed by stepped grooves located on concentric circles and connected by radial transitions, disks are rigidly fixed at the ends. These discs have sectorial axial protrusions at the ends facing the elastic sleeve. The sectorial protrusions are placed in the grooves of the inner concentric row, and the gap between the outer radius of the sectorial protrusions and the inner radius of the elastic sectorial elements does not exceed the maximum permissible vibration amplitude of the rotor. The ends of the elastic sleeve due to the rigid attachment to her drive tightly pressed to the ends of the disks facing her. 2 Il. 5 (L ate with

Description

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The invention relates to mechanical engineering and can be used in elastic bearing supports of rotary machines.

The purpose of the invention is to increase the vibration resistance of the elastic support.

Fig; 1 shows the elastic support, cross section; in fig. 2 - the same, axonometric, parsed state.

The elastic support consists of an elastic sleeve 1, which contains rigid parts: external 2 and internal 3, interconnected by elastic elements 4. Elastic elements 4 are formed by through sectorial grooves: internal 5 and external 6, lying in two concentric circles. the end of each internal groove 5 is connected to the beginning of the corresponding external groove 6 by radial grooves 7. This embodiment of the grooves 5 and 6 forms elastic elements 4, each of which is connected with one hard end to the internal rigid part 3 of sleeve 1 by means of m radial jumpers 8, and the other end with the outer rigid part 2 through radial jumpers 9. At the ends 10 and 11 of the sleeve 1 installed disks 12 and 13, rigidly mounted on the inner hard part 3 of the sleeve 1. At the ends of the disks 12 and 13, facing the sleeve 1, the end protrusions 14 and 15 are inserted into the grooves 5 of the inner row, and the inner surfaces 16 and 17 of the projections 14 and 15 are in contact with the inner surface 18 of the notches 5, and the radius of the outer surfaces 19 and 20 of the projections 14 and 15 are smaller outer surface radius 21 by an amount equal to ma maximum DUTY allowable amplitude oscillations of the rotor mounted in the resilient support.

The elastic support works in the following way.

When the rotor rotates, vibrations arise, caused, for example, by residual unbalance. At the same time, radial movements of the inner rigid part 3 of the sleeve 1 relative to its outer rigid part 2 occur. This is ensured by the elastic deformation of the elastic elements 4, in which the bridges 8 are displaced in the radial direction relative to the bridges 9. Therefore, the end faces

five

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the surfaces of the elastic elements 4 perform oscillatory movements, the larger the larger the section of the elastic element 4 closer to the jumper 9. At the same time

5, these amplitudes are equal to the amplitudes of the vibrations of the disks 12 and 13 only in the sections located in close proximity to the jumpers 9. Thus, there is a relative radial movement of the ends of the elastic elements 4 relative to the internal ends of the disks 12 and 13. This provides friction inside the elastic support and, therefore, its constructive damping. The disks 12 and 13 have the same vibrations as the internal hard part 3 of the bushings 1. Therefore, the end protrusions 14 and 15 of the disks 12 and 13 have the same vibration amplitudes that

0 and the internal hard part 3 of the sleeve 1, and hence the rotor mounted in an elastic support. When these amplitudes reach a gap between the outer surface 21 of the grooves 5 of the bushings 1 and the outer surfaces 19 and 20 of the end projections 14 and 15 of the discs 12 and 13, the outer surfaces 19 and 20 of the projections 14 and 15 abut against the surface 21 in the radial sections close to the ridges 8 of the sleeve 1. This limits the further increase in the amplitudes of the vibrations of the rotor. Jumpers 8 and 9 with their ends are clamped between the disks 12 and 13,

35 which eliminates the mutual axial movement of the inner rigid part 3 of the sleeve 1 relative to its outer rigid part 2. This increases the axial rigidity of the elastic support without

40 changes in its radial stiffness.

The limitation of the maximum vibration amplitudes of the rotor and the structural damping, which are provided by the design of the elastic support, increase its vibration resistance. Increasing the axial stiffness of the elastic support without changing its radial stiffness makes it possible to increase the loads perceived by the support in

50 axial direction, and increase its structural damping, which also increases the vibration resistance of the elastic support, the bearing life, reduces vibration and

Claims (1)

55 generated by rotary noise. Invention Formula Elastic support containing sleeve with external and internal rigid hour30 t-connected elastic elements separated by concentric rows of axially through grooves uniformly circumferentially distributed; the end of each groove of one row is connected to the beginning of the groove located in the adjacent concentric row, characterized in that to increase vibration resistance by increasing its axial stiffness without changing the radial stiffness, limiting the amplitudes vibrations and creation of structural damping, it is equipped with disks fixed to the ends of the inner rigid part of the sleeve with end sectoral protrusions whose outer diameter is less than the diameter of the inner surfaces of elastic elements, and the outer diameter of the disks is less than the outer diameter of the outer surfaces of the grooves of the outer concentric row of outer diameter of the elastic elements. 2 1 19 21 I 12 6 10 one ////////////// ..7 /// 7 ///////// 7 // 7A - t one ////////////// eleven fig 1 21 FIG. 2 18