EP3143470A1

EP3143470A1 - Flow control valve

Info

Publication number: EP3143470A1
Application number: EP15722442.9A
Authority: EP
Inventors: Michael Söchtig; Klaus Witte
Original assignee: Neoperl GmbH
Current assignee: Neoperl GmbH
Priority date: 2014-04-30
Filing date: 2015-04-30
Publication date: 2017-03-22
Also published as: CN106462169B; US20170052544A1; US10663981B2; DE202014003567U1; CN106462169A; WO2015165590A1

Abstract

The invention relates to a flow control valve comprising a membrane (2) which has at least one opening (7) through which a fluid flows, and an annular body (3; 20) which comprises a flow surface (8) and at least one through-flow opening (10). Said through-flow opening (10) is in fluid connection with the at least one opening (7) of the membrane (2). Said membrane (2) is flexible in the direction of the flow surface (8). Said flow control valve is able to maintain the volume flow constant when the pressure changes and is also low in height.

Description

Flow regulator

description

The invention relates to a flow regulator.

Flow rate controllers are well known in the art and in wide bandwidth. They are used, for example, in gas or, in particular, liquid lines or attached at the end and serve to keep the volume flow of a fluid flowing through the flow regulator constant independently of the pressure of the fluid.

From DE 2004 008 281 U1 a flow rate regulator is known which has a housing and a control body guided in the housing. The control body is conical and cooperates with a control orifice, into which the control body extends as the pressure of the fluid flowing through it increases. As a result, the control opening is increasingly closed. With decreasing pressure of the control body moves back in the direction of its initial position and thus releases a larger cross-section of the control opening.

CONFIRMATION COPY The well-known flow regulator has proven itself. However, it has been found that the overall height of the known flow rate regulator is quite high and thus not suitable for all applications.

Based on the known prior art, the present invention seeks to provide a flow regulator whose height is as low as possible.

To achieve this object, the flow rate regulator according to the invention comprises a membrane with at least one opening for the passage of a fluid and an annular body with an inflow surface and at least one flow opening, wherein the flow opening is in flow communication with the at least one opening of the membrane, and wherein the membrane is formed bendable in the direction of the inflow surface. The membrane represents a departure from the known conical rule body. It is flat and has only a small height. Through the at least one opening, the fluid can flow through the membrane. The membrane interacts with the inflow surface of the annular body. With increasing fluid pressure, the membrane bends advantageously in the direction of the inflow surface. As a result, the at least one opening approaches the inflow surface so far that the opening cross-section for the fluid is reduced. As a result, the invention provides a flow rate regulator which, on the one hand, is able to keep the volume flow constant as the pressure changes, and which at the same time has a construction height which is very low.

Preferably, the membrane and the inflow face form a gap. The fluid flows through the gap at low fluid pressure. As the fluid pressure increases, the gap advantageously becomes increasingly narrower. It should be noted that - depending on the material of the membrane - the gap may not be completely closed. However, at least in sections, the gap becomes so small that it inhibits the flow through the fluid. In an essential development of the invention, it is proposed that the gap widens preferably continuously towards the middle of the flow rate regulator. For a flow regulator with a cylindrical basic shape - as it is considered to be particularly advantageous - this means that the gap opens in the direction of the symmetry axis. In this context, it should be noted that a flow regulator with a cylindrical basic shape can advantageously have a cylindrical - possibly graduated - outer contour. The inner area of the flow rate regulator, on the other hand, may not have a rotationally symmetrical construction. Such conditions should be conceptually encompassed by the basic cylindrical shape.

A particularly advantageous embodiment of the invention is characterized in that the membrane is in its Lasteten state is just formed. Such an embodiment has several advantages. On the one hand, a planar membrane is simple and inexpensive to produce, for example by punching or laser cutting. The at least one opening can also be introduced into the membrane, for example by punching or laser cutting. Another advantage of a flat design of the membrane is the space savings. While in the prior art as mentioned above conical body rule are used, builds the advantageous embodiment of the invention

Flow regulator extremely flat.

Preferably, the membrane has a height between 0.1 and 0.5 mm, preferably between 0.1 and 0.3 mm. On the one hand, such a thickness provides sufficient stability of the membrane and, on the other hand, provides the necessary flexibility for the membrane to bend as the fluid pressure increases. Known flow rate regulators are at least partially made of plastic and have proven successful insofar as their production is inexpensive and their life is high. However, it has been found that plastic flow regulators are disadvantageous in certain applications. In particular, in the hospital or nursing area increased hygiene requirements are made. Preferably, all equipment should be as low-germ as possible. In the case of plastic parts, the desired sterility is not guaranteed since plastics are susceptible to bacterial attack due to the material. Against this background, it is considered to be particularly advantageous if the membrane is formed of metal, in particular consists of stainless steel. Such an advantageous embodiment opens up completely new applications. For example, the preferred embodiment is advantageously used in the hospital sector. The metallic membrane can be treated, for example, with aggressive cleaning agents. It is also largely resistant to temperature (especially in relation to plastic), which makes it autoclavable and, to that extent, sterilizable. Finally, it can be used in a wide temperature range, which opens up new application possibilities for the flow rate controller beyond the hospital area.

The at least one opening in the membrane is of particular importance. In the simplest case, it is round (for example as a punched hole) formed. With increasing deflection of the membrane, it is closed.

It is considered advantageous if the at least one opening is elongated. An elongated opening offers the possibility that with increasing deflection of the membrane, the opening is gradually closed over its length. Rather, it is intended to encompass such closing in which the fluid flow through the opening (s) is reduced due to the deflection and the consequent approach to the inflow surface. The preferred gradual closing of the opening described above is particularly advantageous when the at least one opening extends from outside to inside. For example, it may be provided that the opening extends radially from the peripheral area of the membrane towards its center. Alternatively, an arrangement of the opening is conceivable, in which the elongated opening also runs inwardly, but passes (in imaginary extension of the opening) at the center of the membrane.

In an essential development of the invention, it is proposed that the at least one opening is bent, in particular sickle-shaped. Preferably, the opening in this case runs arcuately in the edge region of the membrane in coarse adaptation to the edge region of the membrane. Such an embodiment is particularly advantageous if - as it is generally regarded as preferred - the membrane is round in plan view. A curved and preferably crescent-shaped design creates the possibility of a continuous and at the same time finely tuned reduction of the flow opening with increasing fluid pressure.

An essential aspect of the invention is that the membrane is bendable in the direction of the inflow surface. As a result, the at least one opening formed in the membrane is at least partially closed. An embodiment of the invention has proved to be particularly preferred in which, in a plan view of the flow rate regulator, the at least one opening at least partially, preferably substantially, in particular lies completely over the inflow surface. As a result, at a very high pressure, the flow regulator is able to minimize the flow area of the at least one orifice.

Preferably, the edge region of the membrane is continuous. Such a construction gives the membrane a desired intrinsic stability. At the same time, the at least one opening provides the necessary flexibility needed for the membrane to flex as the pressure increases. The edge region is advantageously not interrupted by the at least one opening.

An advantageous embodiment of the invention is characterized in that the center of the membrane is full-surface. This means that the membrane in the middle of the fluid can not be flowed through. The middle (and possibly further regions of the membrane) thus serve as an inflow surface for the

Fluid to deflect the membrane as pressure increases. Such a construction provides an advantageous response of the membrane.

The flow regulator has according to the invention at least one opening. Advantageously, at least 3 openings are provided in the membrane, which are preferably formed evenly distributed in the membrane. Several openings lead to a uniform flow of fluid through the flow regulator. In particular, more than 3 openings may be provided, for example 4 openings. The membrane is suitably attached to the ring body.

For this purpose, the annular body advantageously forms a receptacle for the membrane. Such a construction provides a compact flow regulator.

The receptacle can be formed as a groove, which is preferably formed circumferentially in the annular body. In this groove, the membrane is advantageously clipped, resulting in a simple construction of the flow regulator.

Alternatively, the ring body expediently forms a support for the membrane. The membrane is thus on the ring body. In this context, two types of storage are conceivable. In a first alternative, the membrane is firmly clamped. Here comes a clamping between the ring body (as a support) and, for example, a fastening ring or an input-side screen body into consideration, which firmly clamps the membrane between itself and the annular body. In a deflection, the edge regions of the membrane will not bend due to their restraint.

As an alternative to the fixed clamping, the membrane is mounted torque-free on the ring body. In particular, the membrane can rest freely on the support. In the context of the invention is understood by a torque-free storage when the membrane is not clamped at its edge. In the case of a deflection, the edge regions of the membrane can thus move, so that a comparatively sensitive response is expected. In a further development of the invention, it is proposed that the at least one flow opening is arranged in a central portion of the annular body. In particular, it is proposed that the at least one opening is preferably not arranged in the inner circumferential region of the annular body. It is expected that a passing of the fluid through the central portion of the annular body leads to particularly advantageous flow conditions, as will be explained in more detail below. Under a central portion is understood within the scope of the invention, the central region of the annular body. This may be a central bore or recess. Also possible are a plurality of passage openings which are formed centrally in the annular body. For example, a central opening can be provided around which a plurality of further openings, for example at least 5 openings, are arranged in a circle.

Preferably, the inflow surface drops toward the central region. The passing through the openings in the membrane fluid is thus discharged inwardly and passes through the flow opening of the annular body therethrough.

The geometry of the inflow surface is of particular importance. Among other things, it determines the characteristics of the flow rate controller. In this context, it is considered particularly advantageous if the inflow surface of the membrane asymptotically increases towards the outside. This measure also leads to an advantageous characteristic. The increase is preferably continuous. At this point be on it It is pointed out that an asymptotic increase is understood to mean a course in which the inflow surface increasingly approaches the membrane. In this case, a gap between the inflow surface and the membrane may remain in the edge region of the membrane or the inflow surface. This does not change the asymptotic approach.

The membrane is preferably attached in its edge region on the annular body, as has been explained above using the example of a groove formed in the annular body or the support. The maximum deflection thus advantageously benefits the membrane in its center. In this case, the membrane underside can approach the sloping inflow surface, which likewise drops toward the center, which, as described above, leads to an advantageous reduction of the flow cross-section.

The primary task of a flow rate regulator is to provide a constant volume flow independently of pressure. This is achieved in that, as the pressure of the fluid increases, the passage cross section for the fluid is reduced by the flow regulator. In the case of the invention, the diaphragm approaches the inflow surface of the annular body, whereby the opening cross section of the openings of the diaphragm is increasingly reduced. Consequently, the volume flow can be kept constant even at higher pressure.

Frequently, a flow controller is given a second task. In fact, it may be desirable for the flow leaving the flow regulator to have certain flow characteristics. In particular, it may be desired be that the fluid - for example water - emerges either as a laminar jet or as an air-mixed jet. In this context, it is advantageous if the annular body has in a lower portion a connecting device for a deflection device for the fluid. The connection device particularly advantageously allows a connection of a deflection device to the flow lines. The arrangement in the lower section supports the compact, flat design of the flow rate regulator.

Preferably, the connecting device has a plurality of feet, which are preferably directed radially outward. The feet can advantageously engage in a suitably circumferential groove of the deflection. For this purpose, the preferably resilient feet are simply clipped into the deflection and thereby create a durable connection. A preferred embodiment of the invention He is characterized in that the Verbindungsein device forms at least one breakthrough to flow through the fluid. In the case of the feet so the fluid passes through, for example, through openings formed between the feet.

Alternatively, the connecting device has a preferably central connecting pin. The connecting pin engages in a central pin receiving the Umlenkeinrichtun. Around the connecting pin around several flow openings are preferably formed. The connection is preferably created by a press fit. Such a Ver Bond manufacturing technology is particularly easy to implement, even if the ring body is formed of metal, as it is considered advantageous.

In terms of a compact and flat design of the invention, a preferred embodiment is provided in which the annular body has a bottom surface opposite the inflow, which causes a flow of the fluid to the outside. The annular body thus has both an upper side, which serves as an inflow surface, and an underside, which allows a guidance of the fluid to the outside. Such a construction creates compact dimensions and a particularly advantageous flow of the fluid.

As manufacturing technology particularly simple, an embodiment has been proven in which the underside has a circumferential recess. The recess serves for the above-described deflection of the fluid.

In the context of the invention, a flow regulator is claimed which has a deflection device which is connected to the annular body.

In the following, the invention will be described with reference to preferred embodiments in conjunction with the attached

Drawing explained in more detail. The drawing shows in: in a schematic representation of an exploded view of a first embodiment of the flow rate regulator according to the invention; in a schematic representation of the first embodiment in a sectional view; in a schematic representation of an exploded view of a second embodiment of the flow rate regulator according to the invention; in a schematic representation of the second imple mentation example in a sectional view; in a schematic representation of an exploded view of a third embodiment of the flow rate regulator according to the invention; in a schematic representation of the third imple mentation example in a sectional view; in a schematic representation of a side view of a membrane according to the invention, as used in the three embodiments;

Figure 8 is a schematic representation of the membrane of Figure 7 in a plan view; Figure 9 is a schematic representation of a sectional view of an annular body according to the invention, as it comes in the first embodiment used;

Figure 10 is a schematic representation of the ring body of Figure 9 in a plan view;

FIG. 11 is a schematic representation of a sectional view of an annular body according to the invention, as used in the second exemplary embodiment;

Figure 12 is a schematic representation of the ring body of Figure 11 in a plan view;

Figure 13 is a schematic representation of a sectional view of an annular body according to the invention, as it comes in the third embodiment used;

Figure 14 is a schematic representation of the ring body of Figure 13 in a plan view; Figure 15 is a schematic representation of a sectional view of a deflection device according to the invention, as used in the first and the second embodiment used; 16 shows a schematic representation of a sectional view of a deflection device according to the invention, as used in the third embodiment;

FIG. 17 is a schematic representation of a sectional view of a fourth exemplary embodiment of the flow rate regulator according to the invention;

Figure 18 is a detail view of the fourth embodiment of Figure 17;

19 shows a schematic representation of a sectional view of a fifth embodiment of the flow rate regulator according to the invention; and FIG. 20 shows a detailed view of the fifth exemplary embodiment according to FIG. 19.

Figure 1 shows an exploded view of a first embodiment of the flow rate controller according to the invention. The flow regulator in gur 1 has the following components from top to bottom:

A first sieve 1, a membrane 2, an annular body 3, a deflection device 4, a second sieve 5 and a housing wall 6. In the context of the invention, the membrane 2 and the annular body 3 are obligatory. They form the flow regulator. The two wires 1 and 5, the deflection device 4 and the housing wall 6 are considered as advantageous developments of the invention. The latter components add the further function of a jet regulator to the flow rate regulator according to the invention. In connection with FIG. 1, the basic functions of the flow rate regulator according to the invention should be at least suggested at this point. The first sieve 1 is a dirt sieve. It serves to keep dirt particles in the fluid.

The membrane 2 has a plurality of openings 7 through which the fluid flows. The membrane has a flexible design.

The annular body 3 has an inflow surface 8, which preferably circulates in the annular body 3 and advantageously defines a passage (see FIGS. 9, 11 and 13). The membrane 2 is in the built state (see Figure 2) in the direction of the inflow surface 8 bendable. The annular body 3 further comprises a circumferential groove 9, in which the membrane 2 (and possibly the sieve 1) can be used or are. Furthermore, the ring body 3 has a plurality of flow openings 10, through which the fluid can flow. On the underside of the annular body 3, a plurality of feet 11 are formed, which serve for fastening the deflection device 4, as will be explained in more detail in connection with Figure 2.

The deflecting device 4 is formed like a mushroom and has at its lower end a pin 12 which on the one hand has a flow-guiding function for the fluid and on the other hand keeps the wire 5 at a distance. The screen 5 preferably has a relatively coarse mesh size and acts as a flow straightener. The fluid flowing through the sieve 5 is homogenized by the sieve 5. Preferably, the sieve 5 has a larger mesh width than the sieve 1.

The housing wall 6 holds the wire 5 in position and defines with the deflection device 4 a flow path, as will be explained in more detail below.

Reference is made to Figure 2, which shows a sectional view of the assembled first embodiment. The sieve 1 and the membrane 2 are clipped into the annular body 3, wherein the sieve is seated with prestress in the annular body 3. The membrane 2 is preferably aligned in its unloaded state. The membrane 2 and the ring body 3 define between them a gap 13, which advantageously occurs because the inflow surface 8 drops to the inside of the flow rate regulator.

In the drawing, the fluid enters the flow regulator from above through the sieve 1 and through the openings 7. At low pressure of the fluid, the openings 7 are preferably fully open. If the fluid pressure increases, the membrane 2 bends downwards in the direction of the inflow surface 8. As a result, the opening cross-section of the openings 7 is reduced. The result is a substantially constant volume flow of the fluid despite the increased fluid pressure. It goes without saying that pressure fluctuations of the fluid can lead to slight volumetric flow fluctuations. The fluid thus flows through the openings 7 and the fol lowing flow openings 10 of the annular body 3 therethrough. Between the feet 11 of the annular body a breakthrough 14 is formed in each case, through which the fluid flows from the annular body to the outside.

The annular body 3 and connected to the annular body deflection 4 advantageously define between them a first annular space 15. From there, the fluid enters a formed on the underside of the annular body recess 16. The recess 16 is advantageously formed circumferentially.

The deflection device 4 has a mushroom-shaped outer surface 17. This limited with the housing wall 6, a second annular space 18. From the latter, the fluid exits down from the flow regulator.

It should be noted that within the scope of the invention, terms such as "top" and "bottom" are used. Although the flow rate regulator according to the invention can be installed in any orientation, this information refers to an upright flow rate regulator, as shown for example in Figure 2. The terms "inside", "outside" and "middle" are also used in the context of the invention.These specifications relate to the respective component, for example the center or the center of the ring body 3 is understood to be the region which is defined by the in FIGS FIG. 2 defines a central axis passing through the flow rate regulator from top to bottom is. The deflection device is, for example, an axis of symmetry. The center is not set to the axis or a point on the axis. Rather, the area around it should also be recorded.

3 and 4 show a flow rate regulator which, in contrast to the first embodiment, has only one central passage opening 19 instead of a plurality of throughflow openings 10 (see, for example, FIGS. This can have fluidic advantages. Incidentally, the illustrated second embodiment is identical to the first. This also applies to the attachment of the housing wall 6 to the ring body 3, which is preferably made by press fitting. As in the case of the first exemplary embodiment, the wire 5 is clipped into the housing wall 6 and is held at a distance by the pin 12.

Figures 5 and 6 show a third embodiment of the flow rate regulator according to the invention, which differs from the first two embodiments, inter alia by the attachment of the deflecting device to the annular body.

The annular body 20 has a central connecting pin 21. To the connecting pin 21 advantageously a plurality of flow openings 10 are formed. The deflection device 22 has a central pin receptacle 23. To connect the deflecting device 22 with the annular body 20, the connecting pin 21 is inserted into the pin receiving means 23, preferably in an interference fit. A derar term compound has the advantage of a simple production of the ring body 20, even if the ring body made of metal, in particular stainless steel, as it is preferred.

FIG. 7 shows the membrane 2 alone in a side view. It is flat and flat (in the unloaded state). In particular, the membrane may be formed in one piece.

FIG. 8 shows the membrane 2 in a plan view. From this view, an advantageous arrangement of the openings 7 becomes clear. The openings 7 preferably have an elongated shape. When the membrane 2 deflects, the flow cross-section of the openings is gradually closed off. As preferred, it is considered that the openings 7 are formed sickle-shaped. In particular, the openings 7 may extend from outside to inside. Advantageously, the membrane 2 is circular. As can be clearly seen, the edge region R is preferably designed to be continuous. The same applies to the middle M of the membrane. 2

Figure 9 shows the ring body 3 of the first embodiment in a sectional view. Here it is clear that the inflow surface 8 towards the center, which is characterized by the axis A, drops. The inflow surface 8 is preferably formed circumferentially and delimits advantageously between a central passage 24. Also clearly visible is the recess 16 on the inflow surface opposite th side of the ring body, which is preferably formed circumferentially. Incidentally, in the groove 9, the (not shown here) membrane 2 can be used. FIG. 10 shows a top view of the annular body 3. This has seven flow openings 10. More or less flow openings are conceivable.

FIG. 11 shows the annular body 3 of the second exemplary embodiment in a sectional view, which differs from the first exemplary embodiment according to FIGS. 9 and 10 in that instead of a plurality of passage openings only a single central flow opening 19 is provided. Incidentally, reference is made to the above description.

Figure 12 shows the ring body 3 of the second embodiment in a plan view. The inflow surface 8 advantageously surrounds the passage 24. The flow opening 19 is arranged centrally. In the context of the inventive concept it is to summarize the passage 24 and the passage opening 19 to a passage opening, which then has no jump, but passes through cylindrical. Figures 13 and 14 show the ring body 20 of the third embodiment, which has a connecting pin 21 on its underside. To tap the connection around the openings 10 are arranged. Figure 15 shows the deflection device 4 of the first two embodiments. The deflection device advantageously has a groove 25 designed as a receptacle 25 for connection to the ring body 3. The outer surface 17 of the deflection 4 is configured mushroom-shaped.

FIG. 16 shows a sectional view of the deflection device 22. The pin receptacle 23 is suitable for receiving the pin 21 (FIG. 13).

Reference is made to FIGS. 17 and 18, which show a fourth embodiment of the invention. The reference numeral 26 denotes the annular body. The annular body has a central flow opening 27.

The annular body 26 forms a support for the membrane 2.

For this purpose, it has a shoulder 28 on which the membrane 2 rests. The membrane 2 is firmly clamped from above through a screen body 29 against the annular body 26. For this purpose, a clamping body 30 engages over the screen body 29 and simultaneously engages under the annular body 26 and thus holds both components together. As can be seen in particular from FIG. 18, a distance 31 can be formed between the membrane 2 and the inflow surface 18. As can be clearly seen in particular in FIG. 17, the inflow surface 8 of the membrane 2 approaches asymptotically. The latter is flat in its unloaded state.

Referring to Figs. 19 and 20, which show a fifth embodiment. For clarity For the same (functional) components, the same reference numerals are used, even if the components differ structurally slightly. The difference between the fourth and the fifth embodiment consists in the design of the support of the annular body 26 and thus in the storage of the membrane 2. While in the fourth embodiment, the membrane is firmly clamped, the membrane is in the illustrated in Figures 19 and 20 Embodiment on a bead-like projection 32. In contrast to the fourth embodiment of the strainer body 29 further braced the diaphragm is not against the annular body 26, so that the membrane is mounted without torque. In a deflection of the membrane, the edges of the membrane are thus able to adapt to the tendency of the deflection. The clamping body 30 clamps the screen body 29 against the annular body 26th

In the above description of the figures, partial reference numerals have been used for components which differ slightly. This is to serve the better overview. Incidentally, the representations of the individual components and groups are not always true to scale. This should also serve the better overview.

LIST OF REFERENCE NUMBERS

1 sieve

2 membrane

3 ring body

4 deflection device

5 sieve

6 housing wall

7 openings

8 inflow area

9 groove

10 flow openings

11 feet

12 cones

13 gap

14 breakthrough

15 Ringraüm

16 recess

17 outer surface

18 annulus

19 flow opening

20 ring body

21 cones

22 deflection device

23 journal receptacle

24 passage

25 recording

26 ring body

27 flow opening

28 paragraph

29 sieve body 30 clamping body

31 distance

32 ledge R edge M center

Claims

Flow regulator

claims

1. Flow regulator, with

- A membrane (2) having at least one opening (7) for the passage of a fluid, and with

an annular body (3; 20) having an inflow surface (8) and at least one flow opening (10; 19; 27),

- wherein the flow opening (10; 19; 27) with the

at least one opening (7) of the membrane (2) in

Flow connection is, and

- Wherein the membrane (2) in the direction of the inflow surface (8) is formed bendable. 2. Flow regulator according to claim 1, characterized

characterized in that the membrane (2) and the

Anströmfläche (8) form a gap (13).

3. flow regulator according to claim 2, characterized

characterized in that the gap (13) to the center

Flow regulator extended.

Flow regulator according to one of claims 1 to 3, characterized in that the membrane (2) is flat in its unloaded state.

Flow regulator according to one of claims 1 to 4, characterized in that the membrane (2) has a height between 0.1 and 0.5 mm, preferably between 0.1 and 0.3 mm.

Flow regulator according to one of claims 1 to 5, characterized in that the membrane (2) is formed of metal, in particular consists of stainless steel.

Flow regulator according to one of claims 1 to 6, characterized in that the at least one opening (7) is elongated

Flow regulator according to one of claims 1 to 7, characterized in that the at least one opening (7) extends from outside to inside.

Flow regulator according to one of claims 1 to 8, characterized in that the at least one opening (7) is formed bent.

10 flow regulator according to one of claims 1 to 9, characterized in that the at least one opening (7) is at least partially, preferably substantially, in particular completely over the inflow surface.

11. Flow regulator according to one of claims 1 to 10, characterized in that the edge region (R) of the

Membrane (2) is continuous.

12. flow regulator according to one of claims 1 to 11, characterized in that the center (M) of the membrane (2) is formed over the entire surface.

13. Flow regulator according to one of claims 1 to 12, characterized by at least 3 openings (7), which are preferably uniformly, in particular symmetrically distributed in the membrane (2) are formed.

14. Flow regulator according to one of claims 1 to 13, characterized in that the annular body (3; 20) forms a receptacle for the membrane.

15. Flow regulator according to claim 14, characterized

in that the receptacle is formed as a groove (9) into which preferably the membrane (2) can be clipped. 16. Flow regulator according to one of claims 1 to 15, characterized in that the annular body (26) forms a support (28, 32) for the membrane (2).

1 . Flow regulator according to claim 16, characterized

characterized in that the membrane (2) is firmly clamped.

18. Flow regulator according to claim 16, characterized

in that the membrane (2) is mounted torque-free on the ring body (3; 20; 26), preferably rests freely on the support (32).

19. Flow regulator according to one of claims 1 to 18, characterized in that the at least one

Flow opening (10; 19; 27) in the middle of the annular body (3; 20; 26), preferably not in the outer peripheral region of the annular body, is arranged.

20. Flow regulator according to one of claims 1 to 19, characterized in that the inflow surface (8) to the center of the annular body (3; 20; 26) decreases towards.

21. Flow regulator according to one of claims 1 to 20, characterized in that the inflow surface (8) asymptotically increases towards the outside. 22. Flow rate regulator according to one of claims 1 to 21, characterized in that the annular body (3; 20) has in a lower portion a connecting device for a deflection device for the fluid. 23. Flow regulator according to claim 22, characterized

in that the connecting device has a plurality of feet (11), which are preferably directed radially outward. 24. Flow regulator according to claim 22 or 23, characterized in that the connecting device forms at least one opening (14) for flowing through the fluid.

25. Flow regulator according to claim 24, characterized

characterized in that the connecting device has a preferably central connection tap (21).

26. Flow regulator according to one of claims 1 to 25, characterized in that the annular body (3; 20) one of the inflow surface (8) opposite underside

having a flow of the fluid to the outside

causes.

27. Flow regulator according to claim 26, characterized

characterized in that the underside has a circumferential

Recess (16).

28. Flow regulator according to one of claims 1 to 27, characterized by a deflection device (4; 22) for the fluid, which is connected to the annular body (3; 20).