RU124340U1 - Vibration Isolator - Google Patents

Abstract

A vibration isolator comprising a housing, an elastic element of an elastomer interacting with the object, and a base, characterized in that it comprises a central rod installed in the base plate, a restrictive metal washer and a buffer stroke limiter made of elastomer mounted on the central rod, the housing consists of the base of the upper and lower parts connected with the base plate, the base is connected to the object, and the elastic element of the elastomer consists of central, peripheral and lower ring blocks, at m the central and lower ring blocks are made of material with increased, and the peripheral ring block is reduced compliance in axial and lateral directions, the inner surface of the annular peripheral block has a cylindrical shape corresponding to the shape of the outer surface of the annular central block, in which the inner surface has the shape of a truncated cone , the diameter of the lower base of which is equal to the diameter of the Central rod, and the inner side surface is made wavy, the outer surface The part of the annular peripheral block has a cylindrical shape at a part of its height corresponding to the shape of the inner surface of the upper part of the housing, at the other part of the height, it has the shape of a truncated cone, the inner surface of the annular lower block has a cylindrical shape corresponding to the shape of the central rod, the outer surface of the annular lower block has the shape a truncated cone in contact with the upper base with the central and peripheral blocks, and the lower base having a wavy surface with the inner

Description

The utility model relates to mechanical engineering, namely to the design of general-purpose vibration isolators.

A known vibration isolator for technological equipment, comprising a housing and an elastic element of elastomer interacting with the object, the housing is made in the form of a rectangular base to which the lid is attached, and the center and mounting holes are made in the base, the elastic element is located between the inner surface of the lid and the outer the surface of the installation element, made in the form of a sleeve with a Central hole and a shoulder, and the elastic element in the lower part has a recess in the form of an arch, and thicknesses elastomer arch over and under the rib is 10% ... 20% of the height of the elastic member [Pat. 2305805 RF, IPC F16F 1/36, publ. 09/10/2007].

A disadvantage of the known design of a vibration isolator for technological equipment is that an elastic element made of an elastomer is a monolithic rubber block and has limited capabilities to adaptively change its elastic and damping properties when axial and lateral vibrational loads with different frequencies act on it.

The closest in technical essence to the utility model is a rubber vibration isolator containing an elastic element from an elastomer interacting with an object, and a housing made in the form of a sleeve resting on the upper end face of the elastic element and a ring connecting the housing to the base through a peripheral undercut, while the ratio of the height of the vibration isolator h to the diameter D of the supporting surface is in the optimal ratio of values: h / D = 0.45 ... 0.55 [Pat. 2302566 RF, IPC F16F 1/37, publ. 07/10/2007].

A disadvantage of the known design of the rubber vibration isolator is that the elastic element of the elastomer is a monolithic rubber block and has limited capabilities to adaptively change its elastic and damping properties when axial and lateral vibrational loads with different frequencies are applied to it.

The objective of the utility model is to create a vibration isolator circuit that provides improved quality of vibration isolation when used in the suspension of a sprung object.

EFFECT: increased vibration-isolating qualities of a vibration isolator due to adaptive changes in its elastic and damping properties depending on the amplitudes and frequencies of axial and lateral vibrational loads acting on it.

The specified technical result is achieved by the fact that in the vibration isolator containing the housing, an elastic element of elastomer interacting with the object and the base, the central rod installed in the base plate, a restrictive metal washer and a buffer stroke limiter made of elastomer installed on the central rod, the housing consists of associated with the base of the upper and associated with the base plate of the lower parts, the base is connected with the object, and the elastic element of the elastomer consists of a central, peripheral and lower face blocks, while the central and lower ring blocks are made of material with increased, and the peripheral ring block is reduced compliance in axial and lateral directions, the inner surface of the annular peripheral block has a cylindrical shape corresponding to the shape of the outer surface of the annular central block, which has an inner surface has the shape of a truncated cone, the diameter of the lower base of which is equal to the diameter of the central rod, and the inner side surface is made of a wave on the part of its height, it has a cylindrical shape corresponding to the shape of the inner surface of the upper part of the housing, on the other part of the height, has the shape of a truncated cone, the inner surface of the annular lower block has a cylindrical shape corresponding to the shape of the central rod, the outer surface of the annular lower the block has the shape of a truncated cone in contact with the upper base with the Central and peripheral blocks, and the lower base having a wave surface - with the inner surface of the lower part of the body.

In Fig.1 shows a vibration isolator in section; figure 2 is an annular Central block in the context; figure 3 is an annular central block, a view along arrow A; figure 4 is an annular lower block in the context; in Fig.5 is an annular lower block, view along arrow B, in Fig.6 is the dependence of the axial deformation of the vibration absorber on the axial load, in Fig.7 is the dependence of the lateral deformation of the vibration isolator on the lateral load.

The vibration isolator (Fig. 1) includes the upper 4 connected to the base 1 and the lower 4 body parts connected to the base plate 3, an elastic element made of elastomer, consisting of a central 5, peripheral 6 and lower 7 ring blocks, a central rod 8 installed in a base plate 3 associated with a vibration source, a restrictive metal washer 9 and a buffer stroke limiter 10 made of elastomer mounted on the central rod 8, the base 1 being connected to the sprung object.

The outer surface of the annular central block 5 has a cylindrical shape, and the inner one is the shape of a truncated cone, the diameter of the lower base of which is equal to the diameter of the central rod 8, and the inner side surface of the truncated cone is made wavy (figure 1, figure 2, figure 3).

The inner surface of the annular peripheral block 6 has a cylindrical shape corresponding to the shape of the outer surface of the annular central block 5, and is in contact with it. The outer surface of the annular peripheral block 6 on a part of its height has a cylindrical shape corresponding to the shape of the inner surface of the upper 2 part of the housing and in contact with it, on the other part of the height - the shape of a truncated cone (figure 1).

The inner surface of the annular lower block 7 has a cylindrical shape corresponding to the shape of the central rod 8, and is in contact with it. The outer surface of the annular lower 7 block has the shape of a truncated cone in contact with the upper base with the central 5 and peripheral 6 blocks, and the lower base having a wavy surface with the inner surface of the lower 4 part of the housing (Fig. 1, Fig. 4, Fig. 5) .

The central 5 and lower 7 ring blocks are made of material with increased flexibility in the axial and lateral directions, peripheral 6 ring blocks are made of material with reduced flexibility in the axial and lateral directions.

Vibration isolator works as follows. When acting in the axial direction from the side of the base plate 3 vibrational loads with high, medium frequencies and small amplitudes, these loads are perceived by the wavy surface of the annular lower block 7 in contact with the inner surface of the lower 4 of the housing. Under the action of loads, the protrusions of the wave-like surface of this block are crushed (the OA section of the axial deformation of the vibration isolator f _o of the axial load P _o , Fig.6), the volume of the deformable elastomer and the stiffness of the block in the axial direction increase (section AB, Fig.6). As a result of the elastic and damping action of the material of the annular lower block 7, the amplitude of the loads decreases and the vibrational energy is partially absorbed. Loads with reduced amplitude from the annular lower block 7 through its upper base in contact with the surfaces of the central 5 and peripheral 6 ring blocks are transferred to the material of these blocks, as a result of the elastic and damping action of which the amplitude of the loads decreases (in the extreme case, to zero) partially or completely absorbed vibrational energy. In this case, the axial stiffness of the vibration isolator changes in accordance with the section of the aircraft, Fig.6.

When acting in the axial direction from the side of the base plate 3 of vibrational loads with low frequencies and high amplitudes, these loads are also perceived by the annular lower block 7. But, due to the fact that the material of this block has increased flexibility, the amplitudes of such loads are reduced and their vibrational energy is absorbed only partially and loads with a larger amplitude than in the previous case are transmitted to the central 5 and peripheral 6 ring blocks. They cause a greater axial deformation of the material of these blocks than in the previous case, while the axial stiffness of the vibration isolator increases to a greater extent (section BD, Fig. 6). With significant loads, part of the material of the annular peripheral 6 and lower 7 blocks has the ability, as a result of elastic deformation, to move into the free volume between the upper 2 and lower 4 parts of the housing intended for this purpose (Fig. 1). As a result of the elastic and damping action of the material of all blocks, the amplitude of axial loads decreases (in the extreme case, to zero) and the vibrational energy is partially or completely absorbed. Thus, depending on the frequencies and amplitudes of the axial loads acting on the vibration isolator, its elastic and damping properties adaptively change in order to improve the vibration-isolating qualities.

If the amplitude does not decrease to zero, the part of the vibrational energy that is not absorbed by the vibration isolator is transmitted through the upper 2 part of its body to the base 1 connected to the sprung object. In extreme cases, when the amplitude of the loads is so large that, despite the elastic and damping properties of the vibration isolator, a significant part of the vibrational energy cannot be absorbed by it and transmitted to the sprung object through the base 1, its axial movement is limited by the buffer stroke limiter 10 from the elastomer, based on a restrictive metal washer 9 mounted on a central shaft 8.

When acting in lateral directions from the base plate 3 of vibrational loads with high, medium frequencies and small amplitudes, these loads are perceived by the inner surface of the annular lower block 7 and the undulating inner conical surface of the annular central block 5. Under the action of the loads, the protrusions of their undulating surfaces increase, the volume increases deformable elastomer and the rigidity of these blocks in the lateral directions (plot OA of the dependence of lateral deformation f _{b of the} vibration isolator on lateral load P _b , Fig.7). As a result of the elastic and damping action of the material of these blocks, the amplitude of the side loads decreases (in the extreme case, to zero) and the vibrational energy is partially or completely absorbed.

When acting in lateral directions from the side of the base plate 3 vibrational loads with low frequencies and high amplitudes, these loads are also perceived by the ring central 5 and lower 7 blocks. The material of these blocks has increased flexibility, and under the action of lateral loads with high strain amplitudes in the lateral direction, the material of the annular peripheral block 6 is also exposed. In this case, loads with amplitudes partially reduced during deformation of the material of the annular central 5 and lower 7 blocks from the annular central block 5 through its outer cylindrical surface are transferred in contact with it the inner cylindrical surface of the annular peripheral block 6, the material of which is It gives reduced ductility. As a result of the elastic and damping action of the material of all three blocks, the amplitude of the side loads is still reduced (in the extreme case, to zero) and the vibrational energy is partially or completely absorbed. The nature of the change in lateral stiffness of the vibration isolator depending on the change in lateral load from the beginning to the end of the deformation of the material of the annular peripheral block 6 is illustrated by section AB, Fig. 7.

Under the simultaneous action of axial and lateral loads, namely, such load conditions are most frequent in operation, according to the above-described scheme, all three units that perceive axial and lateral loads work simultaneously.

The vibration isolator scheme provides progressive adaptive axial and lateral elastic characteristics - the strain growth in these directions decreases as the load increases, which contributes to the transfer of vibrational loads with an ever-decreasing amplitude and increase of the vibration isolating qualities of the vibration isolator from block to block of the elastic element from the elastomer. Moreover, improving the quality of vibration isolation is ensured by adaptive changes in its elastic and damping properties depending on the frequencies and amplitudes of the axial and lateral loads acting on the vibration isolator.

Thus, the problem of creating a vibration isolator circuit, which improves the quality of vibration isolation when used in the suspension of a sprung object, is solved.

Claims (1)

A vibration isolator comprising a housing, an elastic element of an elastomer interacting with the object, and a base, characterized in that it comprises a central rod installed in the base plate, a restrictive metal washer and a buffer stroke limiter made of elastomer mounted on the central rod, the housing consists of the base of the upper and lower parts connected with the base plate, the base is connected to the object, and the elastic element of the elastomer consists of central, peripheral and lower ring blocks, at m the central and lower ring blocks are made of material with increased, and the peripheral ring block is reduced compliance in axial and lateral directions, the inner surface of the annular peripheral block has a cylindrical shape corresponding to the shape of the outer surface of the annular central block, in which the inner surface has the shape of a truncated cone the diameter of the lower base of which is equal to the diameter of the Central rod, and the inner side surface is made wavy, the outer surface The part of the annular peripheral block has a cylindrical shape at a part of its height corresponding to the shape of the inner surface of the upper part of the housing, at the other part of the height, it has the shape of a truncated cone, the inner surface of the annular lower block has a cylindrical shape corresponding to the shape of the central rod, the outer surface of the annular lower block has the shape a truncated cone in contact with the upper base with the central and peripheral blocks, and the lower base having a wavy surface with the inner surface of the lower part of the housing.

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