EP3227555A1

EP3227555A1 - Length compensation device

Info

Publication number: EP3227555A1
Application number: EP15841038.1A
Authority: EP
Inventors: Stephan Voit; Christian Kneidl; Hisham Kamal; Johann Kreidl; Thomas Streubel
Original assignee: Netzsch Pumpen and Systeme GmbH
Current assignee: Netzsch Pumpen and Systeme GmbH
Priority date: 2014-12-04
Filing date: 2015-12-03
Publication date: 2017-10-11
Also published as: CN107002668B; KR20170091687A; CN107002668A; DE102014117932B3; AU2015357838A1; RU2017123351A3; AU2015357838B2; WO2016086911A1; JP2017536507A; RU2017123351A

Abstract

The invention relates to a length compensation device (4), in particular for a progressive cavity pump with a rotor and an axially adjustable stator (2). The aim of the invention is to produce a length compensation device which compensates the length in a reliable and effective manner. According to the invention, the length compensation device (4) comprises at least one axially flexible support body (10, 12) in which a bellows body (16) which is associated with the support body (10, 12) and which is used to guide a conveying medium, is arranged.

Description

description

Length compensation device

The invention relates to a length compensating device, in particular for an eccentric screw pump with a rotor and an axially adjustable stator, wherein the length compensating device is associated with the stator. The invention further relates to an eccentric screw pump with a length compensation device.

The eccentric screw pump is one of the rotating positive displacement pumps whose pump section has a rotating part (rotor) and a fixed part (stator). The rotor is helically formed with a large pitch and flight depth and relatively small core diameter. The stator has one more thread and has twice the pitch length of the rotor. Between the rotor and the stator arise so pumping chambers, which move continuously from the inlet to the outlet side. Usually, the stator consists of an elastomeric body and a stator shell surrounding the elastomeric body. The elastomeric body effects a seal between the rotor and stator, which is generated by the fact that the inner contours of the stator are smaller than the outer contours of the rotor. Due to the bias creates an uninterrupted sealing line, which seals the successive delivery chambers and allows the construction of a delivery pressure.

To increase the life and for the purpose of adaptation to different operating conditions, solutions are known from the prior art, in which the elastic stator can be adjusted axially or readjusted. For example, DE 1303705 discloses an eccentric screw pump whose internal diameter of the stator can be narrowed by compression, wherein the housing inner wall and the outer surface of the elastic stator are conical and the stator is axially adjustable in the housing. Compensation elements are provided between pump housing and stator. This is intended to ensure that after prolonged operation wear and tear can be compensated by adjusting the stator in the axial direction.

An eccentric screw pump, in which the Statorinnenmaße occurring during operation circumstances can be adjusted, is known from DE 102005042559A1. For this purpose, the eccentric chord pump has a stator jacket and an elastic stator lining arranged therein, a stop being provided at both ends of the elastic stator lining for its axial limitation and means being provided at least at one end for changing the axial position of the stop. The setting of the stator jacket has a tensile or compressive force on the elastic stator lining, which changes the pressure on the rotor and thus the preload. The inner cross section of the lining is correctable.

In order to ensure an adjustment of the stator, means for its length compensation are required. In the known from the prior art solutions, for example, adjusting rings or shims are used, wherein the adjusting ring can also be arranged movably in an adjusting device to act positively on the stator lining during a pump operation.

The adjusting ring is in contact with the fluid, so means are required to ensure a seal between the adjusting ring and the pump housing or stator shell can. However, it would be desirable to have a compensating ^device , with which the change in length of the stator due to the axial adjustment can be compensated without parts of the compensation device come into contact with the fluid.

Also, the compensating device should preferably allow an axial guidance of the stator. However, known from the prior art solutions of the above type are but insufficiently suitable.

The invention is therefore based on the object to provide a length compensation device for guiding a pumped medium, with which a change in length, in particular of the stator of an eccentric screw pump, is effectively and safely possible.

This object is achieved according to the invention in that the length compensating device comprises at least one axially flexible supporting body in which a bellows body assigned to the supporting body is arranged to guide a conveying medium.

The invention is based on the consideration that a length compensation device or its parts are sensitive to dirt and therefore should not come into contact with the fluid. By using lubricants friction and wear could be kept low and a sealing effect could be increased. It should also be avoided as possible that operating materials such as oils and fats, for example, as a result seal wear and leaks, can get into the fluid.

This is achieved in that the length compensation device has a support body which does not come into contact with the conveyor medium. Within the support body, a bellows body is arranged, which is in contact with the conveying medium and through which the conveying medium can flow. In case of an axial movement, during expansion or compression of the bellows body, a support of the To reach bellows body, the support body is designed such that it can perform the axial movement of the bellows body with. This allows the entire length compensation device advantageously stretching or upsetting. For example, the bellows body can be in contact with the support body so that it can be supported directly on the support body.

However, the bellows body can also be coupled to achieve the support function via suitable means with the support body. For this purpose, the support body is preferably pressure-tightly coupled to the bellows body, such that a fluid chamber between the support and bellows body is formed, which supports the bellows body in the radial direction. The bellows body is thus exposed to no form-changing pressure load and thus remains substantially dimensionally stable.

In a preferred development, a pressure sensor assigned to the fluid chamber is provided for measuring the pump internal pressure. The pressure sensor is thus advantageously not in contact with the fluid and the measuring device, for example, can not clog. The fluid in the fluid chamber thus serves as a pressure transmitter for pressure detection and can also be used as overpressure protection.

The support body may be formed from one or more compensation elements, wherein the compensation elements are in turn pressure-tightly coupled together.

The bellows body is preferably made of an elastically deformable plastic, which elastically deforms when setting the stator. The support body may for example be integrally formed from a metallic material in the form of a bellows as compensation element. The bellows points a sufficiently high radial stiffness to accommodate acting on the bellows body pressure forces can.

Preferably, the bellows body has a funnel-like shape, which tapers towards the pump. This ensures that the bellows body assumes a flow-optimized shape even in the compressed state. Due to the special shape a compact design of the length compensation device is also possible because the bellows body can invagination when upsetting, which is not possible for example in a simple bellows and therefore requires comparatively more space in the axial direction in the compressed state.

Preferably, the length compensation device is arranged product outlet side. The arrangement and design of the pump-side drive elements can be so advantageously disregarded in the configuration of the device according to the invention.

In a particularly preferred embodiment, the support bodies are designed as a cylinder-piston pairing, such that the cylinder is pressure-tightly coupled as a first outer compensation element with the piston as a second inner compensation element by preferably recesses for sealing means are introduced in the piston. Pistons and cylinders are preferably designed such that the support body also serves as a guide means. As a result, a product-side support or guidance of the stator can be omitted.

In a preferred variant, the bellows body to Sollfaltstellen. With the help of Sollfaltstellen can advantageously the shape of the bellows body are influenced in its compression. The Sollfaltstellen can be generated, for example, in that the bellows body has a certain basic shape and / or by increasing or decreasing the material thickness at designated locations or areas. It is also conceivable attachment or insertion of auxiliary elements, for example in the form of a ring, which fluid chamber side to the

Bellows body runs around and a Sollfaltstelle relationship ^¬ forms a circumferential Sollfaltlinie.

In a particularly advantageous embodiment, the bellows body in the axial direction adjoining, around the bellows body around extending surfaces whose transitions form the Sollfaltstellen or Sollfaltlinien. The areal regions of the bellows body may for this purpose have different material thicknesses and / or be arranged at an angle to one another.

According to a preferred development, the support body for regulating fluid within the fluid chamber has at least one closable opening or a valve. Preferably, fluid is introduced into the fluid chamber via a valve, wherein air displaced by fluid can escape at an opposite point of the support body.

Preferably, the amount of fluid in the fluid chamber can be regulated in order to additionally influence the shape and the compression behavior of the bellows body. For this purpose, a control device may be provided, which makes it possible, in dependence on measured parameters of the pump, to increase the pressure in the fluid chamber or to lower it.

Particularly preferably, the bellows body is designed such that the length compensation device in addition we can ^¬ ken as a shut-off. For this purpose, the bellows body is formed of a highly elastic elastomer body. To shut off the pressure in ^¬ example, by means of a controllable pressure source in the fluid ^¬ chamber increases so far until the bellows body deformed and the Passage in the length compensation device seals. This ensures that, for example, assembly work on the pump or the conveyor system are made possible without additional shut-off devices.

The advantages achieved by the invention are in particular that the medium flowing through the bulkhead by means of Belbkörper, in particular by an elastomeric bellows body, does not come into contact with the support body, in particular not in contact with the sealing elements. A formed between the bellows body and the support body cavity can be filled with lubricating fluid, whereby seal and guide means are permanently lubricated protected against excessive wear. In addition, the use of a relatively thin-walled bellows body is made possible, characterized in that the bellows body is not exposed to any significant change in shape high pressure load, thereby further improving its folding behavior. By a funnel-like shape of the bellows body a particularly short design is possible because of the bellows body can collapse in itself. It is also advantageous that only the bellows body, as a wear part or component with certain physical or chemical properties and requirements in terms of the pumped medium, can be easily replaced without replacing the entire length compensation device.

Embodiments of the invention will be explained in more detail with reference to drawings. Show:

Figure 1 shows schematically the stator of an eccentric screw with

a length-compensating device connected on the pressure side, comprising a bellows body and a cylinder-piston pairing surrounding it as supporting body, FIG. 2 shows the length compensating device from FIG. 1 in the state of maximum deflection and the body of the bellows pushed on,

FIG. 3 shows the length compensation device from FIG. 1 in the state of maximum deflection and undipped bellows body;

FIG. 4 shows a length compensation device in the state of maximum

Deflection and inverted bellows body with circumferentially extending Sollfaltstellen,

Figure 5 is a length compensation device with a wave-like bellows body and

Figuer 6 a length compensation device with a wave-like bellows body and a pressure sensor.

Identical parts are provided with the same reference numerals in all figures.

FIG. 1 shows the stator 2 of an eccentric screw pump with a length compensation device 4 connected thereto on the end side. The stator 2 comprises an elastomer body 6, which is arranged inside a stator jacket 8, the stator 8 being coupled to a pump housing at its end, not shown here.

At the housing-side end of the elastomeric body 6 is fixed so that when adjusting the stator 2, the length compensation device 4 is activated. The representation of the length compensation device 4 shown in this figure allows both a negative and a positive axial movement, illustrated by the arrows shown. A cylinder-piston pairing serves as a two-part support body 10,12 of the length compensation device 4, wherein the piston 10 has circumferentially extending recesses 14, in which sealing means not shown here are arranged. With a positive movement during a setting process, the distance between the stator flange 18 and pump flange 20 increases, the elastomeric body is subjected to pressure and thus compressed. As a consequence, the pressure increases on the rotor (not Darge ^¬ asserted). In contrast, in a negative movement, the elastomer body is stretched and the pressure on the rotor is reduced.

Within the support body 10,12 an elastomeric bellows body 16 is arranged, which is clamped pressure-tight stator between a stator 18 and the piston 10 and a pressure-side pump flange 20 and the cylinder 12. On its side facing the bellows body 16, the piston 10 is provided in each case with a bevel on the end side in order to keep a mechanical load on the bellows body 16 as small as possible. A fluid chamber 22 formed between the bellows body 16 and the support body 10, 12 is filled with a lubricating fluid (not shown). Via a lower valve opening 24 in the cylinder 12, the fluid can be filled, wherein over an opposite opening 26 in the cylinder 12 air can escape during a filling process. So that no fluid can escape from the opening 26 and the desired support effect for the bellows body 16 can be achieved, the opening 26 is again closed pressure-tight after the filling process.

The bellows body 16 has seen in the axial direction different wall thicknesses, the wall thickness on the side of the pump flange 18 is lower than on the stator side. This results in a sufficiently high rigidity of the bellows body 16 in an area which should not or only slightly deform. An achieved change in shape upon activation of the length compensation device 4 thus occurs essentially only in a designated area.

A length compensation device 4 in a state of maximum positive and maximum negative deflection, is shown in Figures 2 and 3. The bellows body 16 shown in Figure 2 assumes the shape shown in the inverted state due to its basic shape and different material thickness. Fig. 3 shows the bellows body 16 in its basic form without elastic deformation within the length compensation device in the state of maximum positive deflection.

In FIG. 4, a length compensating device 4 is shown analogously to FIG. 2 without illustrated recesses for sealing elements, which comprises an inverted bellows body 16, but because of its particular configuration has Sollfaltstellen, in particular closed Sollfaltlinien 28 which extend in the periphery of the bellows body 16. The bellows body 16 has for this purpose in the periphery a plurality of surface portions 30, which cause the desired shape when compressing the bellows body 16. The surface portions 30 are arranged at least in the non-deformed state of the bellows body 16 at an angle to each other, wherein the transitions form the desired fold lines 28 from one surface to the adjacent surface. Via fluid (shown dotted) in the fluid chamber 22, between the bellows body 16 and the support body 10,12, the bellows body 16 is supported.

A bellows body 16 which is formed in a wave-like fashion in its basic form in a longitudinal section is shown in FIG. 5, which can be compressed and stretched due to its shape. The bellows body 16 is in places on the piston 10 and forms the fluid chamber 22 dividing chambers. To a flow between the individual To ensure or improve chambers can be introduced in the cylinder support body 22, in the region of the contact points with the bellows body 16, longitudinal recesses (not shown), which form flow channels and connect the individual chambers together.

FIG. 6 shows the length compensation device with a bellows body 16 which has a wave-like design as in FIG. 5, the fluid chamber 22 being coupled via the upper valve opening to a valve 34 and a pressure gauge 32 connected thereto. The valve 34 serves as a shut-off and damping valve. Instead, or in addition thereto, the fluid chamber 22 may be coupled via the upper valve opening to a controllable pressure source (not shown) to control or regulate the pressure in the fluid chamber 22 by means of a pressure sensor.

The device is preferably aligned with adjustable stators of an eccentric screw pump. By using a bellows body, which is stabilized in particular via a fluid chamber by means of a support body, advantageously causes, for example, designed as a support body guide means, which should be lubricated for safe operation, can not come into contact with the fluid. A funnel-like shape of the bellows body has a positive effect on the flow of the pumped medium and its folding behavior.

LIST OF REFERENCE NUMBERS

2 Stator of an eccentric screw pump

4 length compensation device

6 elastomer body

8 stator jacket

10 pistons as a support body (inner)

12 cylinders as support body (outer)

14 recesses for sealing elements

16 bellows body (elastomeric)

18 stator flange

20 pump flange

22 fluid chamber

24 valve opening

26 opening

28 desired folding lines

30 surface sections

32 pressure gauge

34 valve

Claims

claims

1. Length compensation device (4), in particular for use in an eccentric screw pump with a rotor and an axially adjustable stator (2), comprising at least one axially flexible support body (10,12) in which a supporting body associated bellows body (16) for guiding a Delivery medium is arranged.

2. Device according to claim 1, wherein the support body is pressure-tightly coupled to the bellows body to form a fluid chamber which supports the bellows body.

3. Apparatus according to claim 1 or 2, wherein the bellows body (16) is funnel-shaped. , Apparatus according to claim 3, wherein the bellows body (16) tapers towards the pump in a funnel-like manner.

5. Apparatus according to claim 1 to 4, wherein the bellows body (16) is arranged product outlet side.

6. Apparatus according to claim 1 to 5, wherein the support body (10,12) are formed as a cylinder-piston pairing.

7. Apparatus according to claim 6, wherein the support body (10,12) are formed as guide elements.

8. Apparatus according to claim 6 or 7, wherein the support body (10,12) have recesses (14) for means for sealing.

9. Apparatus according to claim 1 to 8, wherein the bellows body (16) Sollfaltstellen (28).

10. Apparatus according to claim 1 to 9, wherein for the regulation of fluid within the fluid chamber (22), a supporting body (10,12) has at least one closable opening (26) and / or a valve opening (24).

11. The device according to claim 1 to 10, wherein the amount of fluid in the fluid chamber (22) is adjustable.

12. eccentric screw pump with a length compensation element according to claim 1.