RU101514U1 - RUBBER-METAL SUPPORT - Google Patents

Abstract

 1. A rubber-metal support, characterized in that it includes supporting elements and a composite working elastic body located between them, which is made in the form of a stacked structure and consists of round metal plates, preferably adhesively bonded to each other with layers of an isotropic polymer elastomer, preferably from the group of chloroprene rubbers, while the outer surfaces of the support elements are made flat, and the inner sides are connected to the elastic body. ! 2. Rubber-metal support according to claim 1, characterized in that the support elements are made in the form of thick-walled metal or composite plates, preferably polygonal, for example, rectangular or square in plan view. ! 3. The rubber support according to claim 1, characterized in that the supporting elements on the inside are reinforced with ribs. ! 4. Rubber-metal support according to claim 1, characterized in that holes or slots are made in the supporting elements. ! 5. Rubber-metal support according to claim 1, characterized in that threaded holes are made in the support elements. ! 6. The rubber support according to claim 1, characterized in that the elastic body is inseparable and, preferably, rigidly connected to the supporting elements. ! 7. The rubber support according to claim 1, characterized in that the elastic body is cylindrical or conical, for example, in the form of a truncated cone. ! 8. The rubber support according to claim 1, characterized in that neoprene is used as an elastomer. ! 9. The rubber support according to claim 1, characterized in that rubber, preferably finely porous, is used as an elastomer. ! 10. Rubber-metal

Description

The technical solution relates to the fields of engineering and construction, preferably to earthquake-resistant supports for machines, buildings and structures.

A rubber-metal support is known from the prior art, consisting of two plates of solid material with a gasket of elastic elements working in compression, and in order to obtain specified non-linear characteristics of the stiffness of the support, there are certain gaps between the elastic elements of rubber or rubber-like material, and their fastening to hard material plates are made rigid, for example, by vulcanization. SU 167713A, F16F 15/08, 08/23/1972.

The rubber-metal support is known from the prior art, consisting of a rubber element glued and / or vulcanized to a metal external reinforcement of a conical shape and internal, in the form of a metal sleeve consisting of several cylindrical parts or a cylindrical and conical part, characterized in that the upper and / or the lower end surface of the rubber element has fins made in the form of symmetrical and / or asymmetric protrusions, the basis of which is a triangle, rectangle, trapezoid, waves or a combination thereof. RU 49172U1, F16M 7/00, 10.11.2005.

A disadvantage of the known technical solutions is the small reserve of energy absorption and, as a consequence, insufficient vibration isolation.

The task to which the technical solution is directed is to provide the support with the necessary level of vibration isolation and seismic isolation with a large reserve of energy absorption and limiting the movement of the supports in predetermined limits.

The problem is solved due to the fact that the rubber-metal support, according to the utility model, includes support elements, and a composite working elastic body located between them, which is made in the form of a stacked structure and consists of round metal plates, preferably adhesively bonded to each other by isotropic layers polymer elastomer, preferably from the group of chloroprene rubbers, while the outer surfaces of the support elements are made flat, and the inner sides are connected with an elastic elom.

The support elements can be made in the form of thick-walled metal or composite plates, preferably polygonal, for example, rectangular or square in plan view.

Supporting elements from the inside can be reinforced with ribs.

Holes or slots can be made in the support elements, preferably threaded holes are made in the support elements.

The elastic body is inseparable and, preferably, can be rigidly connected to the supporting elements.

The elastic body can be made cylindrical or conical, for example, in the form of a truncated cone.

Neoprene may be used as an elastomer. Or rubber, preferably finely porous.

The rubber mount can be further provided with a cage covering the elastic body.

The clip may be made of an elastic and / or elastomeric material.

Between the clip and the elastic body, a layer may be located to protect the elastomeric material from external influences.

The layer for protecting the elastomeric material from external influences can be made of substances chemically neutral to the layers of the elastomer, for example, non-combustible heat-resistant and non-oxidizing lubricating oils from organofluorine compounds or other fire-resistant or fire-resistant materials.

The elastic body can interact with the supporting elements through elastomeric layers or metal plates.

The thickness _e of the elastomeric layer can be less than the thickness of the metal plates.

Metal plates along the height of the elastic body can be made of various thicknesses.

The elastomeric layers may have different thicknesses and / or be made of different materials and / or have different elastic moduli.

Elastomeric layers can be made with different coefficient of elasticity, which varies along the length of the elastic body, for example, according to a linear law or have elastic nonlinearity.

In metal plates and elastomeric layers there may be holes in which at least one core is located.

The core may be made of elastic or elastic-plastic, or plastic, preferably isotropic material.

The core can be multilayer, for example, from concentric or coaxial layers spanning one another.

The elastic or elastic-plastic or plastic material may be a soft metal or alloy, for example, lead, tin, aluminum.

The core and / or cage can be made of the same material as the elastomeric layers and are seamlessly connected to them.

In at least a portion of the plates, at least one additional through hole may be provided into which one or more flexible rods are passed, each of which is rigidly fixed in at least one support element.

Preferably, the height of the elastic body does not exceed the length and width of the support element, and the ratio of the modulus of elasticity of the material of the metal plates to the modulus of elasticity of the layers of an isotropic polymer elastomer is in the range of 25,000 and higher with a relative elongation of the latter to 100%.

The technical result achieved by applying the technical solution is to significantly increase the dynamic stability and seismic resistance of machines, equipment, other elements, structures, buildings and structures, increase compactness and reduce material consumption of the selected rounded shape of metal plates and predictability of the properties and operation of the support, as part of the structures and the foundations of a building or structure and the foundation of machinery and equipment together with similar devices and other systems are regulated reduction of the dynamic response of the building or structure and / or the equipment through the use of the proposed materials and also to improve reliability and durability of the device, including by making the outer surfaces of the flat support elements, as well as compounds with the inner sides of the elastic support body.

The device is illustrated by drawings illustrating particular examples of execution, and in no way limiting other possible options within the formula of a utility model.

Figure 1 shows a rubber-metal bearing with a cylindrical elastic body (top view);

In Fig.2 a section aa in Fig.1;

Figure 3 shows a rubber-metal bearing with a conical elastic body (top view);

In Fig.4 a section bB in Fig.3;

Figure 5 shows a rubber-metal bearing with a core and a clip (top view);

In Fig.6 section bb In Fig.5;

Figure 7 shows a rubber-metal bearing with rods inside an elastic body (top view);

In Fig.8 section GG in Fig.7;

Figure 9 shows a composite elastic body in a perspective view;

Figure 10 shows a rubber mount with monolithically connected clip and core;

In Fig.11 a section DD in Fig.10.

The rubber-metal support includes support elements 1, and a composite working elastic body 2 located between them, which is made in the form of a stacked structure and consists of round metal plates 3, for example, round, adhesively bonded to each other layers 4 of an isotropic polymer elastomer, preferably from the group chloroprene rubbers, while the outer surfaces 5 of the support elements are made flat, and the inner sides are connected to the elastic body.

The supporting elements are made in the form of rectangular or square thick-walled metal or composite plates that are inseparably and rigidly connected to the elastic body through its extreme metal plates, and holes 6 are made in the plates for passing fasteners such as bolts.

The corners of the polygonal support elements can be rounded.

The elastic body can be made cylindrical (figure 1, 2) or in the form of a truncated cone (figure 3, 4), and neoprene is used as layers of the elastomer.

To eliminate large shrinkage deformations under the weight of the structures and to limit relative deformation, the thickness h _{e of the} elastomeric layers of the elastic body can be less than the thickness h _{m of} metal plates.

The rubber-metal support can be additionally provided with a cage 7 of elastic and / or elastomeric material, which covers the lateral surface of the elastic body (Fig.5, 6).

Between the clip and the elastic body, layer 8 (FIGS. 5, 6) can be located to protect the elastomeric material from external influences, prevent its aging and loss of elastic and elastic properties, as well as fire protection. Mentioned layer 8 should be made of substances chemically neutral to elastomer layers 4 such as, for example, non-combustible heat-resistant and non-oxidizing lubricating oils from organofluorine compounds.

For varying the physico-mechanical properties of the support according to the specific conditions of its uploading metallic plate 3 and / or elastomeric plate 4, the height of the elastic body H _y can made of different thickness, different materials (rubber and metal) have different modules of elasticity and so on. d. For example, the materials can be selected in such a way that the elastic modulus of the elastomeric layers will vary along the length of the elastic body according to a linear or non-linear-elastic law, increasing from top to bottom of the device.

To increase the bearing capacity and / or to better ensure the attenuation of vibrational energy in the metal plates and elastomeric layers, there may be openings 9 in which at least one core 10 is made of an elastic or elastoplastic, preferably isotropic material.

To increase the flexibility of the elastic body and increase the return force in the plates, additional through holes 11 can be made into which flexible rods 12 or several rods 12 are assembled in bundles 13, each of the rods 12 being rigidly fixed in at least one supporting element 1 (Figs. 7, 8). The rods 12 may be metal or made of plastic or composite materials.

A possible embodiment of the device is when the elastic core 10 and / or cage are made of the same material as the elastomeric layers and are seamlessly connected to them (Fig. 10, 11).

To ensure stability and work under heavy load, it is preferable that the height H of _the elastic body does not exceed the length and / or width of the support element L (Fig. 1, 2), and the ratio of the elastic modulus of the material of the metal plates to the elastic modulus of the layers of an isotropic polymer elastomer the range from 25,000 to 40,000, preferably with a relative elongation of the latter to 100%.

The proposed design works as follows:

In a static state, in the absence of seismic loading, the supports perceive the vertical load on the building without any special deformations due to optimally selected materials of the device. At the same time, the pressure set by the building is exerted on the supporting elements of the rubber-metal support and the composite working elastic body located between them, which is made in the form of a set-up design and consists of round metal plates and adhesively bonded to each other with layers of an isotropic polymer elastomer from the group of chloroprene rubbers.

During an earthquake or other seismic activity, horizontal alternating loads occur in the area of the base of the building, which are especially dangerous for the vertical structures of the building, working mainly on compression. The mentioned loads in combination with vertical ones can cause cracking or deformation, loss of stability and destruction of vertical structures near the foundation of the building, therefore, the installation of supports is most appropriate there. In the case of the installation of supports, vertical loads are absorbed by elastic bodies and the top of the vertical structure (above the support) begins to oscillate relative to the bottom of the structure (under the support) without breaking and irreversible deformation of the latter, absorbing the earthquake energy, including due to the elastic forces arising in the elastomeric layers. In this case, the support through the external surfaces of the supporting elements made flat and their internal surfaces connected to the elastic body interacts with the building structures and during the entire time the horizontal loads are exposed, the metal layers are displaced relative to each other without losing contact with the elastomeric layers, while continuing to bear vertical load, which is possible due to the unique elastic properties of elastomers and the ability to large elongations in the field of reversible deformations of their material.

The use of the described supports in buildings and structures, structures and equipment will significantly increase their dynamic stability and seismic resistance, and in machine building significantly extend the life of the equipment.

Claims (25)

1. A rubber-metal support, characterized in that it includes supporting elements and a composite working elastic body located between them, which is made in the form of a stacked structure and consists of round metal plates, preferably adhesively bonded to each other with layers of an isotropic polymer elastomer, preferably from the group of chloroprene rubbers, while the outer surfaces of the support elements are made flat, and the inner sides are connected to the elastic body. 2. Rubber-metal support according to claim 1, characterized in that the support elements are made in the form of thick-walled metal or composite plates, preferably polygonal, for example, rectangular or square in plan view. 3. The rubber support according to claim 1, characterized in that the supporting elements on the inside are reinforced with ribs. 4. Rubber-metal support according to claim 1, characterized in that holes or slots are made in the supporting elements. 5. Rubber-metal support according to claim 1, characterized in that threaded holes are made in the support elements. 6. The rubber support according to claim 1, characterized in that the elastic body is inseparable and, preferably, rigidly connected to the supporting elements. 7. The rubber support according to claim 1, characterized in that the elastic body is cylindrical or conical, for example, in the form of a truncated cone. 8. The rubber support according to claim 1, characterized in that neoprene is used as an elastomer. 9. The rubber support according to claim 1, characterized in that rubber, preferably finely porous, is used as an elastomer. 10. The rubber support according to claim 1, characterized in that it is further provided with a cage covering the elastic body. 11. The rubber support according to claim 10, characterized in that the clip is made of elastic and / or elastomeric material. 12. The rubber support according to claim 10, characterized in that between the cage and the elastic body is a layer to protect the elastomeric material from external influences. 13. The rubber-metal support according to claim 12, characterized in that the layer for protecting the elastomeric material from external influences is made of substances chemically neutral to the layers of the elastomer, for example, non-combustible heat-resistant and non-oxidizing lubricating oils from organofluorine compounds or other fire-resistant or fire-resistant materials. 14. The rubber support according to claim 1, characterized in that the elastic body interacts with the support elements through elastomeric layers or metal plates. 15. The rubber support according to claim 1, characterized in that the thickness of the elastomeric layers is less than the thickness of the metal plates. 16. The rubber support according to claim 1, characterized in that the metal plates along the height of the elastic body are made of various thicknesses. 17. The rubber support according to claim 1, characterized in that the elastomeric layers have different thicknesses and / or are made of different materials and / or have different elastic moduli. 18. The rubber support according to claim 1, characterized in that the elastomeric layers are made with different coefficient of elasticity, which varies along the length of the elastic body, for example, according to the linear law has elastic non-linearity. 19. The rubber support according to claim 1, characterized in that in the metal plates and elastomeric layers there are holes in which at least one core is located. 20. The rubber support according to claim 19, characterized in that the core is made of an elastic, elastic-plastic or plastic, preferably isotropic material. 21. The rubber support according to claim 19, characterized in that the core is multilayer, for example, from concentric or coaxial layers spanning one another. 22. The rubber support according to claim 20, characterized in that the elastic, elastic-plastic or plastic material is a soft metal or alloy, for example, lead, tin, aluminum. 23. The rubber support according to claim 20, characterized in that the core and / or ferrule are made of the same material as the elastomeric layers and are seamlessly connected to them. 24. The rubber support according to claim 1, characterized in that at least one additional through hole is made in at least a portion of the plates, into which one or more flexible rods are passed, each of which is rigidly fixed to at least at least one supporting element. 25. The rubber-metal support according to claim 1, characterized in that the height of the elastic body does not exceed the length of the support element, and the ratio of the modulus of elasticity of the material of the metal plates to the modulus of elasticity of the layers of an isotropic polymer elastomer ranges from 25,000 and higher with a relative elongation of the latter to 100% .