Coupling-Damping Layer at Vibration Interface

Abstract

A coupling-damping thin layer of gap-filling material to be used at interfaces under compression and the thickness control techniques. The thickness of the layer is proposed to be controlled by an insertion of an elastic material into the gap-filling material. By selection of appropriate stiffness of the elastic material and the viscosity of the gap-filling material, the dynamic properties of the layer can be controlled to optimise vibration dissipation through hysteresis loop damping.

Claims

1. Coupling-damping layer, formed by means of fusing solid gap filling material with elastic webbing, applied at vibration interface, wherein elastic webbing in a woven form or non-woven form is inserted into the coupling-damping layer, such that the coupling-damping layer maintains with a certain thickness under compression at interfaces and spillage of the gap-filling material is minimized; the coupling-damping layer can be attached at vibration surface by means of compressive force, wherein the coupling-damping layer is capable of filling up any minor mismatch of the two interfacing surfaces by applying strong compression force to enable plastic flow of the gap-filling material; the coupling-damping layer is capable of providing adhesive force at vibration interface to connect the vibration object and a device attaching thereon; the coupling-damping layer is capable of being a gap-filling material to improve vibration transmission passing through uneven interface surfaces; the coupling-damping layer as a damping layer is capable of being a hysteresis dissipation layer to minimize any reflection of vibration at the interface by hysteresis dissipation to improve overall damping effectiveness.

2. The coupling-damping layer in claim 1 maintained at a certain thickness by elastic webbing, capable of being a vibration absorption layer in compression and tension direction wherein the compression and/or tension force is over a certain value.

3. The coupling-damping layer in claim 1 maintained at a certain thickness by elastic webbing, capable of being a damping layer in shearing directions by utilizing the visco-elastic or visco-plastic property of gap filling material to allow energy dissipation and enhancing the energy dissipation in oscillation cycles.

4. At least one coupling-damping layer in claim 1 installed in a vibration damper characterized in that a coupling-damping layer as a vibration coupling layer attached between the vibration surface and surface of vibration damper.

5. At least one coupling-damping layer installed in the vibration damper in claim 4 further characterized in that a coupling-damping layer as a damping layer is attached on some surfaces of vibration damper to damp the vibration in direction of shearing or compression or tension; the coupling layer is capable of fine tuning the dynamic property of the vibration damper.

6. A vibration damper in claim 4 can be a tuned mass damper.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] The attached drawings illustrate some possible arrangements of the invention while other embodiments of the invention are possible. The particularity of the drawing should not supersede the generality of the preceding description of the invention.

[0012] FIG. 1 shows a cross-sectional view of the Invention (Item 100).

[0013] FIG. 2 shows a top view of the Invention (Item 100).

[0014] FIG. 3 shows a typical hysteresis loop of load-displacement relationship in shearing directions.

[0015] FIG. 4 illustrates an application of the invention in tuned mass damper (single oscillation mass).

[0016] FIG. 5 illustrates an application of the invention in tuned mass damper (multiple oscillation masses).

DETAILED DESCRIPTION OF THE INVENTION

[0017] The invention comprises elastic material inserted into a gap-filling material, as illustrated in FIG. 1 and FIG. 2. Item 101 represents the elastic material, such as webbing in a mesh structure. Item 102 represents the gap-filling material. Item 101 is inserted into Item 102 to give the overall structure of the coupling-damping thin layer (Item 100). A mesh of webbing forms the main structure of the thin layer in order to limit the compression of attached gap-filling material to a finite thickness. On the other hand, the gap-filling material serves the main function of vibration coupling and dynamic properties of the whole structure. Elastic property of the inserted elastic material allows transmission of both shearing force and compressive force in the respective directions. Inheriting the physical property of gap-filling material, the design is also capable of direct shearing flow.

[0018] A typical hysteresis loop of load-displacement relationship in shearing directions is shown in FIG. 3. For a given force, which is smaller than F, the coupling-damping thin layer (Item 100) acts as an elastic material and be compressed. When the force is beyond F, the layer will start to flow. Later, when the force is decreased, it will return to be elastic and be recovered.

[0019] The insertion of elastic material to the gap-filling layer solves the problem of excess flowing out of coupling material. The elastic material, such as webbing, provides constraint to limit the flowing out of gap-filling material and help controlling the layer thickness with time without hindering the gap filling process of the gap-filling material. With such design inserted between two working surfaces, the working efficiency of vibration coupling layer and hence of the vibration control could be maintained over a prolonged period of time.

[0020] Apart from the application as a vibration coupling layer between the vibrating surface and the vibration control device in compression/tension direction, the invention can also act as a damping layer to modify the overall dynamic properties. For example, when it is used in tuned mass damper, the plastic flow or the viscous flow property of the gap-filling material can allow extra energy dissipation, and hence optimizing and enhancing the energy dissipation in oscillation cycles.

[0021] First embodiment illustrates an application of the invention as in tuned mass damper with single oscillation mass in FIG. 4 where the coupling damping layers are integrated into a vibration damper, such as tuned mass damper, at different interfaces serving for different functions. The overall assembly (Item 200) illustrates the application of modified tuned mass damper to a vibration surface. Item 201 represents a coupling-damping thin layer applied, mainly to serve the first function as a vibration coupling layer to enhance the vibration transmission from the vibration surface to the vibration controlling device, i.e. the tuned mass damper in this example. Item 202 represents the mounting of tuned mass damper to the vibration surface. The mounting could be magnetic, clamped, or by other means. Item 203 represents another coupling-damping thin layer, mainly to serve the second function as a damping layer to modify and optimise the overall dynamic properties of the tuned mass damper. Item 204 and Item 205 represent the elastic material and oscillation mass of the tuned mass damper design. Item 201 and Item 203 can be optimised individually to serve the intended purposes.

[0022] Second embodiment illustrates an application of the invention as in tuned mass damper with multiple oscillation masses in FIG. 5 where multiple oscillation masses are included in different directions instead of using a single oscillation mass as in FIG. 4. Item 301 represents a coupling-damping thin layer applied, mainly to serve the first function as a vibration coupling layer to enhance the vibration transmission from the vibration surface to the tuned mass damper. Item 302 represents the mounting of tuned mass damper to the vibration surface. The mounting could be magnetic, clamped, or by other means. Item 303 represents another coupling-damping thin layer, mainly to serve the second function as a damping layer to modify and optimise the overall dynamic properties of the tuned mass damper. Item 304 and Item 305 represent the elastic material and the multiple oscillation masses of the tuned mass damper design. Item 301 and Item 303 can be optimised individually to serve the intended purposes.

[0023] As illustrated in FIG. 5, the invention could be applied in a tuned mass damper to modify the overall dynamic properties of the damper. Item 303 illustrates the application of modified tuned mass damper to a vibration surface while Item 304 and Item 305 represents the elastic material and oscillation masses of the tuned mass damper design. Considering the original tuned mass damper system without damping layer Item 303, although the tuned mass damper works very effectively at the resonance frequency of the free vibration surface, the resonance frequencies from the damped system may hinder the overall performance of the tuned mass damper. Through applying and optimising the damping layer Item 303 to the tuned mass damper design, the overall dynamic properties of the tuned mass damping system could be fine-tuned to achieve the desired outcome.