ES2399767A1 - Absorber for dissipating strain energy using viscoelastic material - Google Patents

Abstract

The invention relates to an absorber for dissipating strain energy using a viscoelastic material. The absorber has been designed to absorb strain energy in oscillating systems subjected to any frequency range. The invention comprises a first base (1), a second base (2) and a central body (6). The central body of the absorber comprises at least two concentric rings, namely a first ring (3) and a second ring (4), with a layer of viscoelastic material (5) disposed therebetween. In addition, a layer of viscoelastic material is disposed between the first base (1) and the ring adjacent thereto and a layer of viscoelastic material is disposed between the second base (2) and the ring adjacent thereto. The first base (1) and the second base (2) are rings that include elements for anchoring to the structure in which the absorber is positioned.

Description

Shock absorber to dissipate deformation energy using viscoelastic material

OBJECT OF THE INVENTION

The present invention aims to provide an acoustic damper in which it uses viscoelastic material as a key element in energy dissipation.

The objective of the present invention is to provide a damper that dissipates deformation energy in elements subjected to spectra of a wide range of frequencies in which noise is generated and the displacements are of the order of tenths of a millimeter.

STATE OF THE PRIOR ART OF THE INVENTION

Classic damping means such as insulating blankets do not work when it comes to dissipating deformation energy in elements that are subject to spectra of frequencies below 1000 Hz. When there are structural elements subject to these frequencies and the displacements are of the order of tenths of a millimeter, noise is generated.

US4759428 discloses a viscoelastic shock absorber that controls the vibration of a structural member that can be caused by an earthquake or wind but that produces only a small reaction force when the structural member moves slowly as a result of thermal deformation of the member itself or Another connected member. This property is achieved using a dilating liquid that exhibits relatively small resistance when the movement speed is small and produces progressively large resistance as the movement speed increases.

US2875861 describes a shock absorber that uses a fluid to dissipate deformation energy. The viscosity forces that appear in a fluid that is placed in the shock absorber are used as a thin, stable and continuous layer, between two adjacent surfaces very close to each other, that are coaxial to an axis and that are each of them rigidly coupled to a system that is parallel to said axis. The shock absorber is used to decrease the relative oscillation between the two systems.

The CN101736828 patent describes a column beam capable of damping deformation stresses to reinforce the sector of the structure in which it is used. A combination of viscoelastic material is used with which to absorb deformations and steel with which to give strength to the structure.

The use of viscoelastic materials for damping vibrations by means of damping devices that dissipate energy is already known from the state of the art.

The use of viscoelastic materials in the interface of a cylinder-piston system is also known from the state of the art.

DESCRIPTION OF THE INVENTION

The present invention aims to overcome the problems posed by the state-of-the-art dampers to absorb deformation energy from elements that are subject to spectra of any frequency range.

Thus, the damper of the invention provides a more efficient result for high energy levels where viscoelastic dampers that are known in the state of the art are not capable of dissipating all the necessary deformation energy.

Specifically, the present application has been designed for the absorption of dissipation energy of elements subjected to frequencies between 50Hz and 500Hz. In some particular embodiments of the present invention in which the viscoelastic materials used are vulcanized gums or materials, the frequencies at which energy is absorbed may be comprised between 1Hz to 50Hz.

The present invention proposes a shock absorber to absorb deformation energy in oscillating systems subjected to any frequency range.

In structural elements, high oscillation frequencies produce vibrations of very small amplitude that are shown as noise. One solution could be to stiffen the structure. This causes resonance frequencies to increase. The problem is that stiffening the structure increases the weight, and in aeronautical structures

or mobile this is not advisable. So, you should try to absorb the energy that causes the vibration.

The shock absorber object of the invention comprises a first base, a second base and a central body. The novel feature of the present invention is that the central body of the shock absorber comprises at least two concentric rings that are a first ring and a second ring, and between them a layer of viscoelastic material is arranged.

The buffer of the invention also comprises a layer of viscoelastic material between the ring that is adjacent to the first base and said first base and a layer of viscoelastic material between the ring that is adjacent to the second base and said second base.

The first base and the second base of the shock absorber have lugs, are attached to eyebolts or use any other fastening means with which they are connected to the structure in which the shock absorber is placed.

The first base and the second base are connected to any area or element of the structure that is vibrating in each specific case in which it is applied.

The first base and the second base are rings that incorporate anchoring elements to the structure in which the shock absorber is placed.

Viscoelastic materials are known to have both viscous and elastic properties depending on the temperature at which they are. These materials dissipate energy when a load is applied.

The combination of stress-strain curves of a viscoelastic material when it is loaded and when it is discharged serves to determine the amount of energy that the material is able to dissipate. The stress-strain curve of the material when it is loaded follows a certain trajectory depending on the properties of the material and the stress-strain curve of the material when it is unloaded follows a different path from the previous one. The area that is limited by these two curves reflects the ability to dissipate the energy of the viscoelastic material in question for a given temperature.

Viscoelastic materials undergo a hysteresis cycle when subjected to a charge so that there is a difference between the charge period and the discharge period in which energy dissipates in the form of heat. As viscoelastic material sheets are used in the present invention, the main effort to be considered for the state of loading is the cut, and this depends on the area of material subjected to stress. Thus, the damper of the present invention comprises several layers of viscoelastic material trying to maximize the area of each of those layers to obtain a total area of viscoelastic material much larger than that of the viscoelastic dampers of the state of the technique. In this way, much more energy is dissipated with the damper of the invention than with the prior art dampers.

In a first preferred embodiment of the invention, the body of the shock absorber is formed by rings having a truncated conical shape. In these rings the wall of the ring has the same thickness over the entire surface of the ring.

In this first preferred embodiment of the invention, the rings are arranged in the central body such that a ring "fits" in the ring that is adjacent thereto. That is, considering a first ring and a second ring, the part of the first ring that has a smaller diameter that is the part of the upper face of the ring, is introduced into the second ring through the part of larger diameter ( which matches the bottom face) of the second ring. The layer of viscoelastic material is arranged between both rings. This layer of viscoelastic material is placed between the inner face of the second ring and the outer face of the first ring.

If the body of the shock absorber is composed of more than two rings, the connection between them is carried out in the same way as explained in the previous paragraph, introducing the part of smaller diameter of a ring through the larger diameter of a ring adjacent to him.

The smaller diameter of a ring is on the upper face of the ring while the larger diameter of a ring is on its lower face.

In a second preferred embodiment of the invention, the rings are in the form of a washer with a bevelled upper face and a lower face.

In this second preferred embodiment of the invention the rings can be of two types.

A first type of ring has the upper face and the lower face beveled inwards. That is, the length of the inner face of the ring measured in the longitudinal direction is less than the length of the outer face of the ring measured in the longitudinal direction.

A second type of ring has the upper face and the lower face beveled outwards. That is, the length of the inner face of the ring measured in the longitudinal direction is greater than the length of the outer face of the ring measured in the longitudinal direction.

In this second preferred embodiment the adjacent rings are arranged such that, considering a first ring and a second ring, the first ring having its upper and lower faces beveled inwardly is placed on a second ring having its upper and lower faces beveled outwards. The layer of viscoelastic material between the rings is disposed between the lower face of a first ring and the upper face of a second ring.

In this second preferred embodiment, when the main body is composed of several rings, these are positioned so that the rings that have a bevel inwardly are adjacent with the rings that have a beveled outward.

In this second preferred embodiment of the invention, the first base has a conical shape that adapts to the inclination that the ring of the main body that is adjacent thereto has on its upper face.

In this second preferred embodiment of the invention, the second base has a conical shape that adapts to the inclination that the ring of the main body that is adjacent thereto has on its lower face.

In one embodiment of the invention, the main body rings are of a material of different stiffness than the material of the viscoelastic material layers to increase the efficiency of the shock absorber.

In one embodiment of the invention, the rings are made of metal to improve heat dissipation in the form of heat. Depending on the rigidity of the metal or metal alloy used, more or less efficient configurations can be achieved both acoustically and in terms of weight or space available playing with the thickness of the rings.

The rings can be of different materials. You can have rings of any metal alloy. Also, you can have rings of any type of composite such as carbon fiber, glass, aramid (Kevlar®), composite with thermoplastic resin, thermosetting, reinforced with carbon nanotubes, etc.

In one embodiment of the invention, the rings are made of carbon fiber to achieve a very light buffer. The shock absorber of the present invention is not a main loading step so it is not necessary to guarantee the electrical continuity between the material of the viscoelastic material layers and the carbon fiber of the rings.

In one embodiment of the invention the viscoelastic material used is vulcanized rubber. In this case, the rings are open to allow deformation of the rubber. This opening is a slot in the longitudinal direction that communicates the inside of the ring with the outside and that extends from the upper face of the ring to the lower face of the ring.

The present invention represents a significant improvement over traditional dampers that use viscoelastic material at the interface of a cylinder-piston system since when high levels of energy are reached, these dampers are not able to continue absorbing energy. However, the shock absorber proposed in the present invention is capable of continuing to dissipate energy even though high levels of energy are reached.

Another important advantage of the invention is that it is applied to existing structures by adding to said existing structures without altering the static behavior of the structure.

One of the most important applications of the shock absorber of the present application is in the aerospace sector to absorb the high levels of vibration at different frequencies that support some of the aircraft components such as the frames, stringers, stringers and beams that make up the structure of the airplane.

The shock absorber of the present invention has another application in the aerospace sector related to the one set forth above. Because the frames that make up the structure of the plane are vibrating at different frequencies, part of this vibration is shown in the form of noise. Thus, by placing the shock absorber of the present invention on elements of the airplane whose vibration produces noise, such as the frames, it is possible to reduce the noise heard by the passengers of the airplane.

Another important application of the shock absorbers of the present invention is in the automotive sector since the shock absorber of the present invention can be used in place of those known in the state of the art to improve the comfort of the users when traveling on roads in disrepair.

Also in the case of the automotive sector, part of the vibrations suffered by the structure are shown in the form of noise. Thus, the application of the damper of the invention in the automobile sector also serves to reduce the noise heard by the users of the vehicle.

BRIEF DESCRIPTION OF THE FIGURES

The following are representative figures of one of the embodiments of the invention that serve only by way of example and, thus, are not restrictive within the present invention and where:

Figure 1 represents a first embodiment of the invention in which the rings have a frustoconical shape.

A perspective view of the damper of the invention in its first preferred embodiment with frustoconical rings is shown in Figure 1a. A section of the view of Figure 1a is shown in Figure 1b, showing how the rings and the layer of viscoelastic material are placed between them. Figure 1c shows the elevation of the view 1b.

Another more schematic section of the shock absorber of the invention in its first preferred embodiment is shown in Figure 1d. Figure 1e shows the section B-B that has been made in Figure 1d and it shows two rings that are in their working position in the damper so that one of them has been introduced into the other. The rings that have been represented in this figure are those used when the viscoelastic material used is a vulcanized material so that they have a groove that allows the expansion of the viscoelastic material when it expands when it is dissipating energy.

Figure 2 shows a shock absorber ring in its first preferred embodiment in which it has a conical shape. Figure 2a shows a ring of those used when the viscoelastic material is not a vulcanized material. Figure 2b shows a ring like the one in Figure 2a but which is used in the embodiments in which vulcanized materials are used so that a groove has been made in the ring to allow dilation of the vulcanized material when it is dissipating energy.

Figure 3 represents a second embodiment of the invention in which the rings are shaped like a washer with its lower face and its upper face beveled.

A perspective view of the shock absorber of the invention in its second preferred embodiment with bevelled upper and lower face rings is shown in Figure 3a. A section of the view of Figure 3a is shown in Figure 3b, showing how the rings and the layer of viscoelastic material are placed between them. Figure 3c shows the elevation of the view 3b.

Another more schematic section of the shock absorber of the invention in its second preferred embodiment is shown in Figure 3d. Figure 3e shows the section AA that has been made in figure 3d and it shows a ring of those used when the viscoelastic material used is a vulcanized material so that it has a groove that allows the material to expand viscoelastic when it expands when it is dissipating energy.

In figure 4 the rings used in the second preferred embodiment of the invention are shown in the form of a bevel washer on their upper and lower faces.

A ring of the second preferred embodiment of the invention is shown in Figure 4a in which the upper and lower faces are beveled outwards. A ring of the second preferred embodiment of the invention is shown in Figure 4b in which the upper and lower faces are beveled inwards.

A ring of the second preferred embodiment of the invention is shown in Figure 4c in which the upper and lower faces are beveled outwards and in which there is a groove for allowing the vulcanized material to dilate when energy is dissipating. A ring of the second preferred embodiment of the invention is shown in Figure 4d in which the upper and lower faces are beveled inwardly and in which there is a groove for allowing the vulcanized material to dilate when energy is dissipating.

References:

1: first base

2: second base

3: first ring

4: second ring

5: viscoelastic material layer

6: central body

7: ring wall

8: smaller diameter

9: larger diameter

10: inner face

11: outer face

12: upper face

13: bottom face

14: first surface

15: second surface

16: slot

EMBODIMENTS OF THE INVENTION

In order to reach a better understanding of the object and functionality of this patent, and without being understood as restrictive solutions, a description of a preferred embodiment of the invention based on the figures indicated above is given below.

The present invention proposes a shock absorber to dissipate deformation energy in oscillating systems subjected to any frequency range. The buffer of the present invention comprises:

a first base (1);

a second base (2); and

a central body (6).

The novel features presented by this invention in relation to viscoelastic buffers that are known from the state of the art are:

the central body comprises at least two concentric rings that are a first ring (3) and a second ring (4), and between which a layer of viscoelastic material (5) is arranged;

there is a layer of viscoelastic material between the ring that is adjacent to the first base (1) and said first base (1); Y

there is a layer of viscoelastic material between the ring that is adjacent to the second base (2) and said second base (2).

The first base (1) and the second base (2) are rings that incorporate anchoring elements to the structure in which the shock absorber is placed.

In a first preferred embodiment of this invention, the rings that make up the central body (6) have a truncated conical shape. The wall (7) of each ring has the same thickness over the entire surface of the ring.

To explain the position of the rings in the central body of the shock absorber, it is considered a first ring

(3) and a second ring (4). The rings are arranged so that the first ring (3) is inserted into the second ring (4).

This embodiment is seen in Figures 1a, 1b, 1c and 1d.

In this first preferred embodiment of the invention, all rings have the same measurements. As the name itself indicates, the smaller diameter (8) of a ring is always smaller than the larger diameter (9) of that same ring. Thus, all the rings having the same measurements, the smallest diameter (8) of a first ring

(3) is always smaller than the larger diameter (9) of a second ring (4) adjacent to it to ensure that the first ring (3) can be introduced into this second ring (4).

The smaller diameter (8) of the cone trunk forming the ring is on the upper face (12) of said ring while the larger diameter (9) is on the lower face (13) of the ring.

A ring like the ones described here for the first preferred embodiment is shown in Figure 2a.

The inner face (10) of a ring is the one that remains on the inside of the cone trunk that forms the ring while the outer face (11) is the one that is on the outside of the cone trunk that forms the ring.

Thus, a part of smaller diameter (8) located on the upper face (12) of a first ring (3) is inserted into a second ring (4) through a part of larger diameter (9) located on the lower face (13) of said second ring (4).

The layer of viscoelastic material (5) between the rings is disposed between the inner face (10) of a second ring (4) and the outer face (11) of a first ring (3) that has been inserted inside of the second ring (4).

When the central body (6) is composed of more than two rings, the connection between them is made in the same way as explained above for a first ring (3) and a second ring (4), introducing the smaller diameter part (8) of a ring through the larger diameter (9) of a ring adjacent to it.

The first base (1) and the second base (2) are attached to the area or elements of the structure in which the shock absorber that is subjected to vibration is installed. They can be attached to the structure by eyebolts, lugs

or any other means of attachment.

In a second preferred embodiment of the invention, the rings that make up the central body (6) are in the form of a washer with an upper face (12) and a lower face (13) beveled.

In this embodiment there are two types of rings that are placed alternatively composing the central body (6) of the shock absorber.

A first type of rings has its upper face (12) and its lower face (13) beveled inwards and a second type of rings has its upper face (12) and its lower face (13) beveled outwards.

In this second preferred embodiment, when the main body is composed of several rings, these are positioned so that the rings that have a bevel inwardly are adjacent with the rings that have a beveled outward.

The inner face (10) of the ring is the one on the inside of the ring shaped like a bevel, while the outer face (11) of the ring is the one on the outside of the ring shaped like a washer. .

In this second preferred embodiment, all rings have a constant smaller diameter (8) that is the same for all rings and a larger constant diameter (9) that is the same for all rings. As the name itself indicates, the smaller diameter (8) of a ring is always smaller than the larger diameter (9) of that same ring.

Specifically, the rings are arranged so that a first ring (3) that has its upper and lower faces (12, 13) beveled inwardly is placed on a second ring (4) that has its upper and lower faces (12 , 13) beveled outwards. In this case, the layer of viscoelastic material (5) between the rings is disposed between the lower face (12) of a first ring (3) and the upper face (13) of a second ring (4).

Similarly, when the first ring (3) is the one with its upper face (12) and its lower face (13) beveled outwards, it is placed on a second ring (4) that has its upper and lower faces (12 , 13) beveled inwards. The layer of viscoelastic material (5) between the rings is arranged between the lower face

(12) of a first ring (3) and the upper face (13) of a second ring (4).

Figures 3a, 3b and 3c show the shock absorber described with the bevelled upper and lower face rings of the second preferred embodiment of the invention.

In this second preferred embodiment, the first base (1) of the damper has a first surface

(14) that is in contact with the upper face (12) of a ring adjacent thereto. This first surface (14) has a conical shape with the same inclination as the upper face (12) of the ring adjacent thereto.

In this second preferred embodiment, the second base (2) has a second surface (15) that is in contact with the lower face (13) of a ring adjacent thereto and said second surface (15) has a conical shape with the same inclination than the lower face (13) of the ring adjacent to it. This is seen in the 3d figure.

In a possible embodiment of the invention, metal rings can be used to increase the efficiency of the damper by dissipating heat.

In another possible embodiment of the invention, carbon fiber rings can be used to have a lighter shock absorber. In addition, due to the small magnitude of the displacements, it is guaranteed that the static conditions of the elements in which the shock absorber is placed are not influenced.

In another preferred embodiment of the invention, metal rings and carbon fiber rings can be combined in the same buffer to increase the energy dissipated in the form of heat and at the same time have a light buffer.

In one embodiment of the invention, the viscoelastic material used is vulcanized rubber. In this case, it is necessary that the rings be open to allow dilation of the rubber when the shock absorber is working. Thus, when rubber is used, the rings have a groove (16) in the longitudinal direction that communicates an inner face (10) of the ring with an outer face (11) of the ring and extends from the upper face (12) of the ring to the underside (13) of the ring.

A sample of these grooved rings, specially designed to be used when working with vulcanized materials, is shown in Figure 2b representing a conical shaped ring of the first embodiment of the invention and in Figures 4c and 4d representing the beveled upper and lower face rings of the second preferred embodiment of the invention.

Claims (13)

1. Shock absorber to absorb deformation energy in oscillating systems subject to any frequency range, comprising: a first base (1); a second base (2); and a central body (6); characterized by: the central body comprises at least two concentric rings that are a first ring (3) and a second ring (4), and between which a layer of viscoelastic material (5) is arranged; there is a layer of viscoelastic material between the ring that is adjacent to the first base (1) and said first base (1); Y there is a layer of viscoelastic material between the ring that is adjacent to the second base (2) and said second base (2), where the first base (1) and the second base (2) are rings that incorporate anchoring elements to the structure in which the shock absorber is placed.

2.

Shock absorber according to claim 1, characterized in that the rings are conical shaped having the wall (7) of the ring the same thickness over the entire surface of the ring.

3.

 Shock absorber according to claim 2, characterized in that the rings are arranged so that a part of smaller diameter (8) located on the upper face (12) of a first ring (3) is inserted into a second ring (4) ) through a larger diameter part (9) located on the lower face (13) of said second ring (4) and the layer of viscoelastic material (5) between the rings is disposed between the inner face (10) of a second ring (4) and the outer face (11) of a first ring (3) that has been introduced inside the second ring (4).

Four.

 Shock absorber according to claim 1, characterized in that the rings are shaped like a washer with an upper face (12) and a lower face (13) beveled.

5.

 Buffer according to claim 4, characterized in that the rings are arranged such that a first ring (3) having its upper and lower faces (12, 13) beveled inwardly is placed on a second ring

(4) having its upper and lower faces (12, 13) beveled outwards and the layer of viscoelastic material (5) between the rings is disposed between the lower face (12) of a first ring (3) and the upper face (13) of a second ring (4). 6. Shock absorber according to claim 4, characterized in that the rings are arranged such that a first ring (3) having its upper and lower faces (12, 13) beveled outwardly is placed on a second ring (4) having its upper and lower faces (12, 13) beveled inwardly and the layer of viscoelastic material (5) between the rings is disposed between the lower face (12) of a first ring (3) and the upper face (13) of a second ring (4).

7.

 Shock absorber according to claim 4, characterized in that the first base (1) has a first surface (14) that is in contact with the upper face (12) of a ring adjacent thereto and said first surface (14) has a conical shape with the same inclination as the upper face (12) of the ring adjacent to it.

8.

 Shock absorber according to claim 4, characterized in that the second base (2) has a second surface

(15) which is in contact with the lower face (13) of a ring adjacent to it and said second surface (15) has a conical shape with the same inclination as the lower face (13) of the ring adjacent to it.

9.

 Shock absorber according to claim 1, characterized in that the rings are made of composite.

10.

 Shock absorber according to claim 1, characterized in that the rings are made of metal or a metal alloy.

eleven.

 Shock absorber according to claim 1, characterized in that the viscoelastic material used is a vulcanized material.

12.

 Damper according to claim 11, characterized in that the rings have a groove (16) in the longitudinal direction that communicates an inner face (10) of the ring with an outer face (11) of the ring and extends from the upper face (12) from the ring to the underside (13) of the ring.

SPANISH OFFICE OF THE PATENTS AND BRAND Application no .: 201031952 SPAIN Date of submission of the application: 12.27.2010 Priority Date: REPORT ON THE STATE OF THE TECHNIQUE 51 Int. Cl.: F16F1 / 41 (2006.01) B64C1 / 40 (2006.01) RELEVANT DOCUMENTS

Category

56 Documents cited Claims Affected

X

GB 2204935 A (ODOBASIC STEVEN) 23.11.1988, page 6, line 1 - page 12, line 14; page 19, line 21 - page 22, line 7; Figures 1A-1E, 2A, 2B, 7. 1-3,9-12

X

GB 432304 A (DUNLOP RUBBER CO et al.) 24.07.1935, the whole document. 1-3,9-11

TO

US 3416783 A (CARLO TONDATO) 17.12.1968, the whole document. 1.4

Category of the documents cited X: of particular relevance Y: of particular relevance combined with other / s of the same category A: reflects the state of the art O: refers to unwritten disclosure P: published between the priority date and the date of priority submission of the application E: previous document, but published after the date of submission of the application

This report has been prepared • for all claims • for claims no:

Date of realization of the report 19.03.2013

Examiner D. Hermida Cibeira Page 1/4

REPORT OF THE STATE OF THE TECHNIQUE Application number: 201031952 Minimum documentation sought (classification system followed by classification symbols) F16F, B64C Electronic databases consulted during the search (name of the database and, if possible, terms of search used) INVENES, EPODOC State of the Art Report Page 2/4  WRITTEN OPINION Application number: 201031952 Date of Completion of Written Opinion: 03.19.2013 Statement

Novelty (Art. 6.1 LP 11/1986)

Claims 1-12 Claims IF NOT

Inventive activity (Art. 8.1 LP11 / 1986)

Claims Claims 4-8 1-3,9-12 IF NOT

The application is considered to comply with the industrial application requirement. This requirement was evaluated during the formal and technical examination phase of the application (Article 31.2 Law 11/1986).  Opinion Base.- This opinion has been made on the basis of the patent application as published. State of the Art Report Page 3/4  WRITTEN OPINION Application number: 201031952  1. Documents considered.- The documents belonging to the state of the art taken into consideration for the realization of this opinion are listed below.

Document

Publication or Identification Number publication date

D01

GB 2204935 A (ODOBASIC STEVEN) 11/23/1988

 2. Statement motivated according to articles 29.6 and 29.7 of the Regulations for the execution of Law 11/1986, of March 20, on Patents on novelty and inventive activity; quotes and explanations in support of this statement The present invention relates to a shock absorber for dissipating deformation energy using viscoelastic material. Document D01 is considered to be the closest in the state of the art to the object of claim 1. In said document, to which the following alphanumeric references belong, is disclosed (page 19, line 21-page 22, line 7; Figure 7) a shock absorber comprising a first base (710), a second base (710) and a central body (70, 73). Said central body (70, 73) comprises at least two concentric rings (71) between which a layer of viscoelastic material (72) is arranged. There is also a layer of viscoelastic material (72) between the bases (710) and the end rings (71). The bases (710) comprise plates (711) that have anchoring elements (721, 722, 723) to the structure. It is noted that, in the invention of document D01, the bases (710) are not really rings (71) that incorporate anchoring elements. Due to this difference with the object of claim 1, claim 1 and its dependent claims 2-12 are considered to be new (Art. 6, LP 11/1986). With regard to the inventive activity of claim 1, it is considered that it would be obvious to a person skilled in the art that starts from document D01 to replace said bases (710) with rings (71) that incorporate, among others, the anchoring elements (721, 722, 723) as a design alternative. Thus, for example, the load transmission rings (717) that have precisely truncated conical surfaces (718) adapted to contact with the layers of extreme viscoelastic material (72) could be dispensed with. According to what has just been stated, it is estimated that claim 1 does not imply inventive activity (Art. 8, LP 11/1986). On the other hand, it is also estimated that claims 2, 3, 9-12 do not imply inventive activity (Art. 8, LP 11/1986), since their objects are also disclosed in document D01. Indeed: the rings (71) have a truncated conical shape and a constant thickness, being introduced into each other to form a stack; the rings (71) can be made of composite or metallic (page 8, line 9 - page 9, line 5); The viscoelastic material used is an elastomer, for example, silicone (page 11, line 25-page 12, line 4), silicone vulcanization being common; the rings (11) have grooves (12) (page 6, lines 1-12; figure 1C). As for the inventive activity of claim 4, no prior art document has been found that disseminate the technical characteristics of its object and, therefore, it is estimated that claim 4 and its claims Dependents 5-8 do involve inventive activity (Art. 8, LP 11/1986). State of the Art Report Page 4/4