EP1227243A2 - Stator for a Moineau pump - Google Patents

Abstract

The stator consists of a removable elastomer body (1) with a hollow pump cavity for a rotor and a surrounding support jacket in the form of a truncated cone. The external surface of the elastomer body is received positively in the support jacket. It has a projection (3) extending over the outer surface. There is a corresponding recess in the support jacket.

Description

The present invention relates to a stator for progressing cavity pumps and in particular a stator with an easily replaceable elastomeric inner part. Such stators are usually referred to as insertion stators.

Stators generally consist of an elastomeric, essentially cylindrical molded part with an internal pump cavity that corresponds to a single or multi-flight screw is shaped and receives the rotor. The pump cavity is usually dimensioned so that that the elastomer is pre-loaded on the outside of the rotor. The elastomeric inner part is in usually enclosed in a stabilizing jacket.

The elastomer part wears out during conveyor operation. After a certain period of operation it is therefore necessary to remove the stator and replace the elastomer part or the entire stator.

In composite systems in which the elastomer body is firmly connected to the stabilizing jacket the stator must be replaced as a whole. This is not just for cost reasons, but also disadvantageous from an ecological point of view, since stators of this type are difficult to recycle are.

For recycling, it is necessary to separate the stator into the individual materials. A It is possible to melt the elastomer out of the steel jacket at high temperature. The other is to cool the stator in liquid nitrogen and that in the cold to squeeze the shrunk elastomer part out of the jacket. Both methods require one considerable energy expenditure, which is not desirable from an ecological point of view, and are also complex and costly. In the case of the first-mentioned procedure, it can do so Furthermore, the high temperatures cause decomposition of the elastomer and the used adhesive come and thus further damage to the environment.

The use of solvents or other chemicals to remove the The elastomer body from the jacket is not desirable from an ecological point of view.

When using composite system stators, however, it is an advantage that the elastomer body is firmly connected to the support jacket. The elastomer body also moves when Operation of the stator practically not. In contrast, with insert stators of the prior art, in Which of the elastomer bodies is only loosely inserted into the jacket has often been the problem observed that the elastomer body rotates radially in the conveying operation and thereby changes the geometry of the pump cavity in an undesirable manner. In addition, Leakages are frequently observed on the upper and lower end faces of such stators. The Stators could therefore generally only be used at low delivery pressures, not against it at high delivery pressures.

The applicant has therefore proposed stators in which the elastomer Inner part is secured against twisting in the conveyor operation and which even at high delivery pressures lead to a good seal. This is possible because the insertion stator is next to the elastomer body and the outer support jacket has stabilizing outer parts, which enclose the elastomer body and which in turn held together by the support jacket become. The elastomer body has elevations on its outer peripheral surface on which form-fitting in corresponding recesses of the stabilizing outer parts intervention. This positive connection between the elastomer body and the stabilizing one External parts prevent the elastomer body from twisting during conveying.

A corresponding slide-in stator, which can also be re-tensioned to expand the To be able to compensate for the pump cavity after a certain delivery period is, for example described in DE 19847406 A. The essentially hollow cylindrical elastomer body this stator has several key-like elevations on its outer circumferential surface, the height of which increases continuously from the suction side towards the pressure side. The The elastomer body is surrounded by two or more stabilizing outer parts, in which the key-like elevations of the elastomer body corresponding depressions are present. The stabilizing outer parts, which surround the elastomer body, have an outer contour, which corresponds to that of a truncated cone. The continuous increase in diameter of the External parts from the suction side to the pressure side allow the stator to be re-tensioned. For this purpose, the support jacket, which surrounds the stabilizing outer parts and which the Has the shape of a truncated cone, only further towards the pressure side of the Stator advanced so that the stabilizing outer parts approach each other and the the elastomer body enclosed by them is compressed.

The conical design of the support jacket and the stabilizing outer parts thus serves Retensioning the stator, while the elastomer body itself is basically a cylindrical one Has shape and only the feather-like elevations of the conical design of the External parts and the support jacket are adjusted.

The conical stator described above enables easy replacement of the elastomer Inner part with good tightness even at high delivery pressures. However, it poses certain Requirements for the operating personnel, on the one hand, with the relatively large number of individual parts connected (elastomer body, at least two stabilizing outer parts, support jacket and rotor) and, on the other hand, the fact that the support jacket can be moved freely the exact setting of the desired delivery pressure on the stabilizing outer parts is not always easy.

There was therefore a need for a slide-in stator that was easy to use with a minimum of handling individual parts, with easy interchangeability of the elastomeric inner part a rotation of the elastomer body during the conveyor operation is reliably prevented and thus leads to a good seal even at high delivery pressures, and at which the setting uniform pressure values and delivery volumes is possible in a simple manner.

The object of the invention is to provide such a plug-in stator.

The problem is solved with the insertion stator according to claim 1. Further embodiments can be found in the subclaims.

The insertion stator according to the invention for eccentric screw pumps consists of a removable one Elastomer body with an axial pump cavity to accommodate a rotor. This pump cavity can basically be used in any state of the art Technically usual manner. The elastomer body is essentially conical and includes an outer surface that is substantially in the shape of a truncated cone having. This conical elastomer body is supported by a tubular support jacket surrounded, the cavity of which has the shape of a truncated cone. The side with the lesser In the installed state of the stator, the opening diameter faces the suction side, the opening with the larger diameter is arranged towards the pressure side. elastomer body and support jacket are formed so that the frustoconical outer surface of the elastomer body and bear against the inner surface of the support jacket in a form-fitting manner.

In contrast to the prior art, the elastomer body of the invention is missing Insertion stator the elevations on the outer peripheral surface. This also stabilizes External parts can be dispensed with, in the recesses the elevations of the elastomer body were recorded so as to twist the elastomer body during operation of the stator prevent. It has now been found completely surprisingly that such elevations on the outer peripheral surface of the elastomer body are not required to twist the elastomer body to prevent during operation. Rather, a twisting of the elastomer body even with a completely smooth outer circumferential surface that has no anti-rotation lock in the form of Has elevations or depressions, solely by the conical shape of the outer peripheral surface can be prevented safely.

The conical configuration of the support jacket and the elastomer body does not serve Retensionability of the slide-in stator, as is the case with the conical design of the support jacket and the stabilizing outer parts in the stator, which is described in DE 19847406 A is described. Rather, it creates the possibility of the elastomer body without the application of great force to fit tightly into the pipe jacket and also easily out of it to be able to remove. After inserting the elastomer body into the support jacket from the outer surface of the truncated cone of the elastomeric body lies towards the larger and smaller opening over a large area on the inner surface of the support jacket. After turning the rotor into the Pump cavity and during the delivery operation of the eccentric screw pump, this becomes Truncated cone outer peripheral surface practically all over and evenly against the inner surface of the support jacket. The clamping effect generated is so great that a twisting of the Elastomer body is excluded during the conveyor operation. Ledges on the Outer peripheral surface of the elastomer body or other means that twist the Preventing the elastomer body during operation is therefore unnecessary. In fact, that by the large-area pressing of the elastomer body on the support jacket a clear better clamping effect is achieved than in the case of key-like elevations State of the art stators have been observed. The insertion stator according to the invention leads therefore with a significantly simplified structure to an at least comparable tightness.

As already mentioned, it is not the aim of the invention to create a conical structure To create re-tensioning of the stator. Rather, it is preferred if the elastomer body and support jacket are positioned in a predetermined position to each other. Both the elastomer body as well as the support jacket therefore have positioning aids that ensure that both parts are arranged in the desired orientation to each other. These consist of step-shaped stops at any point on the outer surface of the elastomer body and the inner surface of the support jacket can be arranged. So the elastomer body has for example in its pressure-side end area, one over its outer surface protruding projection, which is expediently formed in a circular manner. Complementary there is a corresponding recess in the pressure-side end region of the support jacket or protuberance for receiving the projection of the elastomer body. This Indentation or protuberance can on the one hand by opening the supporting jacket wall to the outside or can be achieved by thinning the wall thickness. The stops thus formed prevent the elastomer body from being pushed too far into the support jacket.

In order to prevent the elastomer body from rotating in the support jacket, it has proven to be Proven to be the diameter of the elastomer body compared to the diameter of the support jacket to enlarge something. The outer diameter of the elastomer body is therefore expedient in the area of its truncated cone outer surface larger than the corresponding one Inner diameter of the support jacket where the elastomer body in the installed state with the Support jacket comes into contact. In this way, the elastomer body is already under tension on the inner surface of the support jacket, even before the rotor enters the pump cavity is screwed in and thus further increases the clamping effect.

Advantageously, the elastomer body and support jacket have the same angle of inclination, that is same continuous increase in thickness over its length. At an angle of inclination here the angle between the inner surface of the support jacket or the outer surface of the Understand the elastomer body to a plane perpendicular to the respective axial direction be, the angle of inclination is measured in the direction of the pressure side and so is greater than 90 °. Suitable angles of inclination are, for example, between 91 and 95 °.

Alternatively, it is also possible that the angle of inclination in the elastomer body is different from the angle of inclination of the support jacket deviates somewhat in order to create a gradient of the contact pressure. If, for example, the angle of inclination in the elastomer body is somewhat larger than the angle of inclination of the support jacket, the pressure with which the elastomer applies to the rotor increases is pressed slightly from the suction side to the pressure side.

In order to increase the tightness of the stator on the end faces, it has proven to be useful the elastomer body on its suction side and / or its pressure side with a flange-like To provide a head start. These flange-like projections serve for a tight connection to the top or bottom flange of the eccentric screw pump in which the stator is installed shall be.

According to the invention, it is preferred if the elastomer body has a greater length than the support jacket having. The shorter length of the support jacket does not have the purpose, however to be able to move the stator in the axial direction of the elastomer body. Much more the support jacket is appropriately dimensioned so that it is installed in the Eccentric screw pump device of the distance between the suction and pressure side Fills the connector part of the pump device completely and thus further deformation of the Prevents elastomer body. Because of the greater length of the elastomer body is initially a part of the truncated cone outer surface of the elastomer body out through the support jacket. When clamping the stator between the connection parts of the eccentric screw pump device this material is compressed into the support jacket. This increases the Preload with which the elastomer body rests on the support jacket and on the rotor. The already described pressure-side projection of the elastomer body, which acts as a stop for the Depression or protuberance of the support jacket, prevents the support jacket from becoming advances towards the pressure side when installing the stator in the pump device. After the support jacket came to rest on the protrusion of the elastomer body has reached its end position. The height at which the truncated cone outer surface of the elastomer body then protrudes beyond the suction-side edge of the support jacket Appropriately in a range from 0.5 to 1.5 cm, preferably about 1 cm. That way ensures that by compressing the protruding elastomer material in the suction area there is no excessive accumulation of material, which makes the delivery volume impermissible could restrict. At the same time prevents the support jacket from being fixed on the pressure side The protrusion of the elastomer body means that there is too much compression in the pressure area of the elastomer body takes place, which in turn delivery volume and delivery pressure could limit to undesirable values. The arrangement described thus enables an exact positioning of the elastomer body and support jacket to each other and guaranteed due to the precisely predeterminable compression of the elastomer body, that delivery pressure and delivery volume can be set to the desired values. Handling error are practically impossible.

A particularly good seal in the pressure-side area of the stator can also be created be that in addition to the pressure side flange-like projection, which in the pressure side connection part of the feed pump is accommodated, one of the flange-like projection outgoing annular support surface is present, which increases radially outwards towards the suction side. When clamping the stator in the This annular bearing surface is pumped in the direction of the pressure-side connection flange the pump device pressed until it rests on the entire surface of this flange. The annular sealing surface thus obtained ensures a particularly good seal in the print side area.

A particularly good protection against twisting of the elastomer body in the support jacket can can be achieved in that the inner surface of the support jacket with a surface structuring is provided. Under surface structuring, relief-like, large areas should be used Structures are understood with which the friction between the support jacket and the elastomer body can be increased. The depth of the structures only moves in millimeters or Submillimeter range. The surface structuring can be mechanical or chemical Surface processing be generated. An example is the processing of the surface by sandblasting. Another option is to have the surface structures already to generate when manufacturing the support jacket. For example, the support jacket by turning manufactured, this process can be done deliberately so that a coarse screen arises at which transverse grooves are generated in the inner surface of the jacket.

More expedient in terms of protection against twisting are in the axial direction of the support jacket trending structures. Such structures are already in the process of producing the support jacket available. For example, if you make the support jacket by pressing, you can use it as a pressing tool a mandrel can be used which has protrusions on its outer surface. These projections are made as a structure on the inside of the Transfer sheath.

The support jacket can in principle be used for any such jacket in the prior art material used. Metal is particularly suitable. In addition, the Support jacket with the mountings customary in the prior art for fastening in the eccentric screw pump device be provided. For example, at least one over is suitable its outer surface protruding stop, which for example on one of the connecting flanges the pump device comes to rest and a turning of the jacket during the Operation of the device prevented. Alternatively or additionally, lateral holding arms can be used for Attachment to the tie rods of the pump device.

The production of the support jacket is not based on the methods already described or other special manufacturing processes limited. Exemplary of other types of manufacture casting processes, rolling processes or hydroforming processes can be called.

In principle, the elastomer body can also be used from all those already used in the prior art Materials are manufactured using the processes used there. An example is on Rubber, natural or synthetic rubber or polyurethane referenced.

Figur 1

einen Elastomerkörper eines erfindungsgemäßen Einschubstators in Seitenansicht

Figur 2

einen zugehörigen Stützmantel im Längsschnitt

Figur 3

einen druckseitigen Ausschnitt eines Stützmantels, der auf einem Elastomerkörper angeordnet ist, im Längsschnitt

Figur 4

einen in einer Exzenterschneckenpumpen-Vorrichtung vormontierten erfindungsgemäßen Stator

Figur 5

den Stator gemäß Figur 4 in fertig montiertem Zustand.

The invention will be described below using the example of some drawings. In it show schematically

Figure 1

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

Figure 2

an associated support jacket in longitudinal section

Figure 3

a longitudinal section of a pressure-side section of a support jacket which is arranged on an elastomer body

Figure 4

a stator according to the invention pre-assembled in an eccentric screw pump device

Figure 5

the stator according to Figure 4 in the fully assembled state.

1 shows an elastomer body 1 of an insertion stator according to the invention in FIG Side view. The elastomer body 1 essentially has the shape of a truncated cone a longitudinal pump cavity for receiving a rotor (not shown). On both end faces of the elastomer body 1 there are flange-like projections 4 and 5 arranged. Their heights l1 and l2 and their diameters D1 and D4 are dimensioned so that that they are in corresponding recesses in the connecting flanges of the eccentric screw pump Find admission. The side of the truncated cone with the smaller diameter is with the suction side, the one with the larger diameter with the pressure side of the device connected. The diameter increase of the elastomer body 1 takes place in the axial direction continuously. In the case shown, the angle of inclination α is 91.35 °.

In the area of the elastomer body on the pressure side there is an annular contact surface 6, which starts from the flange-like projection 5 and extends radially outwards and in Extends towards the suction side. Above this contact surface 6 jumps in Projection 3 laterally over the entire outer circumference of the truncated cone surface. On his suction-side end it forms a support surface 2 for the support jacket, which during assembly is pulled over the elastomer body.

This support jacket is shown in FIG. 2 and provided with the reference number 7. He is like the elastomer body is conical and has the same angle of inclination α of 91.35 ° on. In its pressure side area, it has a protuberance 9, the shape of the Projection 3 of the elastomer body 1 corresponds. When installed, stage 8 of the support jacket comes 7 to lie on the contact surface 2 of the projection 3 of the elastomer body 1. Thereby further inadvertent advancement of the support jacket on the elastomer body is prevented.

So that the elastomer body rests in the supporting jacket with a prestress, the elastomer body has an outer diameter that is slightly larger than the corresponding inner diameter of the Supporting jacket. The diameter difference can usefully be about 0.5 mm. In the event of The components shown are, for example, the diameter D1 of the elastomer body 1 0.5 mm larger than the corresponding diameter D5 of the support jacket. Appropriate Diameter differences of 0.5 mm can also be found between the related ones Diameters D2 and D6 as well as D3 and D7. The elastomer body 1 is therefore with its outer surface on the entire inner surface of the support jacket 7 with prestress. This Biasing is further increased by screwing the rotor into the pump cavity. This large-area positive connection reliably prevents the elastomer body rotates in the support jacket during operation of the stator, even if the elastomer body has no key-like or other elevations on its outer surface has, as they were common in the prior art, to the rotating of the elastomer body to prevent. Stabilizing outer parts, as used in the prior art the key-like protrusions were not required. The invention Insert stator consists only of the elastomer body receiving the rotor and the support jacket.

Figure 3 illustrates the assembly of the elastomer body and support jacket of the invention Stator. Only the print side area is shown. Because of the conical shape of the elastomer body and the supporting jacket is the sliding on of the supporting jacket the elastomer body possible without great effort. If necessary, the support jacket brought into the end position shown in the right part of the figure by lightly opening it become. Here, the pressure-side projection of the elastomer body 1 is positive in the Well 9 of the tubular jacket 7 added. In contrast to that shown in Figure 2 In a variant, the depression 9 here is in a recess in the jacket wall.

Even if, as shown in the left part of FIG. 3, support jacket 7 and elastomer body 1 have not been positioned in an ideal position with respect to one another, so the projections 2 and 8 are not come to rest on each other, this is not a problem. The exact positioning arises at the latest when clamping the stator according to the invention in the pump device what will be described below with reference to Figures 4 and 5.

FIG. 4 shows an insertion stator according to the invention comprising an elastomer body 1 and a support jacket 7 with the rotor turned in an eccentric screw pump device. The front flange projections 4 and 5 of the elastomer body come in associated Wells of the connecting flanges 10 and 11 of the device to lie. Upper flange 11 and The lower flange 10 are held together by the tie rods 12 and 12 ', which are merely shown here are indicated by the dashed lines. Figure 4 shows the device in one inoperative condition from tensioning the tie rods 12 and 12 '.

The illustration shows that the total length L1 (FIG. 1) of the elastomer body is greater is than the total length of the support jacket 7 and on the other hand, with the same length of the projections 3 and 9, the length L3 of the truncated cone section of the elastomer body 1 has a greater length has as the length L2 of the truncated cone section of the support shell 7. Accordingly, the Elastomer body 1 with a length l3 over the suction end of the support jacket 7 over. The Length l3 is about 1 cm in the case shown.

When the tie rods 12 and 12 'are tightened, the upper flange 11 and lower flange 10 become one another approximated. As a result, the elastomer body 1 is compressed in the axial direction. That about the two The ends of the support jacket 7 protruding elastomeric material is in the support jacket compressed into it. The pressure-side support surfaces 6 are increasingly in the direction pressed onto the lower flange 10 until they lie tightly against it and for an excellent Ensure tightness in this area.

Should the support jacket 7 not be positioned exactly on the elastomer body 1 during the pre-assembly have been, as shown in the left part of Figure 3, this happens at the latest when tightening the tie rods into the operating state. Too far forward of the support jacket towards the pressure side, however, through the projection 3 of the elastomer body prevented. Excessive compression in the area of the print page therefore does not occur.

Simultaneously with the compression of the elastomer body in the area of the pressure side, this becomes also compressed on the suction side. However, by limiting the height of the protrusion I3 here, too, prevents too much elastomer material in the suction-side end of the support jacket 7 is accumulated and there to an undesirable limitation of the flow volume leads. The height of the support jacket 7 limits overall how much the tie rods are tightened can be. Incorrect assembly or incorrect settings when clamping the invention Stators are practically excluded.

After the tie rods have been fully tightened, there is a lateral projection 13, which protrudes from the suction-side end over the outer surface of the support jacket, to the upper flange 11 to lie adjacent. This upper flange 11 has a stop for the projection 13, which prevents the stator according to the invention from moving during operation of the pump device rotates with the rotor.

Claims (12)

Slide-in stator for eccentric screw pumps, consisting of a removable elastomer body (1), which has an outer surface that is essentially in the form of a truncated cone shell for form-fitting reception in a support shell (7) and has an axial pump cavity for receiving a rotor, and a tubular, a cavity in the form of a truncated cone supporting sheath (7) with a suction-side opening of smaller diameter (D5) and a pressure-side opening of larger diameter (D7),
characterized in that the elastomer body (1) has a protrusion (3) protruding beyond the outer surface and a corresponding recess or protuberance (9) for receiving the protrusion (3) is present in the supporting jacket (7). Insert stator according to claim 1,
characterized in that the projection (3) is formed in an annular circumferential manner in the pressure-side end area of the elastomer body (1) and in the recess or protuberance (9) is annularly circumferential in the pressure-side end area of the support jacket (7). Insert stator according to claim 1 or 2,
characterized in that the diameter of the elastomer body (1) in each section of the truncated cone outer surface is slightly larger than the inner diameter of the corresponding section of the support jacket (7) which comes into contact with the elastomer body (1) in the installed state (D5>D1;D6>D2;D7> D3). Insert stator according to one of claims 1 to 3,
characterized in that the angle of inclination (α) between the outer surface of the truncated cone of the elastomer body (1) and a plane perpendicular to the axial direction of the elastomeric body (1), measured towards the pressure side, essentially the angle of inclination (α) between the inner surface of the support jacket and one to the axial direction of the support jacket (7) corresponds to the vertical plane and is in particular between 91 ° and 95 °. Insert stator according to one of claims 1 to 3,
characterized in that the angle of inclination (α) between the outer truncated cone surface of the elastomer body (1) and a plane perpendicular to the axial direction of the elastomer body (1), measured towards the pressure side, is slightly larger than the angle of inclination (α) between the inner surface of the support jacket and one plane perpendicular to the axial direction of the support jacket (7). Insert stator according to one of claims 1 to 5,
characterized in that the elastomer body (1) has a flange-like projection (4, 5) on its suction-side and / or pressure-side end face. Insert stator according to claim 6,
characterized in that, starting from the pressure-side, flange-like projection (5) , the elastomer body (1) has an annular bearing surface (6) which rises radially outwards and towards the suction side. Insert stator according to one of claims 1 to 7,
characterized in that the elastomer body (1) has a greater length (L1) than the support jacket (7; L2). Insert stator according to one of claims 1 to 8,
characterized in that the length (L3) of the truncated cone outer surface of the elastomer body (1) from the suction-side end (2) of the projection (3) to the suction-side end face of the elastomer body (1) or to the pressure-side end of the suction-side, flange-like projection ( 4) is greater than the length (L2) of the support jacket (7) or the length of the support jacket (7) from its suction end to the suction end of its recess or protuberance (9) and the length difference (13), in particular 0.5 up to 1.5 cm, preferably about 1 cm. Insert stator according to one of claims 1 to 9,
characterized in that the support jacket (7) has a surface structuring in the region of its inner surface and in particular a surface structuring generated by mechanical or chemical surface processing. Insert stator according to claim 10,
characterized in that the surface structuring has been obtained by sandblasting, by turning the support jacket (7) or by pressing over a surface-structured mandrel when manufacturing the support jacket (7). Insert stator according to one of claims 1 to 11,
characterized in that the support jacket (7) has at least one stop (13) projecting beyond its outer surface.

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