WO1998055782A1 - Diaphragm with multidirectional compression compensation - Google Patents

Abstract

The invention relates to a diaphragm which has multidirectional compression compensation so that it functions more efficiently. Said diaphragm has a profile (5) which is oriented in neither a radial nor a peripheral direction, especially in a middle area. The inventive diaphragm compensates compression in the conventional way and additionally, compensates compression applied at an angle thereto. To this end, grooves (5), for example, run in a spiral shape from the direction of the edge of the diaphragm (1), in an arch, extending into the oncoming direction towards the centre of the diaphragm. During operation of the diaphragm, the compression forces which extend laterally and crosswise to each other act upon the profile simultaneously in an oblique direction. Consequently, said profile is compressed from different directions and both compression forces are compensated.

Description

Membrane with multi-way compensation of compression

The present invention relates to a membrane with the. Characteristics. the preamble of claim 1.

It is known that flat membranes, for example with a corrugated profile or grooves, compensate for material compression or expansion when actuated by their special profile. Fia nmembrar.en with elienprofii can compensate for the compression aligned between membrane membrane and membrane component, but not for the transverse compression that occurs when the curvature is flattened by reducing the diameter of the circle in different areas of the membrane, which makes it particularly hard Material becomes inflexible. Since the profile known from practice with concentric grooves. is equipped, the compensation is oriented so that it only acts in the radial direction. When actuated, however, a curved membrane is flattened, which means that the concentric grooves distributed over the membrane surface are more or less strong. Reduce the circle diameter. By reducing the diameter of the circle, in these areas of the membrane additional compression is compensated for. borrowed a slight material compression in the transverse direction. The harder the material, the less the area of the membrane can be compressed in this direction. As a result, the membrane stiffens here and becomes worse in the functional sequence because no compensation is effective.

The closest prior art is known from US Pat. No. 3,187,641. There, a round membrane is disclosed, which has almost semicircular profiles. These profiles begin almost tangentially at the outer edge of the membrane, then curve towards the center so that they run radially in a central region of the membrane, and then continue almost tangentially into a circular flange arranged in the center of the membrane. The compensation achieved is effective both radially and in the circumferential direction in the areas in which the profile does not run radially. In the central area, however, the membrane is stiff and uncompensated in the radial direction.

Further known embodiments are known from the publications DE 31 42 440 C2, US Pat. No. 1,793,621 and DE-G 74 04 424. In each of these embodiments, however, part of the profile is arranged either in the circumferential direction or in the radial direction, so that no compression or expansion is compensated for in the relevant direction.

Finally, it is proposed in US Pat. No. 2,874,569 to provide grooves which are arranged at an angle to the concentric grooves and thus run from the membrane edge to the membrane center. However, the structure of the membrane would be very jagged and unstable. In addition, the embossing tool required for normal production becomes very complicated. The object of the present invention is to compensate for this additional slight material compression or material expansion in order to achieve a better functional sequence.

This problem is solved by a membrane with the features of claim 1.

Because the structure in the region between the edge and the center is at an angle to both the circumferential direction and the radial direction of the membrane, radial and tangential compression or expansion forces do not act in the direction of the greatest rigidity of the structure. The membrane can compensate for dimensional changes in both directions over the entire surface area.

It is advantageous if the edge is arranged essentially in a circle and lying in one plane. This results in a resilient membrane. A good compensation results if the structure has rounded, folded or kinked waves whose apex line (mountain or valley) runs from a first point adjacent to the edge to a second point adjacent to the center, the second point from the first point is spaced in the circumferential direction.

A simple manufacture is made possible if the structure, in particular the apex line, is curved or spiral, in particular uniformly curved.

It is also possible that the structure, in particular the apex line, runs straight.

For applications such as transducers, metering or diaphragm pumps and for brake boosters, it is advantageous if the center of the diaphragm carries a connection for an actuating device. The material can preferably be a metal foil, the structure being embossed in a manner known per se. However, the material can also be a composite material with a surface coating, for example a fabric with a lamination that is resistant to tensile strength or resistant to aggressive media.

There are also advantages if the membrane is made from a material that is not very elastic, such as PTFE, because these materials can have properties that cannot be achieved with elastic materials. This range of materials is only opened up for membranes by the present invention. Finally, it is advantageous if the membrane is arranged flat in its rest position, because a symmetrical deflection can then take place in both directions with the same loads. Depending on the application, other membrane geometries are also possible.

An embodiment of the present invention is shown in the drawing and will be described in more detail below. Show it:

1: a plan view of a membrane according to the invention with an arcuate structure;

2 shows a plan view of a membrane according to the invention with a straight structure;

3: a side view of the membrane according to FIG. 2 in a cross section; such as

4: a cross section through the structure along the line 4 from FIG. 2.

In Figure 1, a membrane according to the invention is shown in a plan view. The membrane has an outer edge region 1 for clamping. This is followed by a annular, structured area 2, which is bounded on the inside by a fastening area 3. In the edge area 1, the membrane is flat, while the area 2, depending on the application, is also flat or curved in its undeflected position. The embossed structure comprises waves 5 with flanks 6, valleys 7 and mountains 8. These run linienför ig from a point x at the edge 1 to a point x 'in the center, these points being offset from one another in the circumferential direction by an angle α.

FIG. 2 shows a corresponding membrane with a straight structure. The same elements are provided with the same reference numbers. The cross-sectional line for FIG. 4 is indicated at 4.

FIG. 3 shows the membrane according to FIG. 2 in a cross section from the side. The edge 1 is arranged in one plane, the central region 3 in a plane that is offset transversely with respect to the edge 1, and the actual membrane region 2 connects the regions 1 and 3.

4 finally shows a cross section along the line 4 from FIG. 2. The wavy structure 5 comprises wave crests 8, valleys 7 and flanks 6 in between. This structure is particularly easy to emboss in metal membranes as the currently preferred embodiment of the invention. However, the advantages according to the invention also result from other materials and other structures.

The advantageous effect achieved with the invention arises from the fact that the compensation acts in an additional direction. This also increases the flexibility of a membrane made of harder material. At the same time, the durability is increased. By changing the orientation of the concentric grooves, no additional grooves are required. Nevertheless, both compensations are now achieved at the same time. Grooves run obliquely from the direction of the membrane edge or in an arc in the approximate direction to the membrane center. The curvature of the arch can be determined according to the thickness of the membrane curvature. When the membrane is flattened, the lateral compression forces and the transverse compression forces must both impinge on these structures at an angle from the arrangement of the structures. Due to the special arrangement, the structures can be pressed together from different directions, whereby multi-way compensation takes place. A differently strong compensation in the respective direction is effective here due to a gradient of the structure of different strength at the respective corresponding location. For example, the grooves are approximately radially effective in the area of the membrane edge, because here the membrane diameter does not change as much due to the membrane attachment. When the diaphragm is actuated, the diaphragm center and the outer edge of the diaphragm can twist slightly against each other around the axis. So that a membrane with lamination becomes more flexible, the lamination can also have the new arrangement. With a fabric insert with the same arrangement as the new membrane, the special fabric structure could be easier for stretching.

Diaphragm pumps, transducers or transmitters as well as hydraulic elements come into consideration as fields of application. The application of the invention is particularly advantageous in the case of pressure accumulators for hydraulic or hydropneumatic motor vehicle suspensions and servo units, in which so far only rubber membranes have separated a gas cushion from the hydraulic fluid. The storage capacity deteriorates over time because the spring gas diffuses through the membrane. Metal membranes are lacking in durability and sufficient Working strokes were not used. A membrane according to the invention can be made of metal, whereby diffusion is prevented and the spring constant is retained in the long run.

Finally, pressure accumulators for central heating systems come into consideration as applications in which the creeping pressure loss of the buffer gas can likewise be prevented by means of a metal membrane.

Claims

claims Membrane made of a rigid, hardly stretchable material with an outer clamped edge (1) and a center (3) movable transversely to its edge (1) and with a profile (2) which is introduced into the surface of the membrane and which , Wrinkled or groove-shaped structure (5), characterized in that the structure (5) in the area between the edge (1) and the center (3) lies at an angle both to the circumferential direction and to the radial direction of the membrane . Membrane according to claim 1, so that the edge (1) is arranged in a substantially circular manner and lying in one plane. Membrane according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the Structure (5) has waves whose apex line (8) extends from a first point (x) adjacent to the edge (1) to a second point (x ^λ ) adjacent to the center, the second point (x ^Λ ) from the first point (x) is circumferentially spaced. Membrane according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the Structure (5), in particular the apex line (8) runs in an arc. 5. Membrane according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the Structure (5), in particular the apex line (8) runs spirally. 6. Membrane according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the Structure (5), in particular the apex line (8) is uniformly curved. 7. Membrane according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the Structure (5), in particular the apex line (8) runs straight. 8. Membrane according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the Center (3) of the membrane carries a connection for an actuator. 9. Membrane according to any one of the preceding claims, that the material is a metal foil, the structure (5) being embossed. 10. Membrane according to one of the preceding claims, that the material is a composite with a surface coating. 11. Membrane according to one of the preceding claims, characterized in that the material is a substantially inelastic plastic, preferably polytetrafluoroethylene (PTFE). 2. Membrane according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the membrane is arranged flat in its rest position.