DE4103848A1 - Rotating displacement pump for handling viscous media - incorporates at least one drivable impeller worm rotatably located in cylindrical inner chamber of pump housing - Google Patents

Abstract

The impeller worm (2) is rotatably located around the pump longitudinal axis (40) in the cylinder inner chamber (3) of the pump housing (4). It is connected at its driveside end with a drive shaft (5) via approximately radially oriented connecting webs (28). The worm is formed from a tube at least partially open on its face side, the inner and outer cover surfaces of which are screw-form. From the end area of the impeller worm turned away from the drive shaft extends a displacement part into the tube interior which is somewhat cylindrical. At its end projecting over the impeller worm the displacement part is connected to the housing inner wall (8) by at least two radially orientated connecting webs (7). USE/ADVANTAGE - A displacement pump for delivery of heavy, viscous liquids.

Description

The invention relates to a rotating displacer pump for pumping especially viscous fluids with at least one drivable screw conveyor, which in an interior of a pump housing rotatably supports the Contour the radially outer bulges of the conveyor Snail is adjusted, which is about the axial The outer contour of the screw conveyor extends the length of the screw with the inner wall of the pump housing interior (housing-in nenwand) forms a conveying space and the screw conveyor at least one inlet and one outlet for the medium Has.

Rotating positive displacement pumps are a special type of already known screw pumps. Opposite Screw pumps only have positive displacement pumps a spindle also referred to here as a "screw conveyor".

In the known screw pumps are the screws screw-type screw conveyors that are closed at the end rotatably supported in a pump housing. The forms surrounding the screw conveyor, in this area cylin Drische pump interior with the opposite, screw ben-shaped winding surface of the screw conveyor the space. This is where the inside of the pump is located Fluid handled by relative rotation of the screw opposite the pump housing from an inlet to an outlet  emotional. This fluid movement becomes practical achieved by a "screwing movement" of the screw conveyor.

These previously known positive displacement pumps are particularly suitable for pumping viscous fluids. It is always a disadvantage but the ratio of the volume of the comparatively large Pump to the rather small delivery volume.

You also already know a rotating positive displacement pump a metal, single-start helical ge wound rotor and one made of an elastic material manufactured stator. Between the rotor and him receiving, two-start helically wound stator the so-called "sealing line" is formed. Although is at this rotating displacement pump the axis of rotation of the rotor slightly offset from the central axis of the stator, however, this fits because of its elastic material good at which result from a rotary movement of the rotor the contact and flexing forces. Such pumps are in the trade also known as "Mohno pumps". With these leaves by pressing the rotor against the stator and the this caused the development of walking processes can hardly avoid the desired frictional heat. A gentle for change in the pumping medium in the pump housing and avoidance However, unnecessary frictional heat can affect the quality and the Durability of the material to be conveyed is essential.

A delivery pump has also been known for a long time Pump housing a helically wound inside of the pump has space (see DE-PS 21 31 305). In this pump interior a rotor is rotatably mounted in a longitudinal slot transversely displaceable, immediately adjacent and the inner peripheral wall of the interior be on both sides has impact sealing elements. This known pump has has proven itself for a long time, but it is because of the  Wear peripheral elements acting on the peripheral wall sensitive and can only with comparatively less rotation numbers of the rotor are operated.

Previously known screw pumps usually have Maximum speeds in the range of about 200 to 800 U / min, in favorable cases with a relatively thin För dermedium also up to about 1400 U / min. That draws the disadvantage to the fact that one does not use such screw pumps can directly drive a standard motor at 3000 rpm, but for example a reduction gear or same additional effort required. Also means an upper limited speed also a limitation of the pressures to be achieved under otherwise identical circumstances.

There is therefore in particular the task of rotating To create a positive displacement pump of the type mentioned, the while largely avoiding the disadvantages of previously known Pumps of this type have a high delivery rate if also generate comparatively higher delivery pressures can, and wherever possible, the pumped medium gentle and practically without inside of it witnessed friction heat can transport.

The achievement of this task consists in a Positive displacement pump of the type mentioned at the outset in particular rin that the screw conveyor by a helical ge sore and at least in part on its end faces wise open tube is formed, inside of which a the respective inner casing of the screw conveyor tube Lich displaced part of its outer diameter protrudes and that between the respective outer diameter of the Ver external part in the area of the screw conveyor and the conveyor a further conveying space is formed inside the screw.

The positive displacement pump according to the invention therefore not only has  one between the helically wound outer Surface of the screw conveyor and the neighboring inner one Shell surface of the pump interior formed delivery room but has another funding room on the im Inside the screw conveyor, which is open at the front their also helically wound inside and the outside of the displacer part. The invention The positive displacement pump thus has an approximately coaxial, double flow Flow, which is practically a doubling of the Funding volume corresponds. Because the pumped medium from both Sides forth with approximately the same pressure on the screw conveyor acts, a pressure equalization are also created and Radial forces acting largely on the screw conveyor avoided. But this also means one Reduction of undesirable frictional pressures that otherwise due to pressure-related installation of the screw conveyor on the Displacement part could arise. The one in the pump interior rotating screw conveyor practically "floats" in the conveyor good. Since the development of frictional heat prevented and a walking process when conveying the Pumped medium is avoided, the inventive can Displacement pump the material to be conveyed very gently in the pump housing to transport. You can also at high speeds of for example 5000 rpm and can do that Conveyed goods largely without damaging crushing transport, as this is less in the interior of the pump displaced rather than by one with the help of the particular designed screw conveyor caused drag effect is moved.

It looks particularly simple and advantageous leadership form of the positive displacement pump according to the invention that the displacer relative to the rotational movement of the conveyor snail stationary and preferably on his end area protruding from the screw conveyor with the  Housing inner wall is connected.

Another embodiment according to the invention, which also has its own worthy of protection, is in particular that the positive displacement pump has two preferably coaxially and non-rotatably connected screw conveyors, which are wound in opposite directions helically and can be driven via an expediently common screw conveyor drive. If necessary, the screw conveyors in their connec tion area have at least one flow opening and the pipe interior of both screw conveyors can be penetrated by a possibly common displacer part, at least one inlet or one outlet being provided on the pump housing in the connection area of the screw conveyors.
The oppositely coiled screw shape of the conveying screws, which are designed as a tube and are connected to one another in a rotationally fixed manner, not only reduces a friction pressure, but also largely compensates for an axial thrust acting on the screw conveyors. This embodiment is also characterized by a high delivery volume, a particularly gentle transport of the goods to be conveyed and a compact design.
In a way, you get a double-flow displacement pump.

The inlet or outlet is in this embodiment in Ver connection area of the screw conveyors on the pump housing see. At least one for the tubular casing of the screw conveyor provided and arranged in their connection area Flow opening allows the feed to flow in or out derstrom in the between the displacer and the also helically wound inner surface the conveyor chamber located in the screw conveyor. So while the Inlet or outlet is centrally located, two ent speaking counter openings serving as outlet or inlet for example at two opposite ends of the pump  pen housing may be provided.

To ensure a good entry or exit of the flow into the to allow internal conveying spaces of the screw conveyors it is expedient if both screw conveyors are closed have at least one flow opening on both sides of the Connection area of the screw conveyors are arranged.

It is advantageous if the displacement part is on NEN both ends open and during the pumping process from the medium through which the medium flows is formed. Thus, for example, the inlet and the Outlet of the conveyor rooms to be assigned to a screw conveyor in Longitudinal extension on one and the same side of the conveyor snail can be arranged.

An advantageous simple and compact embodiment according to the invention provides that the two conveyor snails in a common pump housing rotatable gela gert are that the housing interior at one end of the two screw conveyors are sealed liquid-tight and at the other end of the two screw conveyors passes into the inlet or outlet for the pumped medium and that in the connection area of both screw conveyors, the other, provided as an outlet or inlet pump connection is.

Further features of the invention result from the following the description of exemplary embodiments of the invention in Connection with the claims and the drawing. The single Features can be used individually or in groups of two an embodiment of the invention can be realized. It show in different scales:

Fig. 1 a positive displacement pump in a lateral position with Schnittdar a drivable rotatably mounted in the pump housing screw conveyor, which is formed as a helically wound about and open at its end faces tube,

Fig. 2 is a positive displacement pump similar to FIG. 1, just if ver a gap tube coupling comprising a non-illustrated pump drive is connected in a sectional view, wherein the pen housing in Pum this displacement pump provided För Dersch corner,

Fig. 3 is a positive displacement pump having housing in the interior of their pumps two coaxial and rotationally fixed to one another ver Thematic screw conveyor which passes through the Common a mes and open at its end faces displacer part,

Fig. 4, the positive-displacement pump of FIG. 1 in a partial sectional view in which a drive shaft abge facing region of its screw conveyor,

Fig. 5, the illustrated Verdrän also cut gerpumpe of FIG. 1 and 4, in the drive-side region of its screw conveyor

Fig. 6, the rotationally connected to the screw conveyor to the drive shaft of the positive displacement pump from FIGS . 1, 4 and 5 in a cross section in section plane VI-VI of Fig. 5 and

Fig. 7 is a highly schematic partial longitudinal section in the area Be the front end of the displacer 6 a.

Fig. 1 shows a partially sectioned side view of a positive displacement pump 1 , which has a feed screw or screw conveyor 2 . This is located in a guide for cylindrical interior 3 from a pump housing häuses. 4 The screw conveyor 2 is rotatably mounted there about the Pum pen longitudinal axis 40 . The screw conveyor 2 is connected at its drive end to a drive shaft 5 via approximately radially oriented connecting webs 28 ( FIGS. 1 and 6). The screw conveyor 2 is formed by a tube which is at least partially open on its end faces, the inner and outer lateral surfaces of which are wound in an approximately helical manner. Of which the drive shaft 5 end region of the screw 2 from remote projects a displacement part 6 in the tube interior which, according to exemplary embodiments the off in the region of the screw conveyor 2 is approximately cylindrical and at its through the screw conveyor 2 protruding end portion over at least two, also approximately radially oriented connecting webs 7 is connected to the housing inner wall 8 .

The outer diameter D 1 of the outer enveloping circle 41 of the screw conveyor corresponds approximately to the inside diameter D 2 of the Ge housing interior 3rd In this case, is meant a coat-like radially outside imaginary around the feed screw 2 of curves under the outer envelope circle 41, the straight in the embodiment in case of cylindrical diameter D 2 of, to the pump longitudinal axis 40 parallel lines 41 is formed, of which in Fig. 2, two lines 41 are shown in dash-dotted lines. The same applies to an inner enveloping circle 43 with the diameter D 3 , which is also formed by a family of imaginary Li lines 44 ( FIG. 2), which runs parallel to the longitudinal axis 40 of the pump through the screw conveyor 2 in its inner tube. In the case of a cylindrical displacer part 6 , this inner enveloping circle 43 also has a cylindrical shape and, as seen in the axial direction, it largely coincides with the outer jacket of the cylindrical displacer part 6 , if the diameter D 3 of the inner enveloping circle 43 advantageously corresponds to the outer diameter D 4 of the cylindrical displacement part 6 is adapted. The outer enveloping circle 41 and the inner enveloping circle 43 are after standing in the embodiment with a cylindrical displacement gerteil 6 and cylindrical housing inner wall 8 based on the usual designations for threads also referred to with outer diameter D 1 and core diameter D 3 .

In this embodiment, the positive displacement pump 1 has two För der spaces 9 , 10 , which form a practically coaxial, parallel double flow flow. One delivery chamber 9 be found between the inner wall 8 of the pump housing 4 and the adjacent outer surface 35 of the conveyor screw 2 and the other delivery chamber 10 between the inner surface 36 and the outside 37 of the displacer part 6 . By a relative rotational movement of the rotating in the pump housing 4 screw 2 relative to the pump housing 4 , a conveying movement of the medium located in the housing 3 is caused by an inlet 11 to an outlet 12 . The conveying medium is practically carried out by a "screwing movement" or a "dragging action" of the screw conveyor 2 (cf. also FIG. 2). Inlet 11 and outlet 12 are each arranged at the opposite end regions of the screw conveyor 2 .

In Fig. 1 it can be seen that the end faces 29 of the displacer part 6 are closed. The end of the drive shaft 5 facing away 29 a, which forms the verbun via the connecting webs 7 with the housing inner wall 8 which end region of the displacer part 6 , tapered approximately streamlined, while the end region facing the drive shaft 5 , which is approximately in the right Angled to the longitudinal extent flattened end face 29 b is formed, is spaced from the adjacent drive shaft 5 .

The indicated by points and wavy lines 31 (z. B. Fig. 2) conveyed medium can flow past the connecting webs 7 of the United displacer part 6 well into the conveying spaces 9 and 10 (see arrows 30 ). Since the drive shaft 5 is connected via comparable and also approximately radially oriented connecting webs 28 and a drive ring wall 21 (in short: "ring wall 21 ") to the drive-side end region of the conveyor screw 2 , there is again a good outflow in the pump housing 4 transported medium allows. By changing the direction of rotation of the pump housing 4 rotating screw 2 , the conveying direction can also be changed and the inlet and outlet sides of the displacement pump 1 can be interchanged.

The positive displacement pump 1 and also the feed pumps 1 a and 1 b shown in FIGS . 2 and 3 are distinguished by a high delivery volume due to their practically coaxial, double-flow delivery flow. Since the conveying medium acts on the screw conveyor 2 from approximately radially on both sides with approximately the same pressure, at least approximately a radial pressure equalization is created. Radial forces acting on the screw conveyor 2 are largely avoided. Thus, the pumped medium is transported gently and largely avoiding unnecessary frictional heat inside the housing of the positive displacement pumps 1 shown here.

In Fig. 2, a rotating positive displacement pump 1 a is shown in a side sectional view, in which the screw conveyor 2 is connected via a canned coupling 16 to a pump motor, not shown. This gap pipe coupling 16 consists in a known manner essentially of two approximately coaxial magnetic coupling elements 17 and 18 , one of which is outside and the other inside the gap tube 19 encapsulating the displacement pump on the drive side. The outer, the gap pipe pot encompassing magnetic coupling element 17 is designed as an external magnetic carrier and connected in a rotationally fixed manner to the pump motor via a coupling shaft 20 . In this bell-shaped outer magnet carrier, the magnetic coupling element 18 , which forms the inner magnet carrier, is immersed, which sits in a rotationally fixed manner on the drive shaft 5 mounted in the pump housing 4 . The outer and inner magnetic coupling elements 17 , 18 are separated from one another by an annular gap in which the canned pot 19 is also arranged.

The nested arrangement of the coupling elements te this canned coupling 16 favors the compact construction of the positive displacement pump 1 a according to the invention with a simultaneously hermetic closure of the delivery spaces 9 , 10 with respect to the pump drive area. On stuffing box, mechanical seal or the like seals can then be omitted in the drive shaft area. Instead of a canned pipe coupling, a canned motor can also be provided as the canned drive.

In Fig. 3, a positive displacement pump 1 b is also shown in a sectional view, which has two coaxially and non-rotatably connected screw conveyors 2 a and 2 b. These are formed from oppositely helical coiled tubes, in the interior of which a corresponding displacement gerteil 6 protrudes. The screw conveyors 2 a, 2 b form with the displacer part 6 a each two conveying spaces 9 , 10 , wherein for the respective inner conveying space 10 on the tube circumference of both conveying screws 2 a, 2 b at least one flow opening 26 is provided, which is on both sides of the Ver Binding area 27 of the screw conveyor 2 a, 2 b are arranged. Here, the pump 1 b forms out to a certain extent.

A common outlet 12 is provided on the pump housing 4 in the connection area 27 of the two screw conveyors 2 a, 2 b. In contrast to the feed pumps 1 , 1 a shown in FIGS. 1 and 1 a, in the displacement pump 1 b, the displacement part 6 a is designed as a flow tube which is open on its two end faces and through which the delivery medium flows during the pumping process and via which the drive-side screw conveyor 2 b the medium is sucked in from the same side as the screw conveyor 2 a. Thus, the common housing interior 3 of the displacement pump 25 can be closed in a liquid-tight manner at the end region located towards the screw conveyor 2 b, while the counter opening serving here as inlet 11 to the outlet 12 centrally arranged in the connection area is provided at the opposite end region of both screw conveyors.

Even with the positive displacement pump 1 b there is a pressure equalization on both sides of the screw conveyors 2 a, 2 b, so that undesired radial pressures can be avoided. Over it from the opposite direction is gewun by the use of two screw conveyors which 2 a, 2 b and an axial thrust largely compensated. The positive displacement pump 1 b also gently pumps the pumping medium contained in its pump housing 4 at a high pumping volume.

The positive displacement pumps shown in FIGS . 1 to 3 are suitable for the gentle transport of viscous, viscous and also of tixotropic liquids, e.g. B. for yogurt, also for example for honey, syrup, plastic or tar. As far as their consistency permits, the transport of these media can also be carried out at high speeds of 5000 rpm, for example.

In FIG. 4 is again an enlarged section of the Ver drängerpumpe 1 of Fig. 1 seen, showing the positive displacement pump 1 in which the drive shaft screw 5 facing away from the area of the conveyor. 2 From this end region of the screw conveyor 2 facing away from the drive shaft 5 , the displacement part 6 projects into the interior of the pipe. It can be clearly seen that this end region of the displacer 6 is streamlined and that the adjacent region 8 a of the housing inner wall 8 is approximately adapted to the shape of the displacer 6 . Thus, in this outlet or inlet area of the conveying spaces 9 , 10 there is no sudden cross-sectional widening or narrowing.

In FIG. 5, 1 and 4, the positive-displacement pump of FIG. Also shown in a partial sectional view of the drive-side region of its screw 2. The end 5 of the displacer part 6 , which faces the drive shaft 5, can be clearly seen, which forms a closed, flattened, approximately at right angle to its longitudinal extension and spaced from the drive shaft 5, end face 29 b. The displacer part 6 delimits not only the inner delivery space 10 with its outer lateral surface 35 ; rather, the conveyor screw 2 or 2 a, 2 b act on the one hand and the displacer 6 or 6 a together in the sense of a bearing-like guide. In their respective contact regions, ie at the Clear open the screw conveyor 2 obligations one hand and the housing in nenwandung 8 on the other hand, and Dersch corner at the indentations of the För 2 and 2 a, 2 b on the one hand and the outer surface 35 of the displacement part 6 and 6 a, on the other hand, there is a bearing-like sealing zone, the conveying medium being able to provide the bearing lubrication to a certain extent, but at the same time there is an adequate seal. The outer envelope circle 41 of the screw conveyor 2 or 2 a u. 2 b on the one hand and the inside diameter 8 of the housing inner wall are coordinated accordingly. The same applies to the outer diameter D 4 of the displacer 6 , 6 a on the one hand in relation to the inner enveloping circle 43 of the screw conveyor 2 or 2 a u. 2 b. This interaction favors that the positive displacement pump 1 , 1 a and 1 b also with comparatively high speeds such as. B. 5000 rpm can rotate.

At its end facing the screw conveyor 2 , the drive shaft 5 is preferably connected in one piece to an outer ring wall 21 by way of three connecting webs 28 which are evenly distributed over the circumference ver. Between the outer ring wall 21 and the drive shaft 5 , an annular gap 22 interrupted by the connecting webs 28 is provided, which enables a good inlet or outlet of the pumped medium. From Fig. 6, in which the cross-sectioned drive shaft 5 is shown without the surrounding pump housing 4, it is clear that the screw 2 is fastened by-two of these connecting webs 28 which extend through the clear core diameter center line of drive shaft coaxial to the To 5 is arranged.

In the positive displacement pump 1 , 1 a or 1 b, the housing inner wall 8 and the displacer 6 need not necessarily be cylindrical, as shown in the exemplary embodiments. For example, the housing inner wall 8 and z. B. the displacer 6 in the direction of conveyance have an at least approximately conical taper. The outer envelope circle 41 and the inner envelope circle 43 of the screw conveyor 2 and 2 a u. 2 b must then be adjusted accordingly. The rejuvenation need not be linear. Such an education can be advantageous in special cases, for example, if the medium is compressed somewhat in the desired manner at elevated pressure. However, the embodiments shown in the drawings, with the substantially cylindrical displacement parts 6 and 6 a, the cylindrical housing inner wall 8 and the conveyor screw fitted thereon in the manner described above, represent a preferred embodiment, inter alia because of the better manufacturability there is also - which is often desired - no significant volume change for the medium to be conveyed via the screw conveyor.

An advantageous development of the invention can still be seen clearly from FIG. 4 in connection with claim 15. Accordingly, the connecting webs 7 a, one of which is shown in FIG. 4 in cross section and dash-dotted lines, are arranged in a guide vane-like manner with an angle of attack W, which gives a flow course when the conveying medium flows in, which on the other, at the beginning of the screw conveyor 2 , 2 a or 2 b flow rate is adjusted. The previously mentioned, possibly axially oriented connecting webs 7 already prevent that in the area before the inlet of the screw conveyor 2 dermedien builds up an undesirable rotary flow with appropriate För. By the conditions on the conveying medium, the pump speed and the inflow coordinated arrangement of such connecting webs 7 a with a suitable angle of W can still improves the flow conditions in the inlet of the screw 2, 2 a and 2 b. Correspondingly favorable conditions are achieved at the inlet openings of channels 9 and 10 . This also favors that the greatest possible suction head is maintained in the pump 1 , 1 a or 1 b due to favorable flow entry conditions. Favorable flow entry conditions also favor the largest possible delivery volume to be enforced every second.

A further advantageous development of the invention can still be seen from FIG. 5 in conjunction with claim 14. There is a special design of the connec tion webs between the screw conveyor (s) 2 , 2 a or 2 b on the one hand with the drive shaft 5 or the associated ring wall 21 on the other hand, a connec- tion web 52 designed as a conveyor blade is shown in dash-dotted lines. If one forms the connecting webs between the ring wall 21 and the conveyor screw 2 accordingly, there is a type of propeller impeller at the end of the conveyor screw, which is formed by the parts 21 and 55 . This can also increase both the delivery volume and the delivery pressure.

From Fig. 7, additional refinements can be seen the displacement pump 1. As indicated there in a highly schematic manner, the housing inner wall 8 a is slightly conical and the outer casing 41 of the screw conveyor 2, which is only indicated by broken lines in FIG. 7, is adapted to the conical shape of the housing inner wall 8 a, while the screw conveyor 2 and the housing inner wall 8 a are relative are axially displaceable to each other. As a result, the gap width Spa between the housing inner wall 8 a and the casing 41 of the screw conveyor 2 , 2 a, 2 b can be changed. This may be desirable depending on the viscosity and / or the consistency of the medium. In Fig. 7 is also, highly schematic, a conical section of the United displacer part 6 a indicated. According to the double arrow 44 in FIG. 7, it can also be adjusted relative to the inner casing 43 of the screw conveyor 2 . In Fig. 7, the inner and the outer enveloping circle are schematically indicated only by a dashed line 43 and 41. By relative displacement of the conical displacement part 6 a of FIG. 7 with respect to the inner envelope circle 43 of the screw conveyor, the gap width Spi between these parts can be changed, for the same reasons and with the same advantages as above in connection with the housing inner wall 8 a already explained.

Characteristic of the positive displacement pump according to the invention is thus - even with the conical design of the parts 8 a, 2 and 6 a - that the screw conveyor is formed by a helically wound and at least partially open tube at its end faces, inside which one each narrowest cross section of the screw conveyor bezüg Lich its outer diameter adapted displacer, and that the respective outer diameter in the area of the screw conveyor with formation of a further delivery space et wa corresponds to the clear core diameter inside the pipe of the conveyor screw.

Another advantage of the positive displacement pump 1 according to the invention is that - depending on the viscosity of the conveying medium - the screw conveyor 2 , 2 a or 2 b can rotate up to 5000 rpm. This initially gives the advantage that standard motors with the usual speeds of 3000 rpm can be used as a drive without the interposition of a gearbox or additional measures. If necessary, one can also generate correspondingly higher pressures with the pump 1 with such motors or other auxiliary measures by correspondingly increasing the speed.

All of the above or listed in the claims Individual features can be used individually or in any combination be essential to the invention with each other.

Claims (17)

1. Rotating positive displacement pump for conveying in particular viscous media with at least one drivable ren screw, which rotatably supports housing in an interior of a pump, the contour of which is adapted to the radially outer bulges of the screw, with the outer contour extending about the axial screw length the screw conveyor with the inner wall of the pump housing interior (housing inner wall) forms a delivery chamber and the screw conveyor has at least one inlet and one outlet for the medium, characterized in that the screw conveyor ( 2 , 2 a, 2 b) by a helical tortuous and at its end faces at least partially open tube ge is formed, in the interior of which the respective inner casing of the screw conveyor with respect to its outer diameter adapted displacer part ( 6 ) protrudes, and that between the respective outer diameter of the United extrusion les in the area of the screw conveyor ( 2 , 2 a, 2 b) and the inside of the screw conveyor a further conveyor space ( 10 ) is formed. 2. Rotating displacement pump according to claim 1, characterized in that the displacement part ( 6 ) relative to the rotary movement of the screw conveyor ( 2 , 2 a, 2 b) is designed to be stationary and preferably at its end region projecting from the screw conveyor with the housing inner wall ( 8 ) connected is. 3. Rotating positive displacement pump according to claim 1 or 2, characterized in that the inlet ( 11 ) in the region of one end and the outlet ( 12 ) in the region of the other end of the screw conveyor ( 2 , 2 a, 2 b) is provided. 4. Rotating displacement pump according to one of claims 1 to 3, characterized in that the displacement pump ( 1 b) has two preferably coaxially and non-rotatably connected screw conveyors ( 2 a, 2 b) which are wound in opposite directions helically and via an expediently common screw conveyor Drive can be driven, the screw conveyors ( 2 a, 2 b) in their connecting area ( 27 ) have at least one flow opening ( 26 ) that the tube interior of both screw conveyors ( 2 a, 2 b) passes through a preferably common displacement part ( 6 ) and the pump casing (4) in the connection region (27) of the conveyor worm (2 a, 2 b) is provided (12) at least one inlet or an outlet. 5. Rotating positive displacement pump according to claim 4, characterized in that both screw conveyors ( 2 a, 2 b) each have at least one flow opening ( 26 ) which are arranged on both sides of the connection area ( 27 ) of the screw conveyors ( 2 a, 2 b) . 6. Rotating positive displacement pump according to one of claims 1 to 5, characterized in that the displacer part ( 6 ) is designed as a continuous flow medium inflow pipe. 7. Rotating positive displacement pump according to one of claims 4 to 6, characterized in that the two screw conveyors ( 2 a, 2 b) are rotatably mounted in a common pump housing ( 4 ), that the housing interior ( 3 ) at one end region of the two screw conveyors ( 2 a, 2 b) is liquid-tightly sealed and at the other end region of the two screw conveyors ( 2 a, 2 b) passes into the inlet ( 11 ) or outlet for the conveying medium and that in the connection area ( 27 ) of both screw conveyors ( 2 a, 2 b) the other, serving as outlet ( 12 ) or inlet Pumpenan circuit is provided. 8. Rotating displacement pump according to one of claims 1 to 7, characterized in that the displacement pump ( 15 ) has a canned drive ( 16 ). 9. Rotating positive displacement pump according to one of claims 1 to 8, characterized in that the screw conveyor (s) ( 2 , 2 a, 2 b) is connected via a possibly axially oriented Ver connecting webs with a drive shaft ( 10 ). 10. Rotating positive displacement pump according to one of claims 1 to 9, characterized in that the drive shaft ( 5 ) facing away from the end portion of the displacer part ( 6 ) is tapered streamlined and that the adjacent area of the housing inner wall ( 8 ) to this form of Displacement part ( 6 ) is approximately adapted to shape. 11. Rotating positive displacement pump according to one of claims 1 to 10, characterized in that the outer contour of the screw conveyor ( 2 ) is enclosed by a cylindrical enveloping circle ( 41 ) which is matched to the inside of the housing ( 8 ) and that the inside of the Conveyor screw ( 2 ) has a substantially cylindrical clear shell ( 43 ) which is matched to the cylindrical displacement part ( 6 ). 12. Rotating positive displacement pump according to one of claims 1 to 11, characterized in that the displacer part ( 6 ) for fastening to the pump housing ( 4 ) has at least one, preferably at least two connecting webs ( 7 ), the flat sides of which may be approximately parallel to the conveying direction are arranged at the pump inlet. 13. Rotating positive displacement pump according to one of claims 1 to 12, characterized in that the speed of their Screw conveyor above 1400 rpm, preferably is at or above 3000 rpm. 14. Rotating positive displacement pump according to one of claims 9 to 13, characterized in that the connecting webs of the screw conveyor (s) ( 2 , 2 a, 2 b) with the drive shaft ( 5 ) or the associated ring wall ( 21 ) as a conveyor show ( 52 ) of a propeller impeller ( 21 , 55 ) are formed. 15. Rotating positive displacement pump according to one of claims 12 to 14, characterized in that the connecting webs ( 7 a) for fastening the displacer part ( 6 ) are arranged in a vane-like manner with an angle of attack (W), which adjusts the inflowing medium to the flow at the beginning the screw conveyor ( 2 , 2 a, 2 b) gives a coordinated direction of entry. 16. Rotating positive displacement pump according to one of claims 1 to 15, characterized in that the housing interior ( 8 a) is slightly conical, the outer casing ( 41 ) of the screw conveyor ( 2 , 2 a, 2 b) is fitted there and the Screw conveyor and the inner casing ( 8 a) are axially displaceable relative to each other. 17. Rotating positive displacement pump according to one of claims 1 to 16, characterized in that the jacket of the Ver displacer body is slightly conical and the inner casing ( 43 ) of the screw conveyor ( 2 , 2 a, 2 b) fitted to it and screw conveyor and displacement part ( 6 ) are relatively axially displaceable.