BE1020794A3 - METHOD FOR MANUFACTURING AN ELASTIC DAMPER FOR A FLOATING CONSTRUCTION - Google Patents

Description

Method for manufacturing an elastic damper for a floating construction

The invention relates to a method for manufacturing an elastic damper for damping vibrations, wherein the elastic damper is intended to be placed between a fixed surface and a floating structure so that the floating structure does not make direct contact with the surface. The floating structure thus rests on top of the dampers.

Such elastic dampers are used, for example, for floating railways in which rails are mounted on or in a concrete plate which is suspended above the ground by means of such dampers.

According to the current state of the art, all kinds of elastic materials are used for this, each having their own specific properties. Depending on the elastic material, for example, the damper will exhibit a certain stiffness that varies depending on the load of the damper. Similarly, the ratio of the dynamic stiffness to the static stiffness will vary depending on the materials used and the load. This ratio is the r-factor and also depends on specific material properties.

For example, rubber has an r-factor of 1.5 to 3 and a virtually continuous stiffening with an increasing pressure load. Furthermore, an ideal spring has a constant stiffness that is independent of the load and it also has a constant r-factor of 1. For some elastomers, such as polyurethane oblique, a stiffening load can occur with a rising pressure load, followed by a relaxation and then another stiffening.

Because of these specific material properties, the choice of the suitable material for manufacturing a damper with a specific stiffness at a certain load is greatly limited. As a result, materials may not be used for specific applications, notwithstanding the fact that they may also have other interesting properties, such as durability or a lower cost price.

The invention seeks to remedy this by proposing a method and an elastic damper for a floating construction that allow a predetermined r-factor to be obtained in a simple manner for a certain load of this damper, this r-factor being the ratio from the dynamic stiffness to the static stiffness at a certain load.

For this purpose, for a preselected r-factor of the elastic damper at a certain load exerted by the floating structure on the elastic damper, the elastic damper is composed of at least two different elastic elements, each having a different r-factor and which are placed parallel to each other between the fixed surface and the floating structure, wherein under the load of the structure these elements undergo the same compression and the load is divided into specific loads which are exerted by the floating structure on each of the elastic elements, wherein the elastic elements are each selected with a specific r-factor for a specific load of each of the elastic elements, the r-factor of the composite elastic damper corresponding to the predetermined r-factor.

It is expedient to determine the r-factor experimentally for at least one elastic element by experimentally determining the static and dynamic stiffnesses.

A metal coil spring is advantageously chosen for one of the elastic elements.

Furthermore, preferably, one of the elastic elements is made from at least one elastomeric material such as recycled rubber, rubber, natural rubber, recycled resin bonded rubber beads, cork rubber, polyurethane, thermoplastic elastomer (TPE), polyvinyl chloride (PVC) and / or ethylene vinyl acetate (EVA) ).

The invention also relates to an elastic damper for damping vibrations, intended to be placed between a fixed base and a floating structure so that the floating structure does not make direct contact with the base, the elastic damper comprising at least two different elastic elements which are intended to be parallel to each other between the fixed surface and the floating structure, wherein under the load of the structure these elements undergo the same compression, wherein these elastic elements each have a different r-factor and load.

Other details and advantages of the invention will be apparent from the following description of concrete embodiments of the method and the device according to the invention; this description is only given as an example and does not limit the scope of the protection claimed; the reference numerals used hereinafter refer to the attached figures.

Figure 1 is a schematic representation of a parallel connection of two elastic elements in a damper according to an embodiment of a method of the invention.

Figure 2 is a result of a first static and dynamic rigidity test of a damper consisting of a rubber cushion.

Figure 3 is a result of a second static and dynamic rigidity test of a damper consisting of a rubber cushion with a steel spring parallel thereto according to an embodiment of the invention.

Figure 4 is a result of a third static and dynamic stiffness test of a damper consisting of a rubber cushion with two steel springs.

Figure 5 is a result of a fourth static and dynamic rigidity test of a damper consisting of a rubber cushion with three steel springs.

Figure 6 is a result of a fifth static and dynamic rigidity test of a damper consisting of a rubber cushion with four steel springs.

Figure 7 is a result of a sixth static and dynamic rigidity test of a damper consisting of four steel springs.

Figure 8 is a schematic representation of a floating railroad provided with a damper according to the invention.

Figure 9 is a schematic representation of a parallel connection of two elastic elements in a damper according to an embodiment of a method of the invention in which an element is made up of different elastic materials placed in series.

The invention generally relates to a vibration damper and a method for designing this vibration damper, wherein a predetermined load, which is carried out on the vibration damper, is fixed together with a predetermined r-factor, which is the ratio of the dynamic stiffness on the static stiffness with this load. More specifically, according to the method of the invention, a damper is composed of different elastic elements, each with a specific r-factor, so that a composite damper is obtained which satisfies the predetermined total r-factor at the determined load. To this end, the various elastic elements are placed parallel to each other so that they each absorb a part of the load under the load and undergo the same compression.

According to a preferred embodiment of the method of the invention, two different elastic elements are combined in this way. Figure 1 shows such an arrangement schematically.

On a solid surface 4 the two different elements 1 and 2 of the damper are placed next to each other. The floating structure 3 is placed above it so that it does not make direct contact with the fixed base 4. The elements 1 and 2 are therefore parallel to each other and, preferably, have substantially the same height. The elements 1 and 2 can consist of, for example, rubber cushions 1 and steel springs 2.

For a specific application, a certain load F can be determined in advance which the floating structure 3 exerts on the damper. Furthermore, an optimum ratio between the dynamic stiffness Kdyn and the static stiffness Kstat which the elastic damper must satisfy with this load F can be determined, so that an optimum damping of vibrations is obtained. The ratio of dynamic stiffness to static stiffness is called the r-factor.

Therefore, for a specific application, a load F and a desired r-factor r can be determined with this load F, which the elastic damper must satisfy.

The damper must therefore be designed to exhibit a predetermined r-factor r at a predetermined load F exerted by the floating structure on the elastic damper.

According to this preferred embodiment of a method of the invention, the elastic damper is built up for this purpose from two elastic elements 1 and 2 which are connected at least partially parallel to each other between the fixed substrate and the floating construction. As a result, these elements 1 and 2 will undergo the same impression d under the load of the construction.

The load F is divided into a specific load F (1) carried by the first element and a specific load F (2) carried by the second element.

The elastic elements 1 and 2 are each selected with a specific dynamic rigidity Kdyn (1) and Kdyn (2), a specific static rigidity Kstat (1) and Kstat (2) and a specific r-factor r (1) and r (2) for the specific load F (1) and F (2) applied to the elements 1 and 2. By the selection of elastic elements 1 and 2 and the mutual ratio of the load applied by each of the elements 1 and 2, a total r-factor of the composite damper is obtained which corresponds to the predetermined r-factor r.

The load distribution between elements 1 and 2 and the corresponding r-factors can be calculated and / or determined experimentally.

Since the r-factor of the damper is the ratio of the dynamic stiffness of the damper Kdyn to the static stiffness of the damper Kstat, for this composite damper it holds that:

Kdyn = r. Kstat

The following also applies to each of elements 1 and 2:

Kdyn (1) = r (1). Kstat (l)

Kdyn (2) - r (2). Kstat (2)

Since the two elements 1 and 2 are connected in parallel, the following applies:

Kstat = Kstat (1) + Kstat (2)

Kdyn = Kdyn (1) + Kdyn (2)

Kdyn = r (1). Kstat (1) + r (2). Kstat (2)

Kdyn = r. Kstat = r. (Kstat (1) + Kstat (2)) = r. Kstat (1) + r.

Kstat (2) so is r (1). Kstat (1) + r (2). Kstat (2) = r. Kstat (1) + r. Kstat (2) from which (r (1) - r). Kstat (1) = (r - r (2)). Kstat (2) is zodus

Kstat (1) / Kstat (2) = (r - r (2)) / (r (1) - r)

This stiffness ratio between the two elements 1 and 2 reflects how much of the total force F will be absorbed by each of these elements 1 and 2 because the compression d is the same for both elements 1 and 2:

According to this preferred embodiment of a method of the invention, a steel spring is selected as the second element 2. The r-factor for this second element 2 is therefore 1.

In order to obtain a damper with a predetermined r-factor r and load F, the r-factors r (1) and r (2) of the elements 1 and 2 are adjusted to each other. However, for the second element 2, r (2) is 1, so that only the value of r (1) remains to be determined. Consequently, an elastic material is chosen for the first element 1 with a specific r-factor r (1).

This r-factor r (l) is dependent on the partial load F (l) and is determined experimentally: r (l) = f (Fl)

Hereby the static and the dynamic stiffnesses Kstat (l) and Kdyn (l) are determined by known test methods. As an example, Figures 2 to 7 show the results of such tests.

From the following three independent comparisons, therefore, F (1), F (2) and r (1) can be unambiguously determined:

The total load F and the r-factor r are predetermined by the requirements of the specific application of the floating construction with the damper. Furthermore, r (2) is also known if, for example, the second element 2 is a steel spring.

To illustrate this embodiment of the method according to the invention, figures 2 to 7 show the results of rigidity tests of six different elastic dampers. Six dampers were tested in a press in which the various elements 1 and 2 were combined.

In a first test, a rubber cushion with a length of 250 mm, a width of 250 mm and a height of 50 mm is used as a damper, the form factor of which is 1.24 and the density is 718.6 kg / m3.

In a second test, the cushion from the first test is connected in parallel with a steel spring with an unloaded height that is also 50 mm.

In a third test, the cushion from the first test is connected in parallel with two steel springs as in the second test.

In a fourth test, the cushion from the first test is connected in parallel with three steel springs as in the second test.

In a fifth test, the cushion from the first test is connected in parallel with four steel springs as in the second test.

In a sixth test, only four steel springs connected in parallel are used as a damper as a check in the second test.

The static stiffness tests were performed up to a total load F of 36 kN during a period of 1 minute. The dynamic stiffness tests were performed up to a total maximum load F of 36 kN with a force amplitude of 10% being maintained at a frequency of 15 Hz.

The overview shown in Table 1 shows the values obtained for the static and dynamic stiffnesses and the corresponding r-factors for a given load. The distribution of the load F (1) and F (2) between the first element 1, the rubber cushion, and the second element 2, the steel springs, is also represented, on the one hand as a calculated value F (1) and F ( 2) as described above and, on the other hand, as a theoretically calculated value F (2) for the second element 2 consisting of steel springs.

Thus, for a specific application on the basis of the desired load distribution F (1) and F (2) between the various elements 1 and 2 connected in parallel, the ratio of the elastic materials to each other can be chosen so that the desired load distribution and also the desired load distribution total r-factor is obtained for the composite elastic damper.

According to another embodiment of a method of the invention, the elastic damper is made up of a plurality of different elastic elements 1, 2, x, placed parallel to each other and each a part F (1), F (2), F (x) of the total tax F. Because each of these elements has a different r-factor r (1), r (2), r (x), according to the method of the invention the ratios of the partial loads F (1), F (2), F ( X)

Table 1: overview of the results of the static and dynamic rigidity tests for a series of damper arrangements with an elastic rubber cushion and / or one or more steel springs from figures 2 to 7.

Test 1: damper consisting of a rubber cushion (elastic element 1) (Figure 2).

Calculated distribution of load between theoretically calculated

Experimental test results static and rubber cushion (element 1) and springs (element 2) load on the springs dynamic stiffness test (1) (element 2) (2) deviation F (l) Kstat (1) Kdyn (1) d (%) d (mm) (kN) (N / mm) (N / mm) r (1) F (1) (kN) F (1) (%) F (2) (kN) F (2) (%) F ( 2) (kN) D (%) 10 5.05 9.23 1963 5229.58 2.66 10 100 0 0 0.00 0 15 7.58 14.59 2345 6698.17 2.86 15 100 0 0 0 00 0 20 10.1 21.43 3187 9275.33 2.91 20 100 0 0 0.00 0

Test 2: damper consisting of a rubber cushion (elastic element 1) and a spring (elastic element 2) (Figure 3).

Calculated distribution of load between theoretically calculated

Experimental test results static and rubber cushion (element 1) and springs (element 2) load on the springs dynamic stiffness test (1) (element 2) (2) deviation

Kstat Kdyn d (%) d (mm) F (kN) (N / mm) (N / mm) r F (1) (kN) F (1) (%) F (2) (kN) F (2) (%) F (2) (kN) D (%) 10 5.05 10.46 2254 5320.63 2.36 8.55 81.76 1.91 18.24 1.84 3.62 15 7.58 16.56 2646 6765.02 2.56 13.89 83.86 2.67 16.14 2.76 3.26 20 10.1 24.24 3536 9275.45 2.62 20.60 84.97 3, 64 15.03 3.68 0.92

Table 1 (continued): overview of the results of the static and dynamic rigidity tests for a series of damper arrangements with an elastic rubber cushion and / or one or more steel springs from figures 2 to 7.

Test 3: damper consisting of a rubber cushion (elastic element 1) and two springs (elastic element 2) (Figure 4).

Calculated distribution of load between theoretically calculated

Experimental test results static and rubber cushion (element 1) and springs (element 2) load on the springs dynamic stiffness test (1) (element 2) (2) deviation

Kstat Kdyn d {%) d (mm) F (kN) (N / mm) (N / mm) r F (1) (kN) F (1) (%) F (2) (kN) F (2) (%) F {2) (kN) D (%) 10 5.05 10 2598 5352.59 2.06 6.37 63.72 3.63 36.28 3.68 1.37 15 7.58 16, 84 2888 6,391.14 2.21 11.00 65.34 5.84 34.66 5.52 5.41 20 10.1 24.87 3545 8305.14 2.34 17.48 70.29 7.39 29 , 71 7.36 0.45

Test 4: damper consisting of a rubber cushion (elastic element 1) and three springs (elastic element 2) (Figure 5).

Calculated distribution of load between theoretically calculated

Experimental test results static and rubber cushion (element 1) and springs (element 2) load on the springs dynamic stiffness test (1) (element 2) (2) deviation

Kstat Kdyn d (%) d (mm) F (kN) (N / mm) (N / mm) r F (1) (kN) F (1) (%) F (2) (kN) F (2) (%) F (2) (kN) D (%) 10 5.05 13.12 2962 5930.07 2.00 7.90 60.22 5.22 39.78 5.52 5.70 15 7.58 21.07 3400 7204.25 2.12 12.70 60.27 8.37 39.73 8.28 1.07 20 10.1 30.63 4296 9577.00 2.23 19.71 64.35 10, 92 35.65 11.03 1.04

Table 1 (continued): overview of the results of the static and dynamic rigidity tests for a series of damper arrangements with an elastic rubber cushion and / or one or more steel springs from figures 2 to 7.

Test 5: damper consisting of a rubber cushion (elastic element 1) and four springs (elastic element 2) (Figure 6).

Calculated distribution of load between theoretically calculated

Experimental test results static and rubber cushion (element 1) and springs (element 2) load on the springs dynamic stiffness test (1) (element 2) (2) deviation

Kstat Kdyn d {%) d (mm) F (kN) (N / mm) (N / mm) r F (1) (kN) F (1) (%) F (2) (kN) F (2) (%) F (2) (kN) D (%) 10 5; 05 15.15 3393 6316.66 1.86 7.84 51.78 7.31 48.22 7.36 0.70 15 7.58 24.23 3854 7584.83 1.97 12.64 52.15 11.59 47.85 11.04 4.77

20 10.1 35.08 NA NA NA NA NA NA NA NA NA

Test 6: damper consisting of four springs (elastic element 2) (Figure 7).

Calculated distribution of load between theoretically calculated

Experimental test results static and rubber cushion (element 1) and springs (element 2) load on the springs dynamic stiffness test (1) (element 2) (2) deviation F (2) Kstat (2) Kdyn (2) d (%) d (mm) (kN) (N / mm) (N / mm) r (2) F (1) (kN) F (1) (%) F (2) (kN) F (2) (%) F ( 2) (kN) D (%) 10 5.05 7 1449 1212.07 0.84 0.00 0.00 10.00 100.00 7.350 5.09 15 7.58 10.68 1480 1257.39 0, 85 0.00 0.00 15.00 100.00 11.04 3.38 20 10.1 14.39 1487 1282.94 0.86 0.00 0.00 20.00 100.00 14.71 2, 24

Table 1 (continued): overview of the results of the static and dynamic rigidity tests for a series of damper arrangements with an elastic rubber cushion and / or one or more steel springs from figures 2 to 7.

Theoretical damper consisting of four springs (elastic element 2)

Kstat Kdyn F (kN) d (mm) F (kN) (N / mm) (N / mm) r (2) 21.6 15.7 1376 1376 1.00 25.2 18.3 1376 1376 1.00 (1) calculated on the basis of experimental data for r (1) from the test 1 (2) calculated with a spring constant K that amounts to 364 N / mm, so that the elastic damper adjusts the pre-imposed or chosen ratio of dynamic to static stiffness or r-factor r.

According to a further embodiment of a method of the invention, the elastic damper is made up of several different elastic elements that are placed parallel to each other and in which the r-factor is determined experimentally by means of static and dynamic rigidity tests which are known per se.

According to a specific embodiment of the method of the invention, the floating construction 3 consists, for example, of a concrete slab with an engineered railroad 5 and a rail vehicle as shown in Fig. 8.

According to a specific embodiment of the damper according to the invention, it consists of a strip of alternating elastomeric pads and steel springs that are placed parallel to each other between the substrate and the floating structure.

The invention is of course not limited to the method and device according to the invention described above.

Thus, the various elements 1, 2, x per se can also be constructed from different series of elastic materials, as also shown diagrammatically in Figure 9. Hereby, different layers of materials 6, 7, 8 are placed on top of each other between the substrate 4 and the floating structure 3. For example, a rubber cushion can have a closed cavity in which a steel spiral compression spring is placed, the rubber cushion also extending between the floating construction and this steel spiral compression spring.

Claims (17)

A method of manufacturing an elastic damper for damping vibrations, the elastic damper being intended to be placed between a fixed surface and a floating structure so that the floating structure does not make direct contact with the surface, characterized in that a predetermined r-factor (r) of the elastic damper is selected at a predetermined total load (F) exerted by the floating structure on the elastic damper, the elastic damper being composed of at least two different elastic elements (1, 2, x) that are placed at least partially parallel next to each other between the fixed surface and the floating structure, whereby under the load of the structure these elements (1, 2, x) undergo the same compression (d) and the total load (F) is divided into specific loads (F (1), F (2), F (x)) imposed by the floating structure on each of the elastic elements n (1, 2, x) is applied, the elastic elements (1, 2, x) being selected with each a specific r-factor (r (1), r (2), r (x)) for the specific loads (F (1), F (2), F (x)) of each of the elastic elements (1, 2, x), as a function of the predetermined r-factor (r), so that the r-factor of the elastic damper at the total load (F) corresponds to this. The method of claim 1, wherein the r-factor (r (1), r (2), r (x)) is determined experimentally for at least one elastic element (1, 2, x) by experimentally the static (Kstat (1), Kstat (2), Kstat (x)) and the dynamic (Kdyn (1), Kdyn (2), Kdyn (x)) stiffnesses. Method according to claim 1 or 2, wherein a metal coil spring is selected for at least one of the elastic elements (1, 2, x). Method according to one of claims 1 to 3, wherein at least one of the elastic elements (1, 2, x) is made from at least one elastomeric material such as recycled rubber, rubber, natural rubber, recycled resin-bound rubber granules, cork rubber, polyurethane, thermoplastic elastomer (TPE), polyvinyl chloride (PVC) and / or ethylene vinyl acetate (EVA). The method according to any of claims 1 to 4, wherein said predetermined r factor (r) is less than 2.50, preferably less than 1.75. Method according to one of claims 1 to 5, wherein the elastic damper is made up of two elastic elements (1, 2) and wherein a load distribution (F (1), F (2)) and the r-factor of the elastic elements (1,2) is obtained from the following equations

r is the r-factor of the elastic damper, F (1) is a first part of the force F that is exerted by the floating structure (3) on a first elastic element (1), r (1) is the r-factor of the first elastic element (1) of the elastic damper, F (2) is a second part of the force F exerted on the second elastic element (2) by the floating structure (3), r (2) is the r is the factor of the second elastic element (2) of the elastic damper, wherein r (1) and / or r (2) are determined experimentally as a function of the load F (1) and F (2), respectively. The method of any one of claims 1 to 6, wherein the elastic damper is manufactured for a floating structure that includes a railway bed, a railway, and a railway vehicle. The method according to any of claims 1 to 7, wherein the elastic damper is built up from steel springs and rubber pads. The method of any one of claims 1 to 8, wherein the elastic damper is made up of at least one elastic element that contains various elastic materials placed in series. 10. Elastic damper for damping vibrations, intended to be placed between a fixed surface and a floating structure so that the floating structure does not make direct contact with the surface, characterized in that the elastic damper has at least two different elastic elements (1, 2 , x) which are intended to be at least partially parallel to each other between the fixed surface and the floating structure, whereby under the load of the structure these elements (1, 2, x) undergo the same compression (d), whereby these elastic elements (1, 2, x) each have a different r-factor (r (1), r (2), r (x)) and load (F (1), F (2), F (x)). Elastic damper according to claim 10, wherein at least one elastic element consists of a steel spring. The elastic damper according to claim 10 or 11, wherein at least one elastic element consists of a cushion made of an elastomeric material such as rubber. The elastic damper according to any of claims 10 to 12, wherein it comprises an elastomer sole between the substrate and the various elastic elements (1, 2, x) and / or between the floating structure and the various elastic elements (1, 2, X). The elastic damper according to any of claims 10 to 13, wherein the elastic elements (1, 2, x) comprise rubber pads and steel springs, with approximately 20 to 80% of the total load being distributed to the rubber pad and approximately 20 up to 80% of the total load is distributed to the steel springs, and in particular about 30 to 70% of the total load is distributed to the rubber pad and about 30 to 70% of the total load is distributed to the steel springs . The elastic damper according to any of claims 10 to 14, wherein at least one elastic element consists of a steel spring with a rigidity that is 200 N / mm to 4000 N / mm, preferably about 300 N / mm to 500 N / mm , in particular about 350 N / mm. The elastic damper of any one of claims 10 to 15, wherein at least one element comprises several elastic materials placed in series. A railroad provided with an elastic damper according to any one of the preceding claims.