EP0994256A1 - Stator for Moineau pump - Google Patents

Abstract

An eccentric screw pump stator (1), comprising a removable elastomeric body (2) fitted with a conical outer part (3) surrounded by a conforming support casing (4), is new. The/each outer part is conical and its outside diameter decreases from the stator suction side to the pressure side, and the inside diameter of the support casing varies in accordance with the conicity of the outer part(s). A stator insert (1), for an eccentric screw pump, comprises a removable cylindrical elastomeric body (2) fitted with one or more outer parts (3) surrounded by a support casing (4), in which the elastomeric body has an internal axially extending pump cavity (5) for receiving a rotor and external peripheral projections (6) and/or recesses which engage corresponding recesses and/or projections of the outer part(s).

Description

The present invention relates to a stator for eccentric screw pumps and in particular a stator with a easily replaceable elastomeric inner part. Such stators are usually referred to as slide-in stators.

Stators generally consist of an elastomeric, essentially cylindrical molded part with an inner pump cavity, which is shaped in accordance with a single or multiple-flight worm and accommodates the rotor. The pump cavity is usually dimensioned such that the elastomer bears against the outside of the rotor with a prestress. The elastomeric inner part is usually enclosed in a stabilizing jacket.
The elastomer part wears out during conveyor operation. The wear can first be compensated for by re-tensioning the stator. After a certain period of operation, however, it is necessary to remove the stator and to replace the elastomer part or the entire stator.
For cost reasons and from an ecological point of view, it is advantageous to replace only the elastomeric inner part and not the stator as a whole.

The stators of the prior art, in which the elastomer part replaced in a relatively simple manner However, there are some disadvantages. For this counts for example that the elastomer body in the conveyor operation radially twisted and thereby the geometry of the pump cavity changes in an undesirable manner.

In addition, such occur on the upper and lower end faces Stators keep leaking. The stators can therefore only in general at low delivery pressures are used while they are not at high delivery pressures or are difficult to use.

Instead of stators with removable elastomer part therefore composite systems have been proposed in which the Hollow elastomer body with the stabilizing jacket connected is. For example, the elastomer body is in glued or vulcanized the coat. These composite materials have because of the better attachment better sealing of the elastomer part in the jacket, but can be correspondingly difficult in their individual Disassemble components. From an ecological point of view, this is from great disadvantage, since such stators are difficult to recycle are.

For recycling it is necessary to put the stator in the separate individual materials. One possibility is the melting of the elastomer from the steel jacket high temperature. The other is to put the stator in cool down liquid nitrogen and shrink the cold Press the elastomer part out of the jacket. Both methods require a considerable amount of energy, which is not desirable from an ecological point of view is, and are also complex and costly. In the event of the first-mentioned method can also be done by the high temperatures cause the decomposition of the Elastomer or the adhesive used come and thus further damage to the environment. Also the use of solvents or other chemicals to separate the elastomer body from the Coat is not desirable from an ecological point of view.

When using stators in practice, it has pointed out as a further disadvantage that, in particular for pumps with vertical or steep stator with the suction opening facing upwards, the stator often is insufficiently clamped. Becomes out of ignorance or lack Care of the stator only on the suction side of the Pump with the clamping device located there, for example a clamp, clamped, not against it on the Pressure side, the pressure required does not exceed the entire length of the stator built. This will Material flow restricted and the performance of the pump decreases.

If the stator is only or predominantly only on the suction side excited, the inflow of material is obstructed and the required Pressure cannot build up. Desirable is therefore a stator that is uniform over its entire length can be excited.

A stator, which largely has the disadvantages described above avoids, is in German utility model No. 295 16,885. The stator has an elastomeric Inner body with elevations arranged on the outer surface on. These surveys are in recesses from stabilizing outer parts, which from the outside to the Elastomer body can be created. The stabilizing External parts are covered by a tubular jacket with a cylindrical Outside contour held together, which over the Outer parts is pushed. To re-tension the stator the cylindrical jacket used initially by another cylindrical mantle replaced by a lesser Has inner diameter than the first jacket. A good Tightness on the suction and pressure side is ensured by the special Design of the end faces of the elastomer body achieved. To increase the tightness are on both ends of the stator specially designed O-ring Flanges provided.

The stator described in utility model 295 16 885 is Starting point for the present invention. This stator has become difficult even as often found on construction sites, proven. A disadvantage consists, however, in that the winding of the cylindrical A considerable amount of force is required for the jacket. The same applies when removing the jacket from the worn one To be able to replace the inner elastomer body or to tighten the stator by putting on a narrower jacket. Are the components dirty, too, like this can easily be done on construction sites even with suitable tools such as combination wrenches or ring spanners considerable difficulties.

The invention is therefore based on the object of providing a stator which has a removable elastomeric inner part which can be removed from the stator at the place of use of the stator as far as possible without the aid of tools. The stator should also be easy to re-tension and have a good seal even under difficult operating conditions.

The problem is solved with the stator according to claim 1. Appropriate and preferred embodiments result itself from the subclaims.

The invention thus relates to a slide-in stator for eccentric screw pumps, which comprises a removable elastomer body with an essentially cylindrical basic structure, as well as at least one outer part which bears against the outer surface of the elastomer body and a support jacket which surrounds the at least one outer part. A pump cavity for receiving a rotor runs in the interior of the elastomer body in the axial direction. This pump cavity can be shaped in the usual way in the manner of a single or multiple-flight screw. Elevations and / or depressions are present on the outer periphery of the elastomer body, which engage in a form-fitting manner in corresponding depressions and / or elevations of the at least one outer part. The at least one outer part is in turn surrounded by the support jacket, which holds the insertion stator together.
According to the invention, the at least one outer part is conical and in such a way that its outer diameter increases from the suction side of the stator to its pressure side. In accordance with the taper of the outer part or the outer parts, the inner diameter of the support jacket changes, so that the inner surface of the support jacket rests essentially on the at least one outer part over its entire surface.

According to the invention, it has at least one outer part, which rests on the elastomer body, on the suction side of the stator has a smaller outer diameter than on the Pressure side of the stator. The outside diameter preferably increases of the at least one outer part from the suction side - that is the side on which the medium to be pumped enters the stator enters - towards the print side continuously. Same thing applies accordingly to the inner diameter of the support jacket, which surrounds the at least one outer part.

The taper is expediently chosen so that the Support sheath in the usual conditions of use in the desired Position remains and does not shift.

The taper can therefore vary depending on the pressure conditions inside of the stator during operation so that it self-locking of the support jacket on the outer part is coming.

Although the stator is very stable during operation and the support jacket sits firmly on the at least one outer part during operation, the stator can be disassembled into its individual components with little effort in order to replace the elastomer body. For this purpose, only the support jacket has to be pushed or knocked away in the direction of the suction side of the stator. Because of the decreasing outer diameter of the at least one outer part towards the suction side, this is very easily possible. It is usually sufficient to open the pressure-side edge of the support jacket on a projection in order to detach the support jacket from the at least one outer part. No special tool is required to disassemble the stator according to the invention into its individual components and to replace a worn elastomer part.
Assembling the stator and fitting the support jacket from the suction side is also easy and requires little effort.

The conical design of the outer parts and support jacket also makes it easier to re-tension the stator. In the case of Utility model No. 295 16 885, the stator will be used tubular support jackets retightened in that a first support jacket with another support jacket a smaller inner diameter is replaced. To do this so the first support jacket completely from the outer parts removed and replaced by the second support jacket. Such is the case with the stator according to the invention Replacement of the support jacket is not necessary. Becomes a tubular support jacket used, the inside diameter increases from the suction side to the pressure side of the stator, the support jacket only has to continue towards the Printing side advanced on the at least one outer part become. Characterized in that the outer diameter of the at least an outer part according to the invention from the suction side towards the pressure side also increases by moving of the support jacket, the outer parts continue to stack moves and thus the pump cavity is reduced. At a continuous increase in the outside diameter of the at least an outer part or the inner diameter of the support jacket is a continuous narrowing of the pump cavity and thus a stepless and even one Retensioning of the stator possible. Neither can be missed, both pressure and suction side of the stator to tighten, still it can because of the tapered formation confuse the stator sides.

Move around the support jacket on the at least one outer part to be able to, this is suitably shorter than that at least one outer part on which it rests. In practice has a 20% shorter length of the support jacket compared to the length of the at least one outer part proven.

To push the support jacket onto the at least one To facilitate the outer part, the support jacket expediently in its pressure side area on the inside edge a curve or chamfer.

Because of the retensioning option described above, it is preferred, the support jacket of the stator according to the invention to be tubular. In the case of an essentially uniform wall thickness of the jacket and with continuous the support jacket therefore has an increasing inside diameter essentially the shape of a truncated cone. It is however, in principle it is also possible to change the support jacket with variable Form wall thickness, so that for example the outer shape is essentially similar to a cylinder. To secure the stator against rotation during operation, the outer contour of the support jacket also in the form of a polygon be designed so that the stator against rotation during operation can be clamped. Alternatively, it is possible one or. on the outer surface of the support jacket attach multiple protrusions or brackets that the serve the same purpose. These anti-rotation locks can for example by contacting the tie rods of a construction machine be attached.

As an alternative to a tubular jacket, a jacket can also be used in the form of a clamp. The clamp can, for example, like a hose clamp be constructed and a truncated cone slit in the longitudinal direction include. Such is used for retensioning Sheath not axially on the least moved an outer part, but it remains in the predetermined position and is by tightening the jig tightened.

The support jacket of the stator according to the invention is made Appropriately made of a dimensionally stable, unbreakable material. This can be a suitable plastic, for example Be hard rubber. However, the support jacket preferably exists of metal and in particular of steel.

Suitable as material for the at least one outer part also a dimensionally stable material such as metal, hardwood or a suitable plastic. For example, in particular Polypropylene and phenolic resin-soaked hardwood such as OBO solid wood can be called.

The elastomer body can be made from those previously suitable for this Materials are made. These are elastomeric plastics such as rubber, natural or synthetic rubber. For example, Polyurethane.

From its basic structure, the elastomer body can essentially resemble that of utility model 295 16 885 is described. According to the surveys and / or Wells of the elastomer body described there are at least the wells and / or elevations formed an outer part, which on the elastomer body lies on. For example, the surveys in Elastomer body and / or outer part as elongated webs or Knobs of any shape should be formed. Alternatively, you can the elevations are formed in the manner of a thread that engages positively in a corresponding counter thread.

In contrast to the utility model 295 16 885, however preferred, the height of the elevations on the elastomer body to adapt to the taper of the outer parts of the stator. Appropriately therefore takes the height of the surveys towards the pressure side end of the stator in such a way that the surveys are essentially in one plane with the Complete the adjacent outer surface of the outer part. The surfaces of the are therefore in the assembled state Elevations also on the support jacket. This ensures that the stator according to the invention even at very high pressures from e.g. 50 bar or more can be used.

It is particularly preferred that the elastomer body at least has a feather key-like elevation, which in runs essentially in the axial direction and in a groove-like Slit in at least one outer part in a form-fitting manner intervenes. Such a configuration particularly prevents effective twisting or axial slipping of the elastomer body. To ensure good tightness at the front To achieve the stator according to the invention extends the groove-like slot preferably not over the entire Length of the at least one outer part, and has accordingly the feather key-like elevation is less than that of the elastomer body.

The stator can be tightly sealed at the end when the elastomer body is at its top and / or its lower end face a flange-like Has a head start. The at least one outer part is then Conveniently designed so that it is attached to the front flange-like projections of the elastomer body are adjacent. The at least one outer part expediently has one correspondingly lower height than the elastomer body. The flange-like projection is preferably serrated or O-ring shaped.

Flange-like projection and that are particularly preferred at least one outer part designed so that the outer part engages in an undercut of the flange-like projection. The flange-like protrusion takes in its Thickness in the radial direction from the inside to the outside. Corresponding is that at least one outer part on one or bevelled on both ends so that the inner edge in protrudes axially beyond the outer edge. To this Way is prevented that the flange-like projection when the stator is operated by the one on the stator Pressure is pulled radially inwards and so to the Leakage occurs at the end faces. The undercut also fixes the outer part to the elastomer body and prevents both parts from falling apart before the Support jacket is put on.

Furthermore, it is preferred according to the invention, at least two To use external parts that are essentially in the form of a have a truncated cone shell divided in the longitudinal direction. Two longitudinal truncated cone segments are preferred used. However, it is also possible to have 3, 4 or more to use such longitudinal segments. These longitudinal segments essentially completely surround the elastomer body.

However, to enable the stator to be retensioned, it is expedient, a small between the individual longitudinal segments To leave longitudinal gap, which when re-tensioning the Stator is narrowed. This narrows that of the outer parts enclosed space, and the elastomer body is pressed more firmly to the rotor.

If several longitudinal segments are used as outer parts, you can these either separated from each other on the elastomer body put on and then fixed with the support jacket. Alternatively, it is possible to pivot the outer parts connect with each other. You can do this, for example Serve hinges.

In addition to the taper of the outer surface, too the inner region of the at least one outer part is conical be trained. A corresponding measure is already described in utility model 295 16 885. The Reduction of the inner diameter of the at least one External part from the suction side of the stator to the stator Pressure side leads to a stronger bias towards on the pressure side and thus to build up a pressure gradient inside the stator. By appropriate choice of Internal taper of the at least one outer part of the invention Stator can the pressure conditions in the stator be influenced in a targeted and positive manner.

To fix the support jacket or to prevent the stator is too tight, can be in the pressure area of the at least one outer part over the outer Exceptional projection, for example a stop flange, be present, which prevents the Support jacket pushed too far towards the pressure side can be.

As already mentioned, the outer parts can be made of plastic such as polypropylene. Appropriately it is manufactured using an injection molding process. In this case, however, it is very difficult to get the right one to manufacture thick-walled parts accurately. To still achieve that the at least one outer part evenly rests on the elastomer body and good surface contact can be obtained in the pressure-side area of the outer part at least one extending in the axial direction Slot. This slot increases the adaptability between the elastomer body and the outer part.

The slot can, for example, from the pressure side edge of the at least one outer part up to about two thirds of the Length of the outer part run. In addition or as an alternative to the longitudinal slots Shorter slots are present from the print edge to a depression, which is used to hold a Elevation of the elastomer body is determined.

Fig. 1

einen Längsschnitt durch einen erfindungsgemäßen Einschubstator;

Fig. 2

einen Elastomerkörper eines erfindungsgemäßen Stators in Seitenansicht;

Fig. 3

ein Außenteil eines erfindungsgemäßen Stators;

Fig. 4

einen Elastomerkörper eines erfindungsgemäßen Stators mit aufgesetztem Außenteil;

Fig. 5

einen Elastomerkörper mit einem anderen Beispiel eines aufgesetzten Außenteils; und

Fig. 6

eine Schnittansicht eines Elastomerkörpers mit zwei aufgesetzten Außenteilen entlang der Linie A-A in Fig. 5.

The invention will be explained in more detail below using the example of drawings. In it show schematically

Fig. 1

a longitudinal section through an insertion stator according to the invention;

Fig. 2

an elastomer body of a stator according to the invention in side view;

Fig. 3

an outer part of a stator according to the invention;

Fig. 4

an elastomer body of a stator according to the invention with attached outer part;

Fig. 5

an elastomer body with another example of an attached outer part; and

Fig. 6

5 shows a sectional view of an elastomer body with two outer parts attached along the line AA in FIG. 5.

1 shows an example of a device according to the invention Stator in longitudinal section in the area of the central axis of the stator. The insertion stator 1 comprises an elastomer body 2 and two outer parts 3. Each of the two outer parts 3 surrounds the elastomer body 2 essentially semicircular The sectional view shows an area in which is groove-like on both sides in one of the outer parts 3 Longitudinal slots are present, so that from the outer part only the front areas are visible. The Outer diameter of the outer part 3 increases from the suction side of the stator in the direction of the pressure side continuously to. The suction side of the stator is the side at which the medium to be conveyed enters the stator, is in the illustration above, the printed page in lower part of the figure. The outside diameter is corresponding d1 smaller on the upper face of the outer part than the diameter d2 in the pressure side edge area of the Outer part.

The outer part 3 lies with its entire inner surface the outer surface of the elastomer body 1. The elastomer body 2 is essentially cylindrical. In his Interior extends in the axial direction of the pump cavity 5, here like a catchy snail is trained. On the cylindrical outer surface of the Elastomer body 2 are a total of four feather keys Elevations 6 evenly over the outer circumference of the Distributed elastomer body. The parallel keys 6 engage positively in the groove-like recesses 7 of the two External parts 3 a. The height of the parallel keys decreases from the Suction side towards the pressure side. The height changes in such a way that the surface of the feather keys 6 ends with the outer surface of the outer parts 3.

On both ends of the elastomer body 2 are flange-like Projections 8 available. These projections worry for a good seal on the front of the stator. The essentially O-ring-shaped flanges 8 are designed that their thickness is radial from the inside out to change. As can be seen in Fig. 1, the thickness of the Flanges 8 radially outwards. According to the increase in thickness the flanges are the front edge areas the outer parts 3 beveled. The slope 9 runs so that the radially inner edge of the outer part 3 over protrudes the radially outer edge. This arrangement of Flanges 8 and 9 slope of the outer parts 3 has one hand the advantage that the outer parts 3 already on the Hold the elastomer body 1 before the support jacket 4 is pushed onto the outer parts. On the other hand prevented this training that the flanges 8 when operating the Stator radially by the pressure applied to the stator be pulled inside and so there are leaks on the end faces arise.

After placing the outer parts 3 on the elastomer body the support jacket 4 is pushed on. This is through the bracket 13, which on both sides of the support jacket protrudes, relieved. The bracket can also on the tie rod be attached to a construction machine, in order to secure the stator secure against twisting.

The further the support jacket 4 is pushed onto the outer parts and advanced toward the print side, the more further the two outer parts 3 are pushed towards each other. This increases the tension with which the Elastomer body on the rotor located in the pump chamber 5 is pressed. The rotor is for the sake of clarity not shown. Due to the continuous increase in Outer diameter of the outer side parts 3, the tension, with which the elastomer body rests on the rotor, continuously can be set. First, there is a preload set so that the rotor turns normally leaves. Has the pump cavity 5 through wear during of the operation of the rotor enlarged, the stator can can be easily re-tensioned in that the support jacket pushed further towards the pressure side becomes.

Is the elastomer body 2 worn so far that it is replaced needs to be, only the support jacket 4th removed from the outer parts towards the suction side to become. Because of the taper of the outer parts 3 and the supporting jacket 4 requires little force. A light blow on the pressure side edge area of the jacket 4 or on the bracket 13 is in the Usually sufficient. After removing the support jacket 4 the two outer parts 3 are removed from the elastomer body. Then they are put on a new elastomer body put on, and the support jacket 4 is from the suction side pushed onto the outer parts. To make this easier is the pressure side edge of the support jacket 4 with provided a rounding 14.

Fig. 2 shows the elastomer body 2, which in the in Fig. 1 stator shown was used, in side view. The course of the pump cavity 5 and the undercut in the flange-like projections 8 on both ends is indicated by dashed lines. To the one on the right and two of the four on the left Feather keys 6 can be seen that the height of the The suction side changes continuously towards the pressure side, namely enlarged. This ensures that the Surface of the parallel keys 6 on the inside of the support jacket 4 is present. This ensures high pressure resistance of the stator according to the invention.

FIG. 3 shows one of the two outer parts 3 of the one in FIG. 1 shown stator. The outer part essentially has the shape of a truncated cone shell halved in the longitudinal direction. The outer diameter of the outer part is reduced from the pressure side towards the suction side of the stator (d2> d1). This is due to an increase in wall thickness reached towards the pressure side. The inner surface the outer part 3 corresponds essentially to a halved Cylinder. The recesses 7 in the outer part correspond in position and shape the corresponding key-like Elevations 6 in the elastomer body 2.

4 and 5 each show elastomer bodies with attached Exterior parts in side view. The elastomer body is as far as it is covered by the outer parts, with dashed lines Lines indicated. 4 and 5 is the View of one of the two outer parts 3 to see which one surrounds the elastomer body essentially semicircular, while the second outer part is on the rear Side of the elastomer body is placed in mirror image and is covered by the first outer part.

Both outer parts 3, which are shown in FIGS. 4 and 5, correspond essentially to the outer part shown in FIG. 3. In addition to the latter, however, one or more slots are present in the pressure-side area of the outer part.
4, the outer part 3 has a slot 10 which extends from the pressure-side edge region of the outer part to the central groove-like opening 7. In the outer part 3 according to FIG. 5 there are two additional, longer slots 11 which are arranged on both sides of the middle groove-like slot 7 and approximately in the middle between this middle groove-like slot and the two side slots 7 of the outer part. The slots 11 each extend from the pressure-side edge region to approximately the upper third of the outer part 3.

The slots 10 and 11 each serve to ensure a form-fitting contact between the elastomer body 2 and the outer part 3 during operation of the stator.
If a plastic such as polypropylene is used in the manufacture of the outer parts and the outer parts are produced, for example, in an injection molding process, it is difficult to manufacture the outer parts so accurately that a positive engagement of the elastomer body with the outer parts is ensured. The additional slots 10 and 11 act as expansion joints, which allow the outer parts in the pressure side area increased flexibility and adaptability to the elastomer body. It is particularly in this area on the pressure side that the accuracy of fit is of particular importance, since this is where the pressure of the stator is greatest. While there is a pressure of 0 bar on the suction side, the pressure on the pressure side can increase linearly up to about 60 bar. In the suction-side area, the requirements for the accuracy of fit of the stator are therefore lower. By making the slots 10 and 11 in the pressure-side area of the outer parts over about two thirds of their total length, an excellent fit can be achieved without taking away the inherent stability of the outer parts, since there are no slots in the upper third.
The number and length of the slots, which can also be shorter than two thirds of the total length, can be varied as desired and according to the respective requirements. However, care should be taken that the inherent stability of the outer parts is not reduced too far.

Fig. 6 shows a sectional view taken along the line A-A of the 5 arrangement of the elastomer body and Outside parts. With the circle and oval in the center of the figure the eccentricity of the pump cavity is to be indicated. The arrows labeled 11 illustrate the position the longitudinal slots 11.

In Fig. 6 it can be seen that the two outer parts 3 with their longitudinal edges do not directly abut each other, but are separated from each other by a gap 12. This Gap 12 enables the stator to be re-tensioned. Emotional if you close the two outer parts towards each other, it narrows the interior between the two parts and thus that of Elastomer body enclosed pump cavity 5. On this The elastomer body can again be attached to the (not shown) Rotor are pressed. Retensioning can as described, either by advancing one tubular support jacket towards the pressure side there or by tightening a clamp.

Claims (25)

Slide-in stator (1) for eccentric screw pumps, which comprises a removable elastomer body (2) with an essentially cylindrical basic structure, at least one outer part (3) lying against the outer surface of the elastomer body and a support jacket (4) surrounding the at least one outer part, in which the elastomer body in its interior has an axial pump cavity (5) for receiving a rotor and on its outer circumference elevations (6) and / or depressions which engage in corresponding depressions (7) and / or elevations of the at least one outer part (3) in a form-fitting manner ,
characterized by that the at least one outer part (3) is conical, such that its outer diameter increases from the suction side of the stator to its pressure side (d1 <d2), and that the inner diameter of the support jacket (4) changes substantially in accordance with the taper of the at least one outer part. Stator according to claim 1,
characterized by that the elevations in the elastomer body (2) and / or outer part (3) are designed as elongated webs or knobs. Stator according to claim 1,
characterized by that the elevations in the elastomer body (2) or outer part (3) are designed in the manner of a thread which engages in a corresponding mating thread in the at least one outer part (3) or the elastomer body (2) in a form-fitting manner. Stator according to claim 1,
characterized by that the at least one outer part (3) has at least one groove-like slot (7) running essentially in the axial direction and the elastomer body has at least one feather-like elevation (6) which can be received in the slot. Stator according to claim 4,
characterized by that the at least one groove-like slot (7) does not extend over the entire length of the at least one outer part and the at least one key-like elevation (6) does not extend over the entire length of the elastomer body (2). Stator according to one of claims 1 to 5,
characterized by that there are at least two outer parts (3) which essentially have the shape of a truncated cone shell which is divided in the longitudinal direction, for example halved, and which essentially enclose the elastomer body. Stator according to one of claims 1 to 6,
characterized by that the elastomer body (2) on its upper and / or its lower end face has a flange-like projection (8) and that the at least one outer part (3) has a lower height than the elastomer body and is so long that it is on the end face of the or flange-like projections of the elastomer body are adjacent. Elastomer body according to claim 7,
characterized by that the flange-like projection (8) is serrated or O-shaped. Stator according to claim 7 or 8,
characterized by that the at least one flange-like projection (8) is designed such that its thickness increases in the radial direction from the inside to the outside. Stator according to claim 9,
characterized by that the at least one outer part (3) is chamfered (9) on one or both end faces so that the inner edge protrudes axially beyond the outer edge. Stator according to one of claims 1 to 10,
characterized by that the inner diameter of the at least one outer part (3) decreases from the suction side of the stator to its pressure side. Stator according to one of claims 1 to 11,
characterized by that the at least one outer part (3) in the pressure-side area has at least one protrusion projecting beyond the outer circumference, for example a stop flange. Stator according to one of claims 6 to 12,
characterized by that the outer parts (3) are pivotally connected to one another, for example by hinges. Stator according to one of claims 1 to 13,
characterized by that the at least one outer part (3) has one or more slots (10, 11) running in the axial direction in its pressure-side region. Stator according to claim 14,
characterized by that the at least one slot (11) extends from the pressure-side edge to approximately two thirds of the length of the outer part. Stator according to claim 14,
characterized by that the at least one slot (10) extends from the pressure-side edge to a recess (7) which is intended to receive an elevation (6) of the elastomer body (2). Stator according to one of claims 1 to 16,
characterized by that the elevations (6) of the elastomer body (2) increase in height in the direction of the pressure-side end of the stator and are essentially level with the adjacent outer surface of the at least one outer part (3). Stator according to one of claims 6 to 17,
characterized by that the outer parts (3) arranged around the elastomer body (2) do not directly abut one another with their longitudinal edges, but rather leave at least one gap (12) and do not completely cover the elastomer body. Stator according to one of claims 1 to 18,
characterized by that the support jacket (4) is tubular. Stator according to one of claims 1 to 19,
characterized by that the support jacket (4) has one or more projections or brackets (13) on its outside. Stator according to one of claims 1 to 20,
characterized by that the support jacket (4) is provided at its pressure-side end on the inner diameter with a circumferential chamfer or rounding (14). Stator according to one of claims 1 to 21,
characterized by that the support jacket (4) is a clamp. Stator according to one of claims 1 to 22,
characterized by that the support jacket (4) consists of a dimensionally stable, unbreakable material, preferably of metal and in particular of steel. Stator according to one of claims 1 to 23,
characterized by that the at least one outer part (3) consists of a dimensionally stable material such as metal, hardwood or plastic and in particular of polypropylene or OBO hardwood. Stator according to one of claims 1 to 24,
characterized by that the elastomer body (2) consists of rubber, natural or synthetic rubber.

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