SE542814C2 - Damping device to reduce the propagation of vibrations, sounds or noise and method of mounting using the damping device - Google Patents

Abstract

The present invention describes a damping device (10) for reducing vibrations, sounds or noise, comprising: a first structure, a second structure and an elastic fastener which attaches the first structure to the second structure.

Description

TECHNICAL FIELD The present invention relates to an attenuation device for reducing vibrations, noise. In particular, the damping device is suitable for reducing vibrations, sounds or noise which propagate from a room in a building or dwelling to an adjoining room.

BACKGROUND Unwanted noise or noise that spreads from one room in a building to another can have a negative impact on human health. Common measures for sound insulation include increasing the thickness of the separating wall or floor / ceiling, adding additional sound-absorbing materials and increasing the number of constituent layers in the separating wall or floor / ceiling. Additional measures include the use of highly specialized cushioning materials that are built into or applied to a separating wall or floor / ceiling. However, these solutions are associated with high costs.

A mechanism by which sound or noise propagates through a wall or floor / ceiling involves mechanical connection between rigid parts therein. Such a mechanical connection depends to a large extent on the use of conventional stationary fastening elements, such as for instance monolithic metal screws or nails.

Elastic fasteners, such as for example the elastic fastener arrangement according to WO 2008/115119 A1, are generally preferred over conventional stationary fasteners for mounting separate parts in a wall or a ceiling / floor, in order to achieve reduced transmission of sound or noise thereby. An elastic fastening element generally comprises a spring means for elastically keeping the various constructions at a distance from each other, and thereby as far as possible preventing mechanical contact between the constructions. Improper mounting of such elastic fasteners with the separate parts and / or in combination with other functions of these separate parts can, however, lead to unchanged or even increased transmission of sound or noise, which is highly undesirable. Improper mounting can, for example, give a wall or floor / ceiling with internal resonance, which is less damping than the corresponding wall or floor / ceiling where conventional stationary fasteners have been used.

Therefore, it would be advantageous to have an improved damping device, for example a damping wall or a damping floor / ceiling, to reduce vibrations, noise or noise.

SUMMARY It is an object of the present invention, taking into account the disadvantages mentioned above, to provide an improved damping device which effectively reduces vibrations, noise or noise between two structures.

In one aspect, a damping device is provided to reduce the propagation of vibration, sound or noise between at least two structures. The damping device comprises a first structure, such as a ceiling structure. The damping device further comprises at least one control structure. Furthermore, the damping device comprises at least one elastic fastening element for elastically fastening the first structure at a first perpendicular distance from said at least one rule structure so that the first structure and said at least one rule structure are in contact with each other only via said elastic fastening elements. The at least one elastic fastening element comprises a first part provided with an outer thread for rigid connection to the first structure. The at least one elastic fastening element further comprises an intermediate elastic part which connects the first part to a second part which is provided with additional outer thread for rigid connection with the control structure, the dimensions of the further outer thread being smaller than the outer thread of the first part and the intermediate elastic part holding separate the first and second parts from each other in a state of relaxation or rest. The first part is provided with a first complementary unit and the second part is provided with a second complementary unit. The first complementary unit is configured to receive the second complementary unit in a compressed state of the elastic fastener so that when the complementary units are interconnected, any relative rotation between the first part and the second part is prevented. The first part and the second part can be screwed into the first structure and the rule structure, respectively. The at least one rule structure is connected to a second structure, which is arranged on the opposite side of the rule structure in relation to the first structure, the second structure being placed at a second perpendicular distance from the first structure. The first perpendicular distance and a surface area of the at least one rule structure facing the first structure form a first volume. The second perpendicular distance and a surface area of the second structure facing the first structure form a total volume between the first structure and the second structure, the total volume decreasing with the first volume and a volume of the control structure forming a second volume. The second volume is larger than the first volume. The second perpendicular distance is greater than the first perpendicular distance.

The at least one elastic fastening element is fastened to said at least one rule structure straight through the first structure, and wherein the second part of the elastic fastening element is rigidly fastened on the opposite side of the rule structure relative to the first structure.

Furthermore, a method for mounting the damping device according to the aspect above is provided. The method of mounting is performed by simultaneously attaching a first part of the elastic fastening element to the first structure and a second part of the elastic fastening element to the control structure, the elastic fastening element being arranged straight through the first structure, so that the first structure can be mounted against the rule structure from one direction.

It is another object of the present invention to provide a damping device which can be manufactured at low cost as compared with current methods of effecting reduction of vibration, sound or noise.

It is yet another object of the present invention to provide a damping device, for example a wall or a floor / ceiling, which is thinner than a damping wall or floor / ceiling according to the prior art, and which also enables the same or improved sound insulation capacity.

These and other objects will be apparent from the description which follows. Further features of the invention and its embodiments are presented in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS These and other aspects, features and advantages to which the invention is capable will become apparent and illustrated from the description which follows from non-limiting embodiments of the present invention, taken in conjunction with the accompanying drawings, in which: Fig. 1 illustrates a damping device; according to an embodiment, Fig. 2 illustrates a damping device according to a further embodiment comprising a flexible material structure arranged in a volume therein, Fig. 3 illustrates a damping device provided with an alternative flexible material structure in a volume therein, Fig. 4 illustrates a damping device according to a further embodiment, where two ceiling or inner wall structures are connected on each side of a control structure by means of an elastic fastening element, Fig. 5a illustrates a damping device according to an embodiment where two ceiling or inner wall structures are connected on each side of a r hedge structure fixed to a foundation structure 104, Fig. 5b illustrates a damping device according to an embodiment where two ceiling or inner wall structures are interconnected on each side of a rule structure, without any foundation structure 104 between the two rule structures 102, Fig. 6a illustrates a damping device according to an embodiment similar to that of Fig. 1, provided with a further first structure glued to the first structure, Fig. 6b illustrates a damping device according to an embodiment similar to that of Fig. 1 and provided with a further first structure which is rigidly screwed to the first structure by means of conventional screws 701, Fig. 7 illustrates a damping device according to an embodiment similar to that in Fig. 1, provided with a further first structure where the elastic fastening element is arranged straight through the two inner wall or ceiling structures, Fig. 8a illustrates a damping device according to an embodiment where e n first structure 101 is connected to a rule structure 102 to a second structure 104, by means of an elastic fastening element 103, the elastic part of the elastic fastening element being placed between the rule structure 102 and the second structure 104. A further ceiling or inner wall structure 601 is rigidly mounted to the first structure 101 by means of non-elastic conventional fastening screws.

Fig. 8b illustrates a damping device according to an embodiment in which the two inner wall or ceiling structures are connected by means of generally known fastening elements, such as screws, and one of the inner wall or ceiling structures is connected by means of elastic fastening elements to the control structure, the intermediate elastic part Fig. 302 of the elastic fastener 103 is located between the rule structure 102 and a foundation structure 104, and Fig. 9 illustrates a damping device according to an embodiment provided with two ceiling or two inner wall structures with an elastic fastener arranged straight through the inner wall or ceiling structures and anchored against the rule construction.

DETAILED DESCRIPTION OF THE EMBODIMENTS Embodiments of the present invention will be described in more detail below with reference to the accompanying drawings, so that those skilled in the art will be able to implement the invention. However, the invention can be implemented in many different forms and should not be construed as limited to the embodiments presented in this presentation. Instead, these embodiments are provided to make this disclosure thorough and complete, and they will fully convey the scope of the invention to those skilled in the art.

The invention is limited only by the appended claims. Furthermore, the terminology used in the detailed description of the specific embodiments illustrated in the accompanying drawings is not intended to be limiting of the invention.

An idea of the invention is to provide a noise-reducing device for walls or ceilings, said at least two wall sections being elastically fastened to each other, in such a way that a first volume is created between the two wall sections near the position of the elastic fastening, and a second volume which is greater than the first volume created further away from the position of the elastic attachment. The first and second volumes act as mufflers, allowing noise reduction.

A further idea is to enable a solution for improved noise reduction of existing walls or ceilings.

In an embodiment according to Fig. 1, a damping device 10 is provided to reduce the propagation of vibrations, sound or noise between at least two structures. The damping device comprises a first structure 101, such as a ceiling structure. Furthermore, the damping device comprises at least one control structure 102 with which the first structure is to be connected. At least one elastic fastener 103 is included to resiliently secure the first structure 101 to the rule structure 102. When said at least one elastic fastener 103 is attached to the first structure and said at least one rule structure, it creates a space between the first structure and the at least one a rule structure, so that the first structure 101 and the at least one rule structure 102 are in contact with each other only via said elastic fastening element 103. A first perpendicular distance L1 from the first structure to the rule structure defines the space between the two. The at least one rule structure 102 is connected to a second structure 104 which is arranged on the opposite side of the rule structure in relation to the first structure 101. The second structure may be, for example, a wall foundation, or further inner wall or ceiling. The dimensions of the rule structure and the location of the second structure 104 in relation to the rule structure result in the second structure being at a second perpendicular distance L2 from the first structure 101.

The first perpendicular distance L1 and a surface area of the at least one control structure 102 facing the first structure 101 form a first volume VI. Although Fig. 1 is a two-dimensional cross-sectional view of the first volume, the designation VI has been used for increased understanding. In Fig. 1 it actually refers to a surface due to the two-dimensional drawing, but it should be noted that the volume in reality extends in the depth of the damping device. In addition, the second perpendicular distance L2 and a surface area of the second structure 104, 101 facing the first structure 101 form a total volume between the first and the second structure. The total volume decreased by the first volume V1 and a volume of the rule structure Vs forms a second volume V2. Therefore, the total volume between the first structure and the second structure consists of the first volume, the second volume and the volume of the rule structure. The present inventors have realized that when the second volume is greater than the first volume, the first perpendicular distance or the first volume is greater than zero, and when the second perpendicular distance L2 is greater than the first perpendicular distance L1, there is an improved noise reduction between the first 101 and the second structure 104 noticeable. Therefore, it is advantageous to arrange the device in such a way that the second volume is larger than the first volume.

Consequently, by allowing the second perpendicular distance L2 to be larger than the first perpendicular distance L1, a further improved sound-absorbing effect is obtained.

With Fig. 1 in mind, sound waves propagating from the left side of the first structure 101 are absorbed by the first structure 101, as well as by the elastic fastener 103, the first structure 101 will begin to oscillate relative to the second structure 104. In addition also ambient atmospheric gas between the first structure and the second structure in use will act as a damper for the relative oscillation of the first and the second structure, thereby reducing the sound transmission between the first 101 and the second structure 104. In addition, since the first structure 101 and the second structure 104 is in direct contact with each other only via the elastic fasteners 103, the mechanical sound transmission between the first structure and the second structure is kept to a minimum.

The first structure 101 may be a gypsum board, a board of the type Medium Density Fibreboard (MDF), High Density Fibreboard (HDF), plywood, chipboard, Oriented Strand Board (OSB) or be of another board of material suitable for ceilings or wall.

By keeping the entire wall or ceiling construction as thin as possible, the room surface or room volume becomes as large as possible, which is highly desirable. However, in order to obtain an improved sound-absorbing effect, additional gypsum boards are currently usually added to the inner wall surface, which gives an additional average sound-absorbing effect of approximately 5 dB. However, it is not only the case that more material is needed, but also the room surface or the room volume suffers from the arrangement with additional gypsum boards.

The present damping device enables a thin sound-absorbing wall construction.

Experiments performed by the present inventors have shown that the attenuation device according to the embodiment shown in Fig. 1 can reduce the sound by 8 dB in comparison with conventional wall (s) or ceiling, where the first structure is rigidly connected to the rule structure in such a way that L1 is zero. The sound attenuation of 8 dB could be observed in the noise frequency range 50 Hz to 5,000 Hz.

Given that an addition of an additional first structure generally attenuates the sound by 5 dB, the present invention attenuates the sound better with only a single first structure elastically attached to a rule structure, than a conventional solution where two first structures are rigidly attached to the rule structure. Thus, it is not merely the solution of the present invention that attenuates sound to a greater extent; it also saves space while significantly reducing costs compared to conventional solutions.

For a typical wall construction, the rule structure is usually attached to the floor foundation and ceiling (not shown in the drawings). But in some cases, for example where the second structure 104 constitutes an existing concrete wall, the rule structure could also be attached to the second structure.

For a typical ceiling construction, the rule structure usually forms the floor rule foundation for the next level in the property. However, within the scope of the present invention, it is possible to attach an additional rule structure to an existing floor rule foundation structure by means of flexible elastic elements to elastically attach the additional rule structure to the existing rule structure when mounting a ceiling damping device according to certain embodiments.

. The elastic fastening element is configured to fasten the first structure to the rule structure in a unidirectional manner, for example by screwing it through the first structure to the rule structure. Such an elastic fastening element mainly comprises three parts. A first part 301 is provided with a surface thread for rigid connection with the first structure 101. An intermediate elastic part 302 of the elastic fastening element connects the first part with a second part 303, which is provided with additional surface thread for rigid connection with the control structure. The dimension of the additional outer thread is preferably smaller than the outer thread of the first part 301, whereby the elastic fastening element can be inserted through a hole in the first structure 101. Due to the smaller dimension of the outer thread of the second part, the second part can be inserted through the hole of the first structure. without colliding with the first structure during assembly. The intermediate elastic member 302 holds the first and second members apart in a state of relaxation or rest. Therefore, the intermediate elastic member 302 returns to its rest or relaxation state when it is not affected by any external longitudinal force or sound pressure wave. The first part 301 is provided with a first complementary unit (not shown in Fig. 1), such as a projection or a recess, which has been configured to receive a second complementary unit belonging to the second part in a compressed state, where the first 301 and the other 303 part are compressed. When the two complementary units are interconnected, any relative rotation between the first part and the second part is prevented, whereby the parts 301, 303 can simultaneously be screwed into the first structure and the control structure 102. The first part and the intermediate elastic element can have a hollow inner shape, whereby a mounting tool mating with the second part 303 can be inserted to screw the second part 303 into the second structure 104 independently of the first part 301. The first part 301 may be configured with an outer recess to fit together with a screwdriver, so that independent attachment of the first part 301 to the first structure 101 is thereby enabled. Thereby, such an elastic fastener 103 allows relative rotation between the first 301 and the second 303 part in the relaxed state by using a mounting tool, or non-relative rotation between the first 301 and the second 303 part in a compressed state when the first part 301 and the second part 303 fits together.

The mounting tool may be configured with a first member which may be coupled to the first portion 301 of the elastic fastener 103 and a second member which may be coupled to the second portion 303 of the elastic fastener 103, wherein, when the coupled mounting tool is rotated, it the first part 301 is screwed into the first structure 101 and the second part 303 is screwed into the control structure 102.

The elastic fastening element may also have an elongated state, in which the first 301 and the second 303 part are placed at a maximum longitudinal distance from each other. Accordingly, the second perpendicular distance L2 between the first structure 101 and the second structure 104, 101 is larger in the extended state than in the compressed state. The elastic fastener 103 is in a state between the extended state and the compressed state when the intermediate elastic member 302 is in its resting state.

To achieve a preferred sound attenuation, the first perpendicular distance L1 should always be greater than zero for each state of the elastic fastener. Therefore, preferably the first perpendicular distance L1 between the surface of the first structure facing the rule structure and the surface of the rule structure facing the first structure is always greater than zero to ensure that the only mechanical sound barrier between the first and the second the surface is through the elastic fastener.

The inventors of the present invention have found that an improved sound attenuation is achieved when the second perpendicular distance L2 is greater than L1, and L1 is greater than zero. This means that even if elastic fasteners are used, in the event that the first perpendicular distance L1 is equal to the second perpendicular distance L2, the sound attenuation according to tests performed becomes relatively poor compared to if L2 is larger than L1.

The second perpendicular distance L2 is consequently larger for the embodiments of the invention consequently than the first perpendicular distance L1.

Therefore, each embodiment could be further significantly improved, in the manner presented in the embodiments of the present invention.

In one embodiment, according to Figs. 2 and 3, the second volume is at least partially filled with a flexible material structure 201. The flexible material structure 201 may be an insulating material, for example rock wool as shown in Fig. 3, insulating balls, for example insulating plastic balls as shown in Fig. 2, glass wool, polystyrene balls or any other insulating material. The flexible material structure 201 may also have sound-absorbing properties, such as a sound-absorbing material. Many insulating materials have sound-absorbing properties, with these types of materials being preferred.

The flexible material structure is preferably porous, which enables the containment of a volume of atmospheric gas.

It should be noted that the second volume V2 can be incorporated at least in part as an atmospheric gas inside the flexible material structure, and as an atmospheric gas which is partly outside the flexible material structure, in cases where the flexible material structure only partially fills the space between the first structure and the second structure, as in Fig. 9. In Fig. 2, for example, the space between the spherical insulating balls containing an atmospheric gas may be included in V2.

According to certain embodiments, the second volume created between the second and the first structure may advantageously be at least partially unblocked by the flexible material structure, so that at least one unblocked passage is thereby provided between the second structure and the first structure. This improves the movement of the atmospheric gas inside the second volume, which can enable improved sound attenuation. In Fig. 2, where the flexible material structure contains a number of insulating plastic balls, there is, for example, an unblocked passage between each ball inside the structure due to the spherical symmetry of the insulating balls.

The flexibility of the flexible material structure should be adapted to enable the absorption of sound pressure waves. Consequently, the flexible material structure does not relate to a completely rigid structure, such as a gypsum board, MDF board or the like, through which the sound waves easily propagate mechanically, as this adversely affects the sound attenuation ability. A rigid material would also create additional direct mechanical contact points between the first structure and the second structure. Instead, a flexible and malleable material is preferred. In other words, it is preferable that the acoustic impedance of the flexible material structure is lower than that of both the first structure and the second structure. Since characteristic acoustic impedance Zo can be described by the formula Z0 =? * c, there? denotes the density of a medium and c is the longitudinal wave velocity or speed of sound, it follows that a low density medium generally has a lower acoustic impedance than a high density medium because the speed of sound is generally higher in a high density medium. Therefore, the flexible material structure preferably has a lower density than the first structure 101 and the second structure 104, 101.

Fig. 4 illustrates a damping device 10 according to a further embodiment, where the second structure 104 is also elastically attached to the control structure 102 by means of a number of elastic fastening elements 103. In this embodiment the second structure can be identical to the first structure, and thereby a ceiling or a wall. Therefore, a difference from Fig. 1 is that the second structure is also elastically attached to the rule structure. In addition to the first and second volumes, as mentioned in connection with Fig. 1 above, a further third volume V3 is created in this embodiment, since a third perpendicular distance F3 and a surface area of said at least one control structure 102 facing the second structure 104 forms a third volume V3. In reality, the third volume V3 and the first volume VI may be approximately equal. The total volume between the first structure and the second structure is formed by the second perpendicular distance F2 and a surface area of the second structure 104 facing the first structure 101. The total volume decreased by the first volume V1, the third volume V3 and a volume of the rule structure Vs forms the second volume in this embodiment. In the event that the second structure is not directly attached to the rule structure, this additional volume can therefore be taken into account when defining the second volume. This embodiment is advantageous for walls when sound insulation is desired from both sides of the wall, for example in open office environments and partitions in apartments.

Fig. 5a illustrates a damping device according to an embodiment similar to that of Fig. 1, where a further control structure 102 and a further first structure 101 are arranged on the opposite side of the damping device in Fig. 1. The further first structure is arranged on a third perpendicular distance F3 from the further rule structure, and at a fourth perpendicular distance F4 from a surface of the second structure 104 facing the further first structure 101. Here, both the second perpendicular distance L2 and the fourth perpendicular distance L4 are preferably larger than the first perpendicular distance L1 and the third perpendicular distance, respectively. The fourth perpendicular distance L4 and a surface area of the further first structure 101 facing the second structure 104 form a further total volume between the further first structure and the second structure. The total volume decreased by the third volume and a volume of the rule structure Vs forms a fourth volume V4. The additional first structure may be referred to as the third structure for the sake of clarity in the appended claims.

In one embodiment, it is also preferable that the second volume V2 is larger than the first volume V1, and the fourth volume V4 is, if applicable, larger than the third volume V3.

Fig. 5b illustrates a damping device according to an embodiment where two ceiling or inner wall structures are interconnected on each side of a rule structure, without any foundation structure 104 between the two rule structures 102. Therefore, in this case it is preferred that L2 is larger than L1 and L3, respectively. and that each of L1 and L3 is greater than zero, in order to obtain the desired sound-absorbing properties.

In one embodiment, the first L1 or third L3 is the perpendicular distance in the range 0.01 to 20 mm, for example 1 to 10, such as 1 to 5 mm, such as 3 mm.

In one embodiment, the second L2 or fourth L4 is the perpendicular distance in the range of 25 to 500 mm, for example 50 to 300, such as 50 to 200 mm.

Fig. 6a illustrates an embodiment where a further first structure or sheet of material 601 has been mounted on top of the first structure 101. The further sheet of material may be, for example, a further plasterboard, MDF, HDF or optionally glued to the first structure 101.

Experiments have shown that the addition of an additional sheet of material 601, such as a plasterboard, can improve the sound-absorbing ability of the wall or ceiling by 5 dB. On the other hand, this will increase the thickness of the wall structure.

Fig. 6b illustrates a damping device according to an embodiment similar to that of Fig. 6a where the further first structure is rigidly screwed to the first structure by means of conventional screws 701.

According to an embodiment, shown in Fig. 7, said at least one elastic fastening element is fastened to said at least one control structure straight through the first structure and the further first structure. Therefore, this embodiment requires a slightly longer elastic fastening element than is required, for example, in Fig. 6a.

The second structure 104, 101 may be rigidly attached to the rule structure which acts as a foundation for a wall, a roof or a floor in a building or a dwelling, while the first structure 101 is elastically suspended in relation to the second structure 104 via the elastic fastener 103.

A favorable effect of the present invention is that it is possible to mount the damping device in a unidirectional manner, since the elastic fastening elements can be screwed into the structures in substantially the same way as usually takes place when mounting gypsum boards. The only difference is that a custom mounting tool may be required, if the elastic fastener is not customized to a specific standard. Therefore, the present invention enables a method of mounting the damping device as proposed with the included embodiments.

Such a method may comprise a method of mounting a first structure 101 to a control structure 102 by means of at least one elastic fastening element 103. The method comprises the steps of simultaneously fastening a first part 301 of the elastic fastening element 103 to the first structure 101 and a second part 303 of the elastic fastening element 103 against the rule structure 102. The elastic fastening element 102 is arranged straight through the first structure 101, so that the first structure 101 can be mounted against the rule structure 102 from one direction.

The step of simultaneous attachment can be performed by means of a mounting tool which can be connected to the elastic fastening element 103 via a through-hole arranged therein. The mounting tool has a first element which can be connected to the first part 301 of the elastic fastening element 103 and a second element which can be connected to the second part 303 of the elastic fastening element 103, wherein, when the coupled mounting tool is rotated, the first part 301 is screwed into the first structure 101 and the second part 303 is screwed into the control structure 102.

As shown in Fig. 1, the first structure is elastically attached to the rule structure 102, while the second structure may be rigidly attached to the opposite side of the rule structure relative to the first structure.

As an alternative, it is also possible to elastically fasten the second structure to the rule structure, and possibly rigidly fasten the first structure to the rule structure opposite the second structure. Two such embodiments are shown with reference to Figs. 7 and 8a. Here, said at least one elastic fastening element 103 is configured to elastically fasten said at least one control structure 102 at a first perpendicular distance from the second structure 104, 101 so that the second structure 104, 101 and said at least one control structure 102 are in contact with each other only. via said elastic fastener 103. The second structure 104, 101 is located at a second perpendicular distance from the first structure 101. The first distance and a surface area of said at least one control structure 102 facing the second structure 104, 101 form a first volume , and the second distance and a surface area of the first structure 101 facing the second structure 104, 101 minus the first volume form a second volume, the second volume being larger than the first volume. In the embodiment according to Fig. 8a, the elastic fastening element can be arranged between the control structure 102 and the second structure 104, wherein the first structure and possibly the further first structure 601 can be rigidly fastened to the control structure by means of conventional screws 701. It should be noted that the conventional screws 701 that fix the additional first structure to the first structure may also be attached to the rule structure (see the lower rule structure). On the other hand, in the embodiment according to Fig. 8b, the elastic fastening element can be arranged straight through the first structure and the rule structure, and then rigidly fastened to the second structure. This may require a longer first portion 301 of the elastic fastener.

For example, the damping device according to Fig. 8a may optionally be used as a ceiling damping device for sound insulation of an existing ceiling, the second structure being the floor foundation, such as an existing rule structure in a property, while the rule structure 102 is a further rule structure, elastically attached to the existing rule structure 104, with using the elastic fasteners.

Fig. 9 illustrates a damping device according to an embodiment provided with two ceiling or two inner wall structures with an elastic fastening element arranged straight through the inner wall or ceiling structures and anchored to the rule construction. Although the invention has been described in connection with separate embodiments, combinations of the described embodiments should also be considered to be within the scope of the invention.

It should be noted that each of the embodiments described herein is suitable for both ceiling and interior wall use.

The scope of the invention is defined by the appended claims.

Claims (16)

A damping device (10) for reducing the propagation of vibrations, sounds or noise between at least two structures, comprising a first structure (101), such as a ceiling structure, at least one control structure (102), at least one elastic fastening element (103) for elastically securing the first structure (101) at a first perpendicular distance (L1) from said at least one control structure (102) so that the first structure (101) and said at least one control structure (102) are in contact with each other only via said elastic fastening element (103), said at least one elastic fastening element comprising: a first part (301) provided with an outer thread for rigid connection to the first structure (101), an intermediate elastic part (302) which connects the first part to a second part (303) which is provided with an additional outer thread for rigid interconnection with the control structure (102), the dimensions of the additional outer thread being smaller than the outer thread of the first part (301), and the intermediate lying elastic part (302) keeps the first and the second part apart in a state of relaxation or rest, the first part (301) being provided with a first complementary unit and the second part (303) being provided with a second complementary unit, the first complementary unit being configured to receive the second complementary unit in a compressed state of the elastic fastener (103) so that when the complementary units are interconnected, any relative rotation between the first part (301) and the second part is prevented. the part (303), wherein the first part (301) and the second part (303) can be screwed into the first structure (101) and into the control structure (102), respectively, the at least one control structure (102) being interconnected with a second structure (104) disposed on the opposite side of said at least one rule structure (102) relative to the first structure (101), the second structure (104) being located on a a second perpendicular distance (L2) from the first structure (101), the first perpendicular distance (L1) and a surface area of said at least one control structure (102) facing the first structure (101) forming a first volume (V1) , the second perpendicular distance (L2) and a surface area of the second structure (104) facing the first structure (101) forming a total volume between the first structure (101) and the second structure (104), the total volume reduced by the first volume (V1) and a volume of the rule structure (Vs) form a second volume (V2), the second volume (V2) being larger than the first volume (V1), and the second perpendicular distance (L2) being larger than the first perpendicular distance (L1), said at least one elastic fastening element being fastened to said at least one control structure (102) straight through the first structure (101), and wherein the second part (303) of the elastic fastening element (103) is rigidly attached to the opposite side of the rule structure (102) relative to the first structure (101). A damping device according to claim 1, wherein the first perpendicular distance (L1) is greater than zero. A damping device (10) according to any one of the preceding claims, wherein the second volume is at least partially filled with flexible material structure (201). A cushioning device (10) according to claim 3, wherein the flexible material structure (201) is an insulating material. A damping device (10) according to claim 3, wherein the flexible material structure (201) is a sound-absorbing material. A damping device (10) according to claim 3, wherein there is at least one unobstructed passage between the second structure and the first structure. The damping device (10) of claim 1, wherein the first structure (101) has a first geometric cross-sectional shape, and the second structure has a second geometric cross-sectional shape, the second volume being created by the space between the first structure (101), the second the structure (104) and the rule structure (102). A damping device (10) according to any one of the preceding claims, wherein said at least one elastic fastener (103) has a compressed state and an extended state, the second perpendicular distance is greater than zero in the compressed state, and wherein the second perpendicular distance between the first structure (101) and the second structure (104) is larger in the extended state than in the compressed state. thereby enabling movement of the first structure (101) relative to the second structure (104). A damping device (10) according to any one of the preceding claims, wherein a shortest distance between the first structure (101) and the second structure (104) is greater than zero. A damping device (10) according to any one of the preceding claims, wherein the first perpendicular distance is in the range 0.01 to 20 mm, such as 1 to 10 mm, such as 1 to 5 mm, such as 3 mm. A damping device (10) according to any one of the preceding claims, wherein the second perpendicular distance is in the range 25 to 500 mm, such as 50 to 300 mm, such as 50 to 200 mm. A damping device (10) according to claim 9 in combination with claim 10, wherein the intermediate elastic member (302) has a resting state to which it returns when unaffected by any external longitudinal force or sound pressure wave, and wherein said at least one elastic fastener ( 103) is in a state between the extended state and the compressed state when the intermediate elastic member (302) is in its resting state. A damping device (10) according to any one of the preceding claims, wherein the second structure (104) is firmly anchored to a foundation of a wall, a roof or a floor of a building or dwelling, and wherein the first structure (101) is suspended in relation to the second structure (104) via the elastic fastening element (103). A damping device according to any one of the preceding claims, comprising a third structure, elastically attached to the second structure (104) by at least one further elastic fastening element (103) via at least one further control structure (102). A method of mounting a first structure (101) to a control structure (102) by means of a damping device (10) according to claim 1, by simultaneously securing a first part (301) of the elastic fastening element (103) to the first structure (101) and a second part (303) of the elastic fastening element (103) against the control structure (102), the elastic fastening element (103) being arranged straight through the first structure (101), so that the first structure ( 101) can be mounted against the control structure (102) from one direction. The method of claim 15, wherein the step of simultaneous attachment is performed by coupling a first element of a mounting tool to the first part (301) of the elastic fastener (103) and a second element of the mounting tool to the second part (303) of the elastic fastener through a through hole provided therein, rotate the interconnected mounting tool so that the first portion (301) is screwed into the first structure (101) and the second portion (303) is screwed into the control structure (102).