DE19743740A1 - Fluid flow quantity regulator using multistage elastomer ring inserts giving more constant driving pressure across pipe - Google Patents

Abstract

Uses two or more elastomer ring stages mounted in flow. The regulator comprises concentric parts with central holes, held on an internal ledge in the tube. Elastomer rings are used in suspending the parts in the flow.

Description

Background of the Invention

This invention relates to a multi-stage flow flow regulator according to the elastomer ring deformation principle, in which several in series, by pressing one fluid flowing through an annular gap is elastic deformable elastomer rings the amount of one by one Control the pipeline flowing fluid flow.

General state of the art

Flow rate working according to the elastomer ring deformation principle volume controls stand out from other conventional ones Flow regulators through a very inexpensive Manufacturing, extensive maintenance and high Wear resistance.

In known after the elastomer ring deformation principle working flow regulators deform as a result the flow resistance of the through the annular gap in Regulator body flowing fluid or elastomer ring (e) into the annular gap. The deformation that Restoring force of the elastomer and the geometry of the Annular gaps are coordinated so that the operating pressure range the flow rate remains almost constant.

However, such known after the elastomer ring Deforming principle working flow controller at high Pressure differences (about <4 bar) for hissing, as with such  Pressure differences because of the effect of the regulation Annular gap becomes very narrow, cavities occur. This You can hiss by adding a choke suppress, but this hinders small Pressure differences the flow so that the target amount is not more is achieved.

Become two or more elastomer ring flow rates controller connected in series, one of them takes over Regulate the whole scheme while the other elastomer ring flow controller remain open. In such Flow controllers with different nominal flow quantity always regulates the smallest regulator. At same It is the controller who is on the tolerance level is most sensitive.

It is an object of this invention, one after the Flow rate working elastomer ring deformation principle to improve the regulator so that despite fluctuation the driving pressure difference over wide areas Fluid flow in a pipeline, e.g. B. outflow a pipeline, to an approximately constant Can regulate flow rate. The pressure difference can for example in continuous water heaters from 1-15 bar vary.

In one embodiment, the setpoint of the controller is said to Invention can be made adjustable. This adjustability for continuous flow water heaters, the flow rate of the flowing fluids (water) of 5-15 liters per minute can adjust.

The above task is done with a generic flow flow regulator invented according to the elastomer ring deformation principle solved according to the invention in that the flow regulator Means for non-positive and / or positive  Connection of the elastomer rings connected in series having.

Advantageously, the invention achieves that even no hiss occurs at high throttle pressures. The according to the invention with a positive and / or positive fit connected, connected in series in the pipeline Elastomer rings are then used when throttling Forces arising in the axial direction of the flow positively deformed. This ensures that the Throttling takes place in stages, with the deformation of all Elastomer rings contribute to throttling.

In one embodiment of the invention Means the frictional connection of the rear reach interconnected elastomer rings by in the pipeline axially movable support body formed wear one of the elastomer rings and so on are designed so that by throttling the Forces arising from fluid flow force the series deform the switched elastomer rings. This one hard compared to the elastomer material of the elastomer rings and rigid material existing support body can be a Have outside wall that run inside the pipeline and is easily movable in the axial direction. The Inner wall of the support body can be used to hold the Have ring groove serving elastomer rings. The carrier body can each be graded so that they with a annular web projecting in the axial direction which at Throttling the flow in the axial direction Force on the elastomer ring in the next downstream located level of the flow controller and deform this elastomer ring elastically.

To the axial movement of the support body or the Limit the carrier body in the direction of flow of the fluid,  can first limiting means in the pipeline be provided. The first limiting means can e.g. B. by a simple ring bead protruding in the radial direction be educated.

Furthermore, the second limiting means can be the axial one Movement of the carrier body (s) against the Limit the direction of flow of the fluid. The second Limiting agents are only important when in the pipe line a backflow of the fluid can occur.

In another embodiment of the invention, a only one elastomer part can be provided in the pipeline, one each two adjacent elastomer rings connecting with each other in a positive and positive manner Has connecting ring section. This connection ring section can thus be made of the same elastomer material exist like the elastomer rings.

The connecting ring section can in particular have thin walls be executed as the respective associated Elastomer rings.

Furthermore, the one or more connecting ring section (s) and the elastomer part that unites the elastomer rings is one in Have flow direction tapered outer wall. In the pipeline, an annular support member can be determined that the elastomer part worn by him by throttling the fluid flow in the Pipe forces arising axially and radially deformable is, the or the connecting ring portion (s) with is or will be deformed. During this deformation process the elastomeric part as a whole is corresponding to the supported conically shaped inner wall of the support part. In the flow controller, d. H. axially in the or the Carrier part (s) carrying elastomer rings can be more advantageous  a conical body lying together with the elastomer rings connected in series form the annular gap Are defined.

This axial body can advantageously by a axially adjustable axis or spindle in the axial direction be adjusted and to adjust the fluid flow Cross-section and thus the nominal flow rate provided be.

The invention is described below with reference to the preferred embodiments of the invention more stage flow controller representing drawing figures described. The drawing figures show in single:

Figure 1 is a schematic longitudinal section through a first embodiment of a two-stage flow controller according to the invention with a non-positive connection of the stages.

Figure 2 is a schematic longitudinal section through a second embodiment of a two-stage flow controller according to the invention with a non-positive and positive connection of the stages. and

Fig. 3 is a similar to Fig. 2 embodiment of a two-stage flow controller according to the invention, which is equipped with a spindle for the axial adjustment of the body defining the annular gap inside the controller.

Principles according to the invention are first explained with reference to the first preferred embodiment of a two-stage flow rate regulator according to the invention shown in a schematic longitudinal section in FIG. 1.

Within a pipeline 9 , in which a fluid flow flows in the direction shown by two arrows, a two-stage flow rate regulator designed according to the elastomer ring deformation principle, which is generally designated by reference number 10 , is used. Two elastomer rings 3 , 3 'lying one behind the other in the axial direction and having the same cross section are used in annular savings in the inner wall of two separate, stepped carrier bodies 1 , 2 lying one behind the other. The inner wall of the pipeline 9 forms an annular bead 8 , which serves to limit the movement of the flow regulator in the flow direction 7 . Limiting means for limiting the movement of the regulating bodies opposite to the flow direction 7 are omitted in FIG. 1. Such a limitation can also be formed by a bead lying on the inner wall of the pipeline 9 upstream of the control body. The second, upstream stage, ie the carrier body 2 of the two-stage flow rate regulator, together with the elastomer ring 3 'fixed on its inner wall, can press and deform the first elastomer ring 3 in the direction of flow due to the force exerted due to the restriction of the fluid flow. This positive connection is realized by an annular axial projection 6 of the second carrier body 2 . The throttling is achieved by a variable annular gap, which forms the elastomer rings 3 and 3 'carried on the carrier bodies 1 and 2 and two axial limiting bodies 4 and 5 . The gap geometry changes according to the pressure difference between the upstream and downstream side of the flow rate controller, namely because of the deformation of the non-positively coupled elastomer rings 3 and 3 ', so that the fluid flow can be regulated over a wide range of the pressure difference to an approximately constant flow rate. The flow regulator 10 according to the invention shown in FIG. 1 can be matched to a relatively large operating pressure range by the appropriate shaping of the limiting bodies 4 , 5 , the carrier bodies 1 , 2 , the elastomer rings 3 , 3 'and their elastic properties, so that the volume flow despite fluctuating pressure difference can be regulated constantly. When used in continuous water heaters, this operating pressure range is, for example, 1-15 bar.

The second embodiment 11, shown in FIG. 2 in the form of a schematic longitudinal section, of a two-stage flow regulator designed according to the principle of the elastomer ring deforming uses a non-positive and positive connection between two elastomer rings 13 lying one behind the other in the pipeline 9 . The elastomer rings 13 together with a connecting ring portion 16 form a one-piece annular elastomer part 20 , which is received with its conical outer surface by a fixed in the pipeline 9 annular support member 14 so that it is created by the throttling of the fluid flow 7 in the pipeline 9 Forces axially and radially deformable. During this deformation, not only the elastomer rings 13 , but also the intermediate annular connecting section 16 are deformed. This connecting ring section 16 preferably consists of the same elastomer material as the two adjoining elastomer rings, and the wall thickness of the connecting ring section 16 is less than at the location of the two elastomer rings 13 . The carrier part 14 has a radial retaining ring at its downstream end, so that the pressure resulting from the throttling of the fluid flow 7 cannot push the elastomer part 20 out of the interior of the carrier part 14 . In addition, a two-stage conical limiting body is mounted axially in the pipe 9 within the flow regulator, for example on the carrier body 14 . Between the limiting body 15 and the elastomer part 20 , the annular gap restricting the fluid flow according to the pressure difference is defined.

The third embodiment 12 of a two-stage flow regulator according to the invention shown in a schematic longitudinal section in FIG. 3 is carried out in a very similar manner to the embodiment shown in FIG. 2 and has essentially the same throttling effect. Here, too, an elastomer body 20 , which connects two elastomer rings 23 connected one behind the other in the axial direction in a non-positive and positive manner via an elastomer connecting section 16, which is preferably made of the same material, is supported on the inner wall of an annular support body 21 fixed in the pipeline 9 and can be supported elastically deform the pressure difference occurring due to the restriction of the fluid flow 7 . In contrast to the embodiment shown in FIG. 2, the axial limiting body 25 , which together with the elastomer part 20 defines the annular gap which causes the throttling action, is axially adjustable by an axially adjustable axis or spindle 26 . The cross-section of the annular gap through which the fluid flows, ie the setpoint of the controller, can thus be adjusted. With continuous water heaters, the required throughput rate can be between 5 and 15 liters per minute, which is achieved by adjusting the controller's setpoint.

The invention has the effect that even at high throttle pressures no hiss occurs.

A major advantage of the multi-stage flow regulator according to the invention is that the elastomer part 20 and the elastomer rings 3 , 3 'as well as the material of the carrier body (s) enable very cheap manufacture of the flow regulator designed according to the invention as a mass article.

Although the embodiments of the flow controller according to the invention shown in FIGS . 1 to 3 are carried out in two stages, it is clear to the person skilled in the art that with the same principles according to the invention according to the elastomer ring deformation principle, flow controllers with more than two stages can be realized.

Furthermore, the person skilled in the art immediately sees that the gap geometry the shape, diameter and length of the elastomer part and the carrier body or the carrier body different Can experience changes.

Claims (12)

1. Multi-stage flow controller according to the elastomer ring deformation principle, in which several elastomer rings connected in series and elastically deformable by the pressure of a fluid flowing through an annular gap regulate the amount of fluid flow ( 7 ) in a pipeline ( 9 ), characterized in that the flow controller ( 10 ; 11 ; 12 ) has means ( 1 , 2 ; 6 ; 16 ) for the non-positive and / or positive connection of the elastomer rings ( 3 , 3 ';13; 23 ) connected in series. 2. Flow controller according to claim 1, characterized in that the means ( 1 , 2 ; 6 ) for the non-positive connection of the elastomer rings ( 3 , 3 ') connected in series are formed by axially movable carrier bodies ( 1 , 2 ) in the pipeline ( 9 ) , which each carry one of the elastomer rings ( 3 , 3 ') and are designed so that they are forced to deform the elastomer rings connected in series as a result of the forces generated when the fluid flow ( 7 ) is throttled. 3. Flow controller according to claim 2, characterized in that the carrier body or bodies ( 1 , 2 ; 14 , 21 ) consist of a hard and rigid material with respect to the elastomer material of the elastomer rings. 4. Flow controller according to one of the preceding claims, characterized in that in the pipe ( 9 ) first limiting means ( 8 ) are provided for limiting the axial movement of the carrier body or bodies ( 1 , 2 ) in the flow direction ( 7 ) of the fluid. 5. Flow controller according to claim 4, characterized in that second limiting means for limiting the axial movement of the carrier body or bodies ( 1 , 2 ) against the flow direction ( 7 ) of the fluid are also provided. 6. Flow controller according to claim 1, characterized in that means for the non-positive and positive connection of the elastomer rings ( 13 ; 23 ) lying one behind the other are formed by an elastomer part ( 20 ) which has a connecting ring section ( 16 ) integral with the elastomer rings connects adjacent elastomer rings in a force-fitting and form-fitting manner. 7. Flow controller according to claim 6, characterized in that the or the connecting ring section (s) ( 16 ) is thin-walled or are, than the elastomer rings ( 13 ) connected thereto. 8. Flow controller according to claim 6 or 7, characterized in that the or the connecting ring section (s) ( 16 ) consists or consist of the same elastomer material as the elastomer rings ( 13 ). 9. Flow controller according to one of claims 6 to 8, characterized in that the elastomer part ( 20 ) has a tapered in the flow direction smooth outer wall and within an in the pipe ( 9 ) fixed annular support member ( 14 ; 21 ) is received so that it can be deformed axially and radially as a result of the throttling of the fluid flow ( 7 ), the connecting ring sections ( 16 ) also being deformed and the elastomer part ( 20 ) as a whole being supported by the correspondingly conically shaped inner wall of the carrier part ( 21 ). 10. Flow controller according to one or more of the preceding claims, characterized in that a multi-stage, axially in the pipe ( 9 ) within the flow controller ( 10 ; 11 ; 12 ) lying conical body ( 5 ; 15 ; 25 ) together with the series Elastomer rings define the annular gap. 11. Flow controller according to claim 10, characterized in that an axially adjustable axis or spindle ( 26 ) for the axial adjustment of the body ( 25 ) and thus for adjusting the fluid-flowed cross section of the annular gap is provided. 12. Flow controller according to one or more of the preceding claims, characterized in that two Elastomer rings are connected in series.