EP3913187B1 - Screw spindle pump - Google Patents

Description

The invention relates to a screw spindle pump, comprising a housing with a running bore consisting of at least two intersecting bores, in each of which a spindle is accommodated, the spindles having a screw profile which meshes with one another in sections and bending in a defined bending direction during operation as a result of hydraulic bending pressure.

Such screw pumps are used to promote a wide variety of fluid media. They include a housing with a barrel bore formed by at least two intersecting bores. A spindle is received in each of these bores, typically one spindle being a drive spindle and the other being a idler spindle driven via the other spindle. Sometimes two running spindles, which are arranged on both sides of a central engaging spindle, are provided, in which case the running bore consists of three intersecting bores. The spindles have corresponding screw profiles, via which they mesh with one another, cavities being formed via the toothing engagement, which form the conveying chambers for the fluid to be conveyed. This makes it possible to convey the fluid supplied on one side from this suction side to the pressure side, where the fluid is discharged. The structure and function of such a screw pump is basically known.

As described, the screw pump sucks in the fluid to be pumped on the suction side and pumps it to the pressure side while constantly compressing it. This results in a corresponding differential pressure between the suction and the pressure side, which can be a few bar up to well over 100 bar, depending on the design of the screw pump. This means that, in particular the higher the differential pressure, a corresponding hydraulic bending pressure is exerted on the spindles, which, since the fluid path is defined within the pump, is always directed in a defined direction. This hydraulic bending pressure causes the spindles to bend in a defined bending direction, i.e. that the spindles, which are usually mounted in plain bearings in the area of both spindle ends, experience a slight deflection, i.e. are deformed. Consequently, as the spindles are located in the respective bores of the housing, which may be either a single housing or an insert inserted into an outer housing, and rotate in the respective bore, the relative position of the spindle changes to the bore wall, which means that the given ring segment-like gap increases in width on one side due to bending, while it narrows on the other side, whereby this change in width naturally varies slightly, seen over the spindle length, due to the bending geometry. In order to avoid the spindle or the screw profile coming into contact with the inside wall of the bore as a result of this bending, which would be extremely wear-promoting, the bore diameter is selected with a corresponding oversize so that, despite bending, ideally there is still a corresponding distance even in the maximum bending area given is. In addition, it is known to arrange the spindle off-axis in the central bore, ie to arrange it with its spindle axis offset slightly from the center against the direction of bending. This design is made in such a way that in the area of maximum bending, the distance between the spindle and the bore wall is almost the same in and opposite the direction of bending. This means that in this area there is a gap with an almost constant gap width between the spindle and the inner wall of the bore. The size of the gap surrounding all the spindles, which has approximately the shape of an "8" in a running bore consisting of two bores, is included in the calculation of the delivery rate. Because there is a certain amount of leakage through this gap, ie a certain amount of fluid that is not pumped. The larger the gap or the circumferential gap cross-section, the larger this leakage component.

DE102011101648A1 , SU1435819A1 and US2019078566A1 disclose screw pumps according to the preamble of claim 1.

The invention is therefore based on the problem of specifying a screw pump that is improved in comparison thereto.

To solve this problem, the invention provides in a screw pump of the type mentioned that each bore with a slot a longer first axis of symmetry and a shorter second axis of symmetry orthogonal thereto, the longer first axis of symmetry running in the bending direction.

The screw pump according to the invention therefore has no central, i.e. circular, bores, as has been customary in the prior art, but slot-like bores, i.e. bores that do not have a clear radius, but are defined by two different, mutually orthogonal symmetry axes. The slot-like bore has a first, longer axis of symmetry and a second, shorter axis of symmetry that is orthogonal thereto. The longer axis of symmetry runs in the direction of bending, the shorter axis of symmetry runs orthogonally to it. This configuration has the advantage that, on the one hand, the spindle can easily deflect, since after the deflection has taken place along the longer axis of symmetry, there is sufficient space within the bore to ensure that the spindle or its screw profile does not run against the inner wall of the bore . However, in the direction orthogonal to this, in which no deformation takes place, it is possible due to the slot-like design to reduce the distance between the opposite wall surfaces of the bore, so that overall there is a smaller gap width seen in the direction of the second axis of symmetry than in the direction of the first axis of symmetry. Due to this slot-like bore geometry, the entire gap cross-sectional area can therefore be reduced considerably, since due to the slot-like design with a longer and shorter axis of symmetry, there is no round gap surrounding the respective spindle with a constant width around the circumference, but a gap with a gap width that varies around the circumference . Depending on how close the opposite inner wall areas of the bore are to the spindle in the short axis of symmetry, there is a correspondingly large reduction in the gap width, which in turn is reflected in a correspondingly large reduction in the overall gap cross-section.

The reduction of this gap cross-section inevitably results in a considerable reduction in the leakage volume over the area of the differential pressure interval, tests having shown that a reduction of up to 25% or more is easily possible.

The screw spindle pump according to the invention and the bore geometry provided according to the invention thus enable problem-free and low-wear pump operation on the one hand, since spindle bending resulting from the hydraulic bending pressure is possible without problems and there is always a sufficient distance to the bore walls adjacent in the direction of the longer axis of symmetry, as well as at the same time due to due to the reduced gap diameter in the direction of the shorter axis of symmetry, there is a considerable reduction in the overall gap cross-section and thus in the leakage volume. This results on the one hand in extremely low-wear distribution, but on the other hand in comparison to the previous circular borehole geometry, a significantly more efficient production operation.

In order to enable the distance of the spindle or the screw profile in the direction of the first, longer axis of symmetry to be almost the same on both sides in the direction of the first, longer axis of symmetry, it is expedient to keep the spindles or their spindle axes in the unloaded state offset to the center of the first axis of symmetry, i.e. to be positioned off-centre here as well. As stated, the location of the same distance ultimately relates to the area of the greatest spindle deflection, with this area usually being in the middle of the spindle area.

The arrangement is expediently such that the spindles are positioned in such a way that at a defined differential pressure between a suction side and a pressure side of the pump or within a defined differential pressure interval, the width of the gap between the screw profiles and the inner wall of the bore in the direction of the first axis of symmetry is greater than is the width of the gap in the direction of the second axis of symmetry. It means that the spindles are arranged in such a way that when bending occurs, the distance of the screw profile from the inner wall of the bore in the direction of the first axis of symmetry to both axial directions is always greater than the distance or the gap width in the orthogonal second axis of symmetry. In the direction of the second axis of symmetry, the gap is therefore always narrower during operation than in the direction of the first axis of symmetry. In this way, symmetrical conditions in the direction of both axes of symmetry can ultimately be set in this bending area.

As described, each bore is designed as a slot-like bore with two axes of symmetry of different lengths that are orthogonal to one another. Such a bore can be formed, for example, by means of a milling tool, which not only makes it possible to introduce a cylindrical bore, but also to lengthen it slightly in the direction of the first axis of symmetry to form a slot-like shape. There is also the alternative possibility of lengthening the bore by grinding a cylindrical bore in the manner of a slot. A simple cylindrical bore is therefore first introduced, which is then ground out in a defined manner to form the longer axis of symmetry. In contrast, a further alternative possibility of forming the bore provides that each bore is formed from two separate, intersecting individual bores, the bore axes of which are offset relative to one another in the bending direction. Accordingly, each bore consists of two intersecting individual bores. These are minimally offset from one another in the bending direction, which means that their borehole axes are minimally spaced apart in the bending direction, specifically by the distance of the expected maximum deflection, which is in the range of 0.1-0.3 mm, for example. The formation of the bore via two separate individual bores has the advantage on the one hand that the bore as such is easy to make, since the formation of the bore requires only a simple linear movement of the drilling tool. In addition, a drilling tool can be used that has a smaller diameter than a drilling tool that is used to produce a circular, central bore, as has been customary in the prior art (this also applies to the use of a milling cutter, this can also be selected with a smaller diameter). Because it only has to be ensured that the diameter of the two individual bores is sufficiently large that the spindle, viewed in the direction of the second axis of symmetry, is still sufficiently spaced from the bore wall, albeit by a significantly narrower gap, after there is sufficient space in the direction of the first axis of symmetry for the absorption of the bend is given. When two intersecting individual bores are formed, a minimal web or shoulder remains in the intersection area, i.e. in the direction of the second axis of symmetry, due to the geometry and due to the minimal offset of the bore axes only a few micrometers inwards into the bore. Although this marginally narrows the gap, its height is so small that it in no case has a negative effect on the spindle movement in and against the bending direction, especially since there is no spindle deformation in the direction of the second axis of symmetry anyway.

The two individual bores expediently extend over the entire length of the housing, which simplifies their formation. As described, the housing can be a complete housing or a central housing block that is only closed by two covers. Alternatively, the housing can also be an insert that is inserted into a corresponding outer housing.

As an alternative to the configuration in which the two individual bores of each bore extend over the entire length of the housing, it can also be possible according to a variant of the invention for each bore to consist of two bore sections that axially adjoin one another, with the central axes of each bore section being set against one another. In this embodiment of the invention, each bore is therefore composed of two separate bore sections, each bore section in turn being formed from two separate individual bores as described above. The bore sections naturally merge into one another, but are not in an axial arrangement or are not axially aligned with one another, but are marginally angled towards one another. The position is chosen in such a way that this approximately maps the bending geometry of the spindle. This means that each bore section, which begins on one side of the housing and runs to the middle of the housing, runs at a minimal angle, so that, viewed in cross section, a quasi minimal V-shape results, with the tip of the V pointing in the bending direction. This bore geometry therefore takes up the spindle bending geometry, so that the bore geometry adapts even better to the actual conditions and, in particular, the gap resulting from the elongated hole-like shape and adapted to the bending is even better adapted to the spindle bending, seen in the axial direction.

The screw spindle pump is preferably a double-flow pump, i.e. each screw spindle has two axially adjacent, oppositely increasing screw profiles, which are preferably provided approximately in the area of the longitudinal center of the respective screw spindles or approximately symmetrically to the longitudinal center. In this double-flow type of pump, corresponding screw profiles running in opposite directions are provided, which extend from the region of the center of the spindle in the direction of the ends of the spindle, where the spindle is mounted. Alternatively, however, it can also be a single-flow pump in which each screw has only one screw profile that rises in one direction.

The screw pump itself is either a pure liquid pump. Alternatively, however, it can also be a multiphase pump, which can also pump a liquid-gas mixture in addition to a pure liquid.

In addition to the screw pump itself, the invention also relates to a housing for a screw pump of the type described. The housing has a running bore, consisting of at least two intersecting bores for accommodating one spindle each, the spindles having screw profiles that mesh with one another in sections and during operation of the Bend the screw pump in a defined bending direction using hydraulic bending pressure. This casing, which can be the actual pump casing, or an insert in one Outer housing is characterized according to the invention in that each bore is designed as a slot with a longer first axis of symmetry and a shorter second axis of symmetry orthogonal thereto, with the longer first axis of symmetry running in the bending direction.

In this case, each bore is preferably formed from two separate, intersecting individual bores, the bore axes of which are offset relative to one another in the bending direction. Alternatively, the slot-like bore can also be designed as a milled bore, i.e. the milling tool is guided accordingly to lengthen the bore while forming the longer axis of symmetry. A further alternative provides that the slot-like bore is ground from a cylindrical bore, i.e. that material is removed locally in a targeted manner by grinding in order to form the longer axis of symmetry.

Each of the two individual bores can extend over the entire length of the housing, which means that the entire bore consists of these two individual bores running axially. Alternatively, it is conceivable that each bore consists of two bore sections axially adjoining one another, with the central axes of each bore section and thus the central axes of the individual bores of one bore section being set against those of the other bore section. In this case, therefore, each bore section is formed from two separate individual bores, the bore axes of which are set slightly to one another, that is to say at an angle other than 180° to one another and are not aligned with one another. This makes it possible to tilt the entire bore geometry minimally following the bending line.

Furthermore, the invention also relates to a method for producing a housing for a screw pump of the type described above, comprising a running bore formed from at least two intersecting bores. This method is characterized in that for the formation of each bore at least two separate, intersecting individual bores whose bore axes are offset from one another, in one Housing body are drilled. The two individual bores or their bore axes are offset from one another in a previously defined bending direction.

Furthermore, it can be provided that the individual bores extend over the entire length of the housing body. Alternatively, each hole can also consist of two axially adjoining hole sections, the central axes of each hole section being set against one another, with two separate individual holes being drilled on both opposite sides of the housing body to form the hole sections. The bore sections or the individual bores meet in the middle of the housing, where the area of maximum spindle deflection is.

Fig. 1

eine Perspektivansicht einer erfindungsgemäßen Schraubenspindelpumpe im teilweise aufgeschnittenen Zustand,

Fig. 2

das ausgeschnittene innere Gehäuse nebst zweier Spindeln der Schraubenspindelpumpe aus Fig. 1,

Fig. 3

eine Stirnseitenansicht des Gehäuses aus Fig. 2 unter Darstellung der Laufbohrung,

Fig. 4

eine Prinzipdarstellung zur Ausbildung der beiden die Laufbohrung bildenden Bohrungen, jeweils bestehend aus zwei einander schneidenden Einzelbohrungen,

Fig. 5

eine Prinzipdarstellung einer langlochartigen Bohrung nebst deachsiert darin angeordneter Spindel im unbelasteten Zustand,

Fig. 6

die Anordnung aus Fig. 5 mit belasteter Spindel,

Fig. 7

eine Prinzipdarstellung einer zentrischen Bohrung mit deachsiert angeordneter Spindel gemäß Stand der Technik,

Fig. 8

die Anordnung aus Fig. 7 mit belasteter Spindel, und

Fig. 9

eine Prinzipdarstellung einer Schraubenspindelpumpe respektive eines Gehäuses mit zwei unter einem Winkel zueinander angestellten Bohrungabschnitten.

Further advantages and details of the present invention result from the exemplary embodiments described below and from the drawings. show:

1

a perspective view of a screw pump according to the invention in a partially cut-away state,

2

the cut out inner housing together with two spindles of the screw spindle pump 1 ,

3

an end view of the housing 2 showing the barrel bore,

4

a schematic representation of the formation of the two bores forming the barrel bore, each consisting of two intersecting individual bores,

figure 5

a basic representation of a slot-like bore together with a spindle arranged off-axis in it in the unloaded state,

6

the arrangement figure 5 with loaded spindle,

7

a schematic diagram of a central bore with a spindle arranged off-axis according to the prior art,

8

the arrangement 7 with loaded spindle, and

9

a schematic diagram of a screw pump or a housing with two bore sections set at an angle to one another.

1 shows in the form of a partially cut-away perspective view a double-suction screw pump 1 according to the invention, comprising an outer housing 2 with an inner housing 3 designed as an insert, in which, cf 2 , Two spindles 4, 5 are arranged, which serve to suck in, convey and discharge a fluid or a liquid-gas mixture. For this purpose, an inlet is provided on the housing side, as shown by the arrow P1, through which the fluid is drawn in. The fluid is discharged under pressure via an outlet which is arranged at 90 degrees in the example shown and is not shown in detail, as represented by the arrow P2.

The two spindles 4, 5 each have two screw profiles 6, 7 and 8, 9, respectively, the respective screw profile pairs 6, 7 and 8, 9 having opposite pitches. This means that it is a double-flow screw pump 1. The screw profiles 6 and 8 would come together in a manner known per se, as would the screw profiles 7 and 9.

The two screw spindles 4, 5 are supported and rotatably mounted in the area of their respective ends via corresponding bearing means 10, 11 or 12, 13, with the bearing means 10-13 generally being plain bearings.

The two spindles 4, 5 are accommodated in a barrel bore 14, which has the shape of a "lying 8" and which is shown as a schematic diagram in 3 shown is. 3 shows an end view of the housing 3 with a view of the barrel bore 14, which extends axially in a straight line through the housing 3.

The barrel bore 14 consists of two separate bores 15, 16 which intersect so that two central shoulders 17 result. A spindle 4, 5 is accommodated in each bore 15, 16 and rotates in it, one spindle being the drive spindle coupled to a drive motor, while the other spindle is the idler spindle. In the example shown, spindle 5 is the drive spindle, while spindle 4 is the following idler spindle. The spindles 4, 5 are accommodated in the barrel bore 14 or the bores 15, 16 at a distance from the adjacent inner wall of the bore, so that they can rotate without contact. Consequently, a gap is formed surrounding both spindles 4, 5, which also has the shape of a "lying figure 8".

According to the invention, each of the bores 15, 16 is embodied as a slot, which means that each bore 15, 16 is not a circular bore but has a longer and a shorter axis of symmetry. Of course, the two holes 15, 16 intersect, but each hole is assigned a defined, specific elongated hole geometry.

4 shows a relevant representation of the principle. The two bores 15, 16 are shown. Each bore 15, 16 consists of two intersecting individual bores 18, 19 in the case of bore 15 and 20, 21 in the case of bore 16. The two pairs of individual bores 18, 19 and 20, 21 have respective Bore or central axes Z1 and Z2, which are spaced apart in a bending direction R here. This bending direction R is the direction in which the respective spindle 4, 5 bends due to the hydraulic bending pressure in the housing 3, resulting from the pressure difference between the suction side and the pressure side. Although this bending is minimal, it does result from the more or less end-side support of the spindles 4, 5 via the bearing means 10 - 13. This defined bending deformation, which takes place in the bending direction R, now means that the screw profiles 6, 7, 8, 9 their position relative to the inner wall of the bore compared to the unloaded one Condition change slightly, so that, which will be discussed below, the corresponding, the respective spindle 4, 5 or the respective screw profile 6 - 9 surrounding gap varies in width.

In 4 For reasons of clarity, the respective individual bores 18, 19 or 20, 21 are clearly far apart from one another by the distance a with their central axes Z1. In fact, the distance a is only 0.1 - 0.3 mm, for example, so it is minimal, but still measurable.

This offset of the individual bores 18, 19 in the bending direction R now means that the resulting bore 15, 16 has a slot-like geometry, i.e. no longer a circular bore shape or inner wall shape, but a slightly elongated bore shape. Each individual bore 15, 16 therefore has a longer first axis of symmetry S1, which extends in the bending direction R, and a second, shorter axis of symmetry S2 that is orthogonal thereto. The symmetry axes S1, S2 are shown for the bore 15, the geometry of the bore 16 is identical. The difference in length between the axes of symmetry S1 and S2 ultimately corresponds to the distance a between the two central axes Z1, Z2, so it is also approximately 0.1-0.3 mm.

As described, it is 4 a purely schematic representation with respective individual bores 18, 19 and 20, 21, which are exaggeratedly spaced from each other. This results in in 4 in each case on the right side of the bore 15 and on the left side of the bore 16 a shoulder. However, this is actually only marginally pronounced with the given minimum axis offset a, it has a height of a few micrometers and therefore does not impede the spindle movement or bending and also has no influence on the pump operation.

The mode of operation of this slot-like configuration of the bores 15, 16 in comparison to a purely centric one previously customary in the prior art Bore is based on the figure 5 and 6 compared to the Figures 7 and 8 clear. the figure 5 shows, in the form of a schematic representation, a slot-like bore 15, which is shown closed here for reasons of description and representation (the following description, which sets out the basic principle, of course also applies equally to the second slot-like bore 16, which together with the bore 15 forms an 8-shaped Barrel bore 14 added). The spindle 4 or the outer circumference of the screw profile 6 is also shown as a schematic representation figure 5 shows, between the inner wall 22 of the slot-like bore 15 and the outer circumference 23 of the screw profile 6, a gap space 24 is formed, which in the example shown is ring-shaped, all the way around, in which the fluid collects during operation for delivery (in the barrel bore is that of the respective bore 15, 16 assigned gap only like a ring segment, whereby the two ring segments complement each other to form the "8" shape). Also shown is the longer first axis of symmetry S1 and the shorter second axis of symmetry S2. Also shown is the diameter D of the spindle 4 and its longitudinal or central axis ZS. This can be seen at a distance b from the longitudinal center or the central axis Z of the bore 15, specifically counter to the bending direction R. This means that, seen in figure 5 , is offset slightly upwards from the center of the bore 15. The distance b ultimately corresponds to the distance a, by which the two individual bores 18, 19 are offset, over which the bore 15 is formed.

If a hydraulic bending pressure acts on the spindle 4 in the direction of the bending direction R during operation, the latter bends slightly. 6 shows this operating situation, showing the area of maximum spindle deflection. As can be seen, the central axis ZS of the spindle 4 and the central axis Z of the bore 15 coincide as an example. The spindle 4 thus bends in the bore 15 somewhat downwards. As a result, the width B1 of the annular gap or gap space 24 seen in the direction of the first, longer axis of symmetry S1 and thus in the bending direction R is almost the same compared to the unloaded state. Viewed in the direction of the second, shorter axis of symmetry S2, however, the width B2 of the gap space 24 is significantly narrower. The gap width consequently changes around the circumference or narrows from the upper and lower axis point on the first axis of symmetry S1 to the lateral axis points on the second axis of symmetry S2, which is also given in the case of a barrel bore. This results from the fact that the two individual bores 18, 19 each have a bore diameter d1 or d2, which is slightly smaller than the diameter that a purely central bore would have. Such a central bore 25, as would be provided in the prior art, is 6 drawn in dashed. As can be seen, the diameter of such a central bore would correspond to the length of the longer first axis of symmetry S1. Viewed in the direction of the shorter second axis of symmetry S2, the comparison in 6 clear that the width B2 of the gap space 24 is significantly smaller compared to the situation with a central bore 25. This results in how 6 also clearly shows that the total cross-sectional area of the gap space 24 is significantly smaller when a slot-shaped bore 15 is formed compared to the cross-sectional area when a central bore 25 is formed, which in turn means that any leakage volume can be significantly reduced and consequently the delivery volume as well as the Efficiency of the screw pump can be improved.

the Figures 7 and 8 show for comparison the arrangement of the spindle 4 in a central bore 25, ie a bore with a constant diameter which corresponds to the length of the first axis of symmetry S1. Here, too, the central axis ZS of the spindle 4 is offset from the central axis Z of the circular central bore 25, so there is also an offset against the bending direction R here.

If the spindle 4 is loaded during operation, it bends slightly, as in 8 is shown. As can be seen, the spindle 4 is then located more or less centrally in the central bore 25. The result is an annular circumferential gap space 24 which has almost the same width B1 around the entire circumference, i.e. the gap width as it is in the embodiment according to the invention only in the upper and lower axis point is given. It can be seen in 8 resulting Cross-sectional area of the annular gap space 24 is significantly larger than the area of the gap space 24 according to 6 .

The inventive reduction of the gap space area or the distance of the bore inner wall from the spindle seen in the plane of the shorter second axis of symmetry S2 results from the slot-like design and the fact that this offers the possibility of producing the respective bore from two individual bores, whose respective individual diameter d1 , d2 is smaller than the diameter d of a cylindrical bore which would be equally suitable to accommodate the spindle deflection. That is, d1, d2 < d.

Although it is described above that the respective bore 15, 16 is formed by two individual bores 18, 19 or 20, 21, which are introduced one after the other and intersect one another, there is in principle also the possibility of drilling the respective bore 15, 16 using a milling cutter to form, which on the one hand introduces a bore, but on the other hand can also be moved slightly in the bending direction in order to produce the elongated hole geometry. This also has a diameter that is smaller than the diameter of a drill forming a central bore as is customary in the prior art.

In the embodiment of the figures described above, each bore 15, 16 extends linearly through the housing 3. Alternatively, however, there is the possibility of forming the respective bore 15, 16 from two adjacent bore sections, the central axes of which are slightly offset against each other in order to angled configuration of the bore sections to each other to accommodate the shape of the resulting spindle bending. A schematic diagram of such an arrangement is shown in 9 shown. There, the housing 3 is shown as an example, as well as the bore 15. This consists of two bore sections 15a, 15b, each bore section in turn consisting of two separate, intersecting individual bores 18a, 19a or 18b, 19b, which intersect, as above for the first Alternative invention described. That means that too here the individual bores 18a, 19a or 18b, 19b are minimally offset by the distance a in the bending direction. As can be seen, the bore sections 15a, 15b are not aligned with one another, but are at an angle α≠180° to one another, that is to say they are tilted or positioned more or less centrally in the bending direction R.

the 9 FIG. 1 also shows schematically the course of the central axis ZS of the spindle 4, which is inevitably also slightly bent due to the bending of the spindle. The angled position of the bore sections 15a 15b now approximately takes up this bending line or bent axis course, so that ultimately the resulting, quasi angled or kinked bore 15 is better adapted to the spindle geometry resulting from hydraulic loading.

Of course, it also applies here that the bend and angled position are clearly exaggerated purely for reasons of representation. In fact, the angle α is only a few minutes.

Although the exemplary embodiments described, in particular the Figures 1 - 4 , shows a double-suction screw pump with two spindles, the invention is of course not limited to this. Rather, it can also be a single-flow screw spindle pump, where only one screw profile is provided on each spindle. In addition, more than two spindles can also be provided, which means that a central working spindle and two parallel running spindles are provided. In principle, the slot-like configuration of the respective spindle bore according to the invention can be used wherever a spindle deflection occurs during operation and has to be compensated for due to the given hydraulic pressure conditions.

Claims (15)

1. Screw spindle pump, comprising a housing (3) having a running bore (14) consisting of at least two intersecting bores (15, 16) in which in each case one spindle (4, 5) is received, wherein the spindles (4, 5) have screw profiles (6, 7, 8, 9) meshing with one another in sections and, during operation, bend in a defined bending direction (R) as a result of a hydraulic bending pressure, characterized in that each bore (15, 16) is formed in the manner of an elongated hole with a relatively long first axis of symmetry (S1) and with a relatively short second axis of symmetry (S2) which is orthogonal thereto, wherein the relatively long first axis of symmetry (S1) extends in the bending direction (R).
2. Screw spindle pump according to Claim 1, characterized in that, in the unloaded state, the spindles (4, 5) are arranged in a manner offset from the centre (Z) of the first axis of symmetry (S1).
3. Screw spindle pump according to Claim 2, characterized in that the spindles (4, 5) are positioned in such a way that, for a defined difference in pressure between a suction side and a pressure side of the pump or within a defined differential-pressure interval, the width (B1) of a gap (24) between the screw profiles (6, 7, 8, 9) and the bore inner wall (22) in the direction of the first axis of symmetry (S1) is greater than the width (B2) of the gap (24) in the in the direction of the second axis of symmetry (S2).
4. Screw spindle pump according to one of the preceding claims, characterized in that each bore (15, 16) is formed from two separate, intersecting single bores (18, 19, 20, 21) whose bore axes (Z1, Z2) are offset from one another in the bending direction (R), or as a milled bore, or as a bore ground from a cylindrical bore.
5. Screw spindle pump according to one of the preceding claims, characterized in that the two single bores (18, 19, 20, 21) extend over the entire length of the housing (3).
6. Screw spindle pump according to one of Claims 1 to 4, characterized in that each bore (15, 16) consists of two bore portions (15a, 15b) which adjoin one another axially, wherein the central axes of the bore portions (15a, 15b) are inclined in relation to one another.
7. Screw spindle pump according to one of the preceding claims, characterized in that each spindle (4, 5) has two axially adjacent screw profiles (6, 7, 8, 9) which rise in an identical but inverted manner, said screw profiles being provided in the region of the longitudinal centre of the respective spindles (4, 5).
8. Screw spindle pump according to one of the preceding claims, characterized in that said screw spindle pump is a liquid pump or a multiphase pump.
9. Housing for a screw spindle pump (1) according to one of the preceding claims, having a running bore (14) consisting of at least two intersecting bores (15, 16) for receiving in each case one spindle (4, 5), wherein the spindles (4, 5) have screw profiles (6, 7, 8, 9) meshing with one another in sections and, during operation of the screw spindle pump (1), bend in a defined bending direction (R) as a result of a hydraulic bending pressure, characterized in that each bore (15, 16) is formed in the manner of an elongated hole with a relatively long first axis of symmetry (S1) and with a relatively short second axis of symmetry (S2) which is orthogonal thereto, wherein the relatively long first axis of symmetry (S1) extends in the bending direction (R).
10. Housing according to Claim 9, characterized in that each bore (15, 16) is formed from two separate, intersecting single bores (18, 19, 20, 21) whose bore axes (Z1, Z2) are offset from one another in the bending direction (R), or as a milled bore, or as a bore ground from a cylindrical bore.
11. Housing according to Claim 9 or 10, characterized in that the two single bores (18, 19, 20, 21) extend over the entire length of the housing (3).
12. Housing according to Claim 9 or 10, characterized in that each bore (15, 16) consists of two bore portions (15a, 15b) which adjoin one another axially, wherein the central axes of the bore portions (15a, 15b) are inclined in relation to one another.
13. Method for producing a housing for a screw spindle pump according to one of Claims 1 to 8, said housing comprising a running bore (14) formed from two intersecting bores (15, 16), characterized in that, for forming each bore (15, 16), at least two separate, intersecting single bores (18, 19, 20, 21) whose bore axes (Z1, Z2) are offset from one another are formed in a housing body, or each bore is milled with the two different axes of symmetry, or each bore is formed with the two different axes of symmetry by grinding a cylindrical bore.
14. Method according to Claim 13, characterized in that the two single bores (18, 19, 20, 21) extend over the entire length of the housing body.
15. Method according to Claim 13, characterized in that each bore consists of two bore portions (15a, 15b) which adjoin one another axially, wherein the central axes of the bore portions (15a, 15b) are inclined in relation to one another, wherein, for forming the bore portions (15a, 15b), in each case two separate single bores (18a, 19a, 18b, 19b) are formed on the two mutually oppositely situated sides of the housing body.

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