DE29707480U1 - Rotary displacement pump - Google Patents

Abstract

A rotary positive displacement pump comprises a stator (1) with a clamping plate (6) and a base plate (3) with an annular surface (5) on the clamping plate (6)-facing side. A membrane (11) covering the annular surface (5) is held between the clamping plate (6) and base plate (3) and forms a pumping channel (12) extending from an inlet (13) to an outlet (15) between the membrane (11) and base plate (3). A powered rotor (2) running around the concentric axis (4) of the annular surface (5) has at least one roller (21) running around the rear face of a circle of individual pressure transfer elements (14) which press the membrane (11) onto the annular surface to progressively interrupt the path from inlet (13) to outlet (15). The annular surface (5) is a layer of a softer material than the base plate (3). Preferably, the soft material layer (5) is a silicone polymer with a 20-50 Shore hardness extending over the area covered by the pressure transfer elements (14) and is either cast, vulcanised or bonded into a recess in the base plate (3) so that it projects above the recess edges. The base plate (3) is made of a dimensionally stable plastic and is held between the fixed clamping plate (6) and a removable clamping plate (24).

Description

KAM1 E006DEU/Be97S020/TW-Br/Be/22.04.1997 Rolf Kammerer, D-75196 Remchingen-Wilferdingen

Rotary displacement pump Description:

The invention relates to a pump with the features specified in the preamble of claim 1.

Such a pump is known from DE-295 11 966 U. The known pump has a stationary arrangement of a base plate and two clamping plates, between which the base plate is clamped. In the surface of the base plate an annular surface is provided, which extends over a partial circle or a full circle and is covered by a membrane, which is clamped tightly to the base plate at its edges by means of the one clamping plate. A pump channel is formed between the membrane and the annular surface of the base plate, into which an inlet and an outlet flow through the base plate. The pump channel connects the inlet and the outlet on the longer path, whereas the shorter path between the inlet and the outlet is blocked. A rotor is arranged coaxially to the annular surface above the membrane, which has several rollers, which are moved by means of axially displaceable pressure transmission elements,

Westliche Karl-Friedrich-Straße 29-31 D-75172 Pforzheim Postbank Karlsruhe 16852-750 (BLZ66010075}

VAT Registration No. DE 144 180005 ■

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which are arranged in a ring shape above the membrane, act on the membrane and press it locally against the ring surface, whereby the membrane interrupts the path from the inlet to the outlet at all times and thus ensures the desired pumping effect. The stroke of the pressure transmission elements can be adjusted using an adjusting ring, which is arranged above one clamping plate in the vicinity of the rollers; this also adjusts the pump's delivery capacity.

The clamping plate, which is arranged on the side of the base plate facing away from the membrane, is ring-shaped and is screwed to the opposite clamping plate by several screws arranged on its circumference, which at the same time firmly clamps the edge of the membrane. Coaxial to the rotor shaft, a threaded rod extends outwards through the circular opening of the ring-shaped clamping plate, onto which an adjusting nut is screwed, which allows the pressure with which the rollers act on the membrane to be adjusted via spring force. The pump's delivery pressure can be changed by turning the adjusting nut.

There are critical pump media that clump when pumped through such a pump. The critical pump media include, for example: dispersions for structural plasters, effect paints (paint dispersions that contain flaky pigments, flakes or chips) and fibrous dispersions (e.g.

Cotton fibers in dispersion to form "liquid wallpaper"). Clumping makes the dispersions unusable.

The present invention is based on the object of reducing the tendency of these delicate materials to clump when being pumped by such a pump.

This object is achieved by a pump with the features specified in claim 1. Advantageous further developments of the invention are the subject of the dependent claims.

In the new pump, according to the invention, a base plate carries a layer of a softer material than that of the base plate to form an annular surface along a pump channel. This simple measure can surprisingly prevent the pump medium from clumping or solidifying in the pump.

It is advisable for the layer of softer material to only extend over the entire area covered by the pressure transmission elements. This is sufficient for optimum effectiveness.

Preferably, the layer of softer material is connected to the base plate in one of the following ways: The softer material is cast on, vulcanized on or glued on. The advantage of these three options is that no pumping medium can get between the layer and the base plate and settle there.

A further advantageous development of the invention provides that the softer material is introduced into a recess in the base plate. This gives the softer material lateral support and the wear on it is thereby reduced when the pressure transmission elements are pressed down.

A further advantageous development of the invention provides that the softer material protrudes over the depression. This means that the membrane cannot be pressed against a freely protruding upper edge of the depression and thus damaged.

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Silicones are suitable as a softer material. They can be manufactured in different degrees of hardness. Hardnesses of 20 to 50 Shore have proven particularly effective for the softer material.

A further advantageous development of the invention provides that the base plate is located between a hold-down device and a clamping plate. This means that if the base plate or a softer layer on it is worn, only this one part needs to be replaced and not the entire clamping plate. This significantly reduces operating costs.

A further reduction in costs - and at the same time a saving in weight - is achieved by making the base plate out of plastic. This requires a dimensionally stable plastic that can withstand the forces that occur without being damaged. The following are particularly suitable as dimensionally stable plastics: polyamide, ABS polymers and polystyrene.

Further advantages of the invention emerge from the embodiment shown in the accompanying drawings . It shows:

Figure 1 shows a longitudinal section through a pump according to the invention along

the line B-B in Figure 2,

Figure 2 is a plan view of a base plate and

Figure 3 shows an enlarged cross-section through the base plate along the line A-A in Figure 2.

The pump has a stator 1 and a rotor 2. The stator 1 is part of the housing of the pump and has a clamping plate 24, a hold-down device 6, a base plate 3 and a membrane 11. The base plate 3 is ring-shaped and arranged coaxially to the axis 4 of the rotor 2. The base plate 3 has

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a flat ring surface 5, which is limited by two conical clamping surfaces 9 and 10, which lie behind the ring surface 5 when viewed from the rotor 2; two further clamping surfaces 7 and 8 lie opposite them, which are formed on the hold-down device 6 and interact with the clamping surfaces 9 and 10 in order to clamp the membrane 11 between them, which consists of an elastomer material, is an annular, flat structure in the relaxed, non-installed state and is bent by clamping between the conical clamping surfaces 7 to 10 so that it arches over the flat ring surface 5. In this way, a pump channel 12 is formed between the curved and thus elastically prestressed membrane 11 and the annular surface 5, into which an inlet 13 and an outlet 15, which is conveniently located close to the inlet 13, open and - just to be able to show it - is provided in a diagonal arrangement in Figure 1. The pump channel 12 is blocked on the short path from the inlet 13 to the outlet 15 by a respective elevation 39 on the annular base plate 3, in that the elevations 39 are designed in the shape of a circular segment in their radial section perpendicular to the base plate 3. The two elevations 39 are arranged radially on the annular surface 5 of the base plate 3. They prevent the pump medium from penetrating into the area that lies between the outlet 15 and the inlet 13 in the direction of rotation of the rotor 2.

A filling material is introduced into a recess 41 in the ring surface 5. The recess 41 extends almost along the entire pump channel 12 from the inlet 13 to the outlet 15. A one-piece silicone bed 35 is preferably used as the filling material. The recess 41 is expediently rectangular in cross-section, just like the silicone bed 35, which is inserted into the recess 41 with a precise fit. The recess 41 and the silicone bed 35 located in it are limited at their ends facing the inlet or outlet 13, 15 in such a way that their edges there each lie on a radius of the base plate 3. The depth of the recess 41 and thus also the thickness of the silicone bed 35 depend on the pump type and the medium to be pumped.

The silicone bed 35 expediently extends over the ring surface 5 of the

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Base plate 3 so that the membrane 11 pressed down by the pressure transmission elements 14 cannot be damaged at the edges of the recess 41. Surprisingly, this silicone bed 35 prevents solidification and demixing of a dispersion to be pumped during the pumping process.

On the outside of the membrane 11, a ring of tappets 14 is arranged, which serve as pressure transmission elements. The tappets 14 are T-shaped in longitudinal section, extend parallel to the axis 4 and are arranged along the entire pump channel 12, which connects the inlet 13 with the outlet 15, but not over that section of the membrane 11 which leads in the direction of rotation of the rotor 2 from the outlet 15 to the inlet 13, because there the pump channel 12 is interrupted by the elevation 39 provided on the annular base plate 3.

The tappets 14 are arranged in the hold-down device 6 so as to be displaceable parallel to the axis 4 and are secured by an adjusting ring 17 which can be displaced against the restoring force of the diaphragm 11 in the direction of the axis 4 by means of an eccentric 19, so that the tappets 14 have a variable end stop which allows the maximum cross-section of the pump channel 12 to be reduced and thus the pump capacity of the pump to be adjusted.

The rotor 2 rotates around a shaft 20, which is mounted in a roller bearing 26 in the hold-down device 6 and in another roller bearing 27 in the rear housing part. The rotor 2 has at least two free-running rollers 21 - in addition to free-running rollers 21, driven rollers are also conceivable - which roll over the tappets 14 and press them down, whereby the membrane 11 is pressed locally against the ring surface 5. This local pressure point moves along the pump channel 12 with the rotor movement, pushes the amount of liquid in front of it out through the outlet 15 and at the same time sucks in more liquid through the inlet 13.

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The delivery pressure of the pump depends on the pre-tension of the membrane 11. This pre-tension depends on the material and thickness of the membrane 11, but also on the extent of its bending. In addition, the delivery pressure depends on the force with which the tappets 14 act on the membrane 11. It can be changed by means of a second eccentric 22, which acts on a collar 28 on the shaft 20 via the rear roller bearing 27 and thereby tensions a spring 29 more or less, which rests on the axially movable carrier 30 of the rollers 21. By turning the eccentric 22, e.g. by means of a handwheel attached to the outside, the force with which the rollers 21 act on the membrane 11 can be increased or decreased. In the event of excessive pressure build-up under the membrane 11, the tappets 14 can evade the pressure, provided that the pressure force exceeds the restoring force of the spring 29, which can be changed by turning the eccentric 22.

The membrane 11 is clamped using a threaded bolt 31, which is screwed into the hold-down device 6, extends through the clamping plate 24 and carries a nut 32, which, when tightened, presses the clamping plate 24 against the base plate 3 and thus the base plate 3 against the edge of the membrane 11. It is also possible to use a quick-release fastener instead of the nut 32 to clamp the membrane 11. This clamps the membrane 11 and the base plate 3 and at the same time seals the pump channel 12. If the membrane 11 and/or the base plate 3 have to be replaced due to wear, only the nut 32 has to be loosened. The clamping plate 24 can then be removed and the base plate 3 and the membrane 11 are freely accessible. The wear occurs primarily on the hard base plate 3 or the soft silicone bed 35 and manifests itself as a result of the abrasion of the base plate 3 or the silicone bed 35 in an enlargement of the pump channel 12, which in turn results in a reduction in the delivery pressure. The drop in the delivery pressure therefore makes it easy to see when a replacement is necessary.

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In addition to the formation of the pump channel 12 by a membrane 11 spanning the annular surface 5 of the base plate 3, the pump channel 12 can also be formed by a hose that is clamped between the hold-down device 6 and the clamping plate 24 and covers the entire area covered by the tappets 14.

Claims (11)

-9-Claims: 1. Rotary displacement pump with a stator (1) which has a hold-down device (6) and a base plate (3), with an annular surface (5) provided on the side of the base plate (3) facing the hold-down device (6) and extending over at least part of a full circle, with an inlet (13) opening into the annular surface (5) and an outlet (15) extending from the annular surface (5), with a membrane (11) covering the ring surface (5), which is clamped tightly with its edges between the hold-down device (6) and the base plate (3), whereby a pump channel (12) extending from the inlet to the outlet is formed between the membrane (11) and the base plate (3), with a driven rotor (2) arranged above the annular surface (5), which rotates around the concentric axis (4) of the annular surface (5), has at least one roller (21) which is arranged above the membrane (11) and continuously presses the membrane (11) locally against the annular surface (5) by running on the back of a ring of pressure transmission elements (14) which are individually movable against the annular surface (5), whereby the membrane (11) progressively interrupts the path from the inlet (13) to the outlet (15), characterized in that the base plate (3) carries a layer of a softer material than that of the base plate (3) for forming the annular surface (5) along the pump channel (12). *♦ · -10- 2. Rotary displacement pump according to claim 1, characterized in that the layer extends over the area covered by the pressure transmission members (14). 3. Rotary displacement pump according to claim 1 or 2, characterized in net that the softer material is cast onto the base plate (3). 4. Rotary displacement pump according to claim 1 or 2, characterized in that the softer material is vulcanized onto the base plate (3). 5. Rotary displacement pump according to claim 1 or 2, characterized in that the softer material is glued to the base plate (3). 6. Rotary displacement pump according to one of the preceding claims, characterized in that the softer material is located in a recess (41) of the base plate (3). 7. Rotary displacement pump according to claim 6, characterized in that the softer material protrudes beyond the recess (41). 8. Rotary displacement pump according to one of claims 1 to 3 and 5 and 6, characterized in that the softer material is a silicone. 9. Rotary displacement pump according to one of claims 1 to 8, characterized in that the softer material is in a hardness range of 20 to 50 Shore. 10. Rotary displacement pump according to one of the preceding claims, characterized in that the base plate (3) lies between the hold-down device (6) and a clamping plate (24). 11. Rotary displacement pump according to one of the preceding claims, characterized in that the base plate (3) consists of dimensionally stable plastic.