DE102007012661B4 - A submersible pump unit - Google Patents

Abstract

Submersible pump unit (1) with a drive part (2) and a multi-stage pump part (4) connected to it via an immersion tube (3), wherein in the pump part at least one impeller (5) connected to the drive part via a drive shaft (6) and a Stator wheels (10) are arranged and a shaft seal is provided in the passage area of the drive shaft into the pump part, the pump part (4) having a pump housing (8) with at least two more identical housing parts (9) which interlock in some areas, with at least one a housing part (9) has an impeller (5) connected to the drive shaft (6) and a stator wheel (10) connected to the housing part as a return, and wherein a gap (37) is provided between the suction side of the impeller and its pressure side, characterized that the pump part (4) is a pump set formed from several with at least two identical, cup-shaped and stackable housing parts (9) Housing (8) has that these housing parts (9) which are designed as one-piece deep-drawn parts and have a step-shaped cross-section, ...

Description

The present invention relates to a submersible pump unit with a drive part and a connected thereto via a dip tube, multi-stage pump part, wherein in the pump part at least one connected via a drive shaft to the drive part impeller and a stator are arranged and wherein in the passage region of the drive shaft in the pump part a Shaft seal is provided, wherein the pump part has a pump housing with at least two same, partially intermeshing housing parts, wherein in at least one housing part connected to the drive shaft impeller and a stator connected to the housing part are located as feedback and wherein between the suction side of the impeller and its Pressure side is provided a gap.

Such a submersible pump unit is already out of the U.S. Patent 1,387,660A previously known. The document in question discloses a pump assembly of a plurality of pump housing parts, which can be connected to one another via a screw thread. A similar arrangement sees this U.S. Patent 5,256,033 A before, as well as the DE 43 10 466 A1 and the DE 744 795 A , In these cases, it is intended to realize a sealing stacking of housing parts, so that in the number of stages adapted pump can be realized.

In this context also to mention are the US Pat. No. 3,158,295 A , the German publication DE 37 29 673 C2 and the US 5,318,403 A in which the clamping of the housing parts does not take place against each other, but they are accommodated in a common outer housing.

The German utility model DE 72 34 608 U represents a special case with only one pump stage, the citation JP 62 29 14 95 A a pump-like fan.

Submersible pump units are used, for example, in connection with so-called bath thermostats, where they serve for the circulation of liquids to be tempered. In this case, very different temperatures may occur, for example, temperatures of -60 ° C to + 150 ° C, with which the submersible pump unit is loaded. The problem here is in particular the sealing material, which is used in the pump. PTFE can be used as the material for the seals, but at temperatures above about 250 ° C, the upper service temperature is reached.

In addition, it is problematic that occur in such submersible pump units, asymmetric radial forces particularly disadvantageous, since the pump part is connected via a comparatively long dip tube with the drive part. Resulting radial forces, which can lead to unwanted vibrations occur increasingly at high flow rates.

Furthermore, axial forces are unavoidable, which load the bearing of the shaft in the axial direction. Particularly with multistage pumps, correspondingly high axial forces occur.

Object of the present invention is to provide a submersible pump unit which can be used in a high temperature range, in which at least small radial forces occur and which is inexpensive to produce.

To solve this problem, it is proposed that the pump part has a pump housing with at least two identical, cup-shaped and stackable housing parts which engage in some areas and in these areas, directly close to each other, that in at least one housing part connected to the drive shaft impeller and a stator connected to the housing part are located as a return and that between the suction side of the impeller and its pressure side, a sealing gap is provided which is formed between the suction side, a cover disc forming impeller side and a substantially over the surface of the cover plate extending housing part.

In this submersible pump unit according to the invention sealing elements are required neither between the individual housing parts nor in the region of the sealing gap between the housing and the impeller cover disk. Thus, the material problem does not occur with respect to the seals otherwise used. In the sealing areas between the housing parts, the sealing surfaces lie directly against each other in a metallic sealing manner.

Also in the region of the sealing gap between the housing and the impeller cover disc no seals are provided. The throttling effect or sealing effect of the sealing gap required for decoupling between the pressure and suction sides is achieved by means of its special geometry. In the present invention, the sealing gap extends approximately over the entire radius of the impeller and the gap width can be kept relatively small. In addition, a friction pumping effect, which counteracts an inner throughflow of the sealing gap from the pressure to the suction side, is established by the surfaces delimiting the sealing gap over a large area.

Experiments have shown that the pump according to the invention in a temperature range of about -60 ° C up to about 350 ° C can be used.

For multi-stage pump designs can be formed by plugging together a corresponding number of housing parts by the same design of the housing parts in a simple manner, for example, with an additional housing part is preferably provided as a pressure-side collecting space. In a three-stage pump four housing parts are then stacked on each other. It is thus realized a modular system, which single-stage or multi-stage pump designs can be constructed with virtually equal parts according to the respective specifications.

It is particularly advantageous if the impeller and also the guide wheel serving as a flow return have two spaced-apart, planar annular disks with blades located therebetween.

In addition to their conveying and guiding function, the blades also serve as spacers for the two annular discs. Separate spacers are thus not required, so that the production is simplified. This also contributes significantly to the fact that the annular discs are flat elements which can be produced inexpensively by simple punching.

In this case, the housing parts and the impeller and the stator preferably made of sheet metal, in particular stainless steel.

The intended type of joining each of the two annular discs and the blades allows an economical production of the wheels and the guide wheels.

The respectively between the two spaced-apart annular discs of the stator and the impeller arranged guide blades or conveyor blades form connecting elements for the two annular discs and are positively and preferably also firmly bonded to the annular discs.

For this purpose, the guide vanes and the conveyor blades on their sides facing the annular discs projections for positive engagement in openings of the annular discs.

The annular discs and the associated blades can thereby be accurately fitted together and thus easily assembled. The positive connection can be designed such that with the mating together a sufficient, non-positive connection is achieved without additional security measures are required. For example, this can be achieved by a press fit in the positive connection area. If necessary, can be done in addition by deforming the projections and / or breakthroughs securing the connection.

Furthermore, there is the possibility that a cohesive connection between the annular discs and the blades by welding, for example by laser welding, inert gas welding, beam welding, resistance pressure welding or the like is made.

Both the non-positive and the cohesive connection are expediently designed so that remain flat over the outer sides of the annular discs and no projections.

For a cost-effective production of the pump part also contributes, that the cup-shaped housing parts are formed as one-piece deep drawn parts.

A particularly advantageous development of the invention provides that the number of conveying blades of the impeller is less than or equal to the number of guide vanes of the stator and that preferably five impellers per impeller per blade and seven blades are provided.

By a comparatively large number, in particular of the spiral-shaped stator blades, on the one hand resulting radial forces can be largely avoided and, on the other hand, pressure pulsations and resonance phenomena can be kept small.

For the modular construction of the pump part is advantageously provided that the protruding into the pump part, inner end of a sleeve-shaped shaft receptacle is designed for coupling with at least one intermediate piece for holding in each case an impeller.

Expediently, the shaft receptacle at its inner end and the intermediate piece at both ends coupling elements for positive coupling with each other and optionally with a further intermediate piece.

The spacers form hub parts each for an impeller and are rotatably coupled to the shaft mount.

The spacers may be formed so that they themselves a shaft extension from the Form shaft recording, so that with a different number of pump stages only a corresponding number of housing parts and spacers must be placed together.

Preferably, the intermediate pieces may be formed as attachable to the shaft end sleeves. In this case, it is expedient to dimension the wavelength to the greatest possible number of stages and to adapt the length of the dip tube to the respective number of stages.

Additional embodiments of the invention are set forth in the further subclaims. The invention with its essential details is explained in more detail with reference to the drawings.

It shows:

1 a side view of a submersible pump unit,

2 a longitudinal sectional view of a pump part of a submersible pump unit with a connected via a dip or pump tube connection plate,

3 a sectional view of a cup-shaped housing part,

4 a perspective view of a holder for the housing parts with a support plate,

5 a perspective view of an impeller overlooking the bottom,

6 a modified embodiment of an impeller with a view of the top,

7 a perspective view of a stator with a view of the top,

8th a sectioned, enlarged view of a pump part,

9 a side view of a wave recording,

10 a perspective view of in 9 shown wave recording,

11 a longitudinal sectional view and

12 a perspective view of an intermediate piece,

13 a longitudinal section and

14 a perspective view of an end spacer.

A submersible pump unit 1 ( 1 ) has a drive part 2 with an electric motor and a via a dip tube 3 connected pump part 4 on.

The submersible pump unit 1 can be part of a bath thermostat, with the liquid tempered and an external device for temperature control fed and can be returned by this again to the bath thermostat. The bath liquid is thereby from a discharge nozzle 12 the pump part 4 supplied to the external device and from this back via a return pipe 45 headed back into the bath thermostat.

The pump part forms a multi-stage centrifugal pump in a vertical arrangement. In the embodiment, the pump part is constructed in three stages (see also 8th ). The wheels located in the pump section 5 are via a drive shaft 6 with the drive part 2 connected. In the passage area of the drive shaft 6 in the pump part 4 is a shaft seal 7 intended.

How good in the 1 . 2 and 8th recognizable, the pump part 4 a multi-part pump housing 8th on that in the present embodiment of four cup-shaped housing parts 9 is composed.

In the lower three housing parts 9 There is one impeller each 5 and a stator 10 , The three wheels 5 are with the drive shaft 6 connected while the idlers 10 stand still and with the housing parts 9 are connected. By the arrows Pf1 the conveying direction of the tempering medium, for example water, characterized. The pump part 4 has underside centrally a suction opening 13 on top and on top of the top housing part 9 that a collection room 46 forms, one in a graduation plate 11 located pressure nozzle 12 ,

The individual, cup-shaped housing parts 9 are stacked on top of each other and interlock in certain areas. The housing parts 9 have a stepped cross-section, as well as from 3 is recognizable. At a bottom part 14 with a smaller outer diameter closes up a shell 15 with larger outer diameter. The bottom part 14 has a central opening 16 on, at the bottom of the housing 9 at the same time the suction opening 13 forms. The top 15 has on its upper edge an inwardly facing annular flange 47 , The clear inner diameter of the annular flange 47 corresponds to the outer diameter of the bottom part 14 , wherein the inner end face 17 of the annular flange 47 and the at least partially as Mating surface formed outer wall 18 of the bottom part 14 lie in a stacking position against each other. In addition, for sealing between the bottom part 14 and the adjoining top 15 a radially oriented support wall 19 provided, on the outside thereof 20 the ring flange 47 a housing part arranged adjacent in stacking position 9 Sealing flat side rests. The radially oriented outside 20 of the annular flange 47 can be subsequently edited to increase the accuracy of fit, in particular be over-turned.

The stacked housing parts 9 are sealed against each other by the aforementioned constructive measures, without the need for additional sealant. The stacked case 9 Form a package that is topped by the end plate 11 is limited and underside a bracket with a support plate 21 which is against the end plate 11 is tense (cf. 1 ). This is the in 4 recognizable, drawn in an extended position support plate 21 provided, which has a central opening 22 approximately congruent with the suction opening 13 of the housing part 9 has and the side flanges 23 with attached, by clamping bolts 24 has formed clamping elements. In upwardly angled position of the side flanges 23 grab the tension bolts 24 through diametrically arranged holes in the end plate 11 and are there by nuts 25 held ( 1 ). By this clamping bracket, the individual housing parts 9 pressed against each other, so that a tight connection is formed between the individual housing parts due to the special shaping.

From the 5 and 7 it can be seen that both the impeller 5 as well as the stator 10 are basically the same structure, with two mutually spaced, planar annular discs are provided with blades located therebetween. The upper annular disc forms a support disc, while the lower in function position, suction-side annular disc forms a cover plate.

In the 5 shown embodiment of an impeller 5 has two in the outer diameter same annular discs 26a . 26b on, which have different inner diameters. The ring disk 26b with the smaller inner diameter is with the drive shaft 6 connected while the larger inner opening of the other annular disc 26a the central suction opening forms. The between the two washers 26a . 26b arranged conveyor blades 27 are arranged spirally and extend from the larger inner diameter of the annular disc 26a to the outer edge of the impeller 5 ,

In 6 is a variant of an impeller 5a with view. shown from above, in which case the lower ring in functional position 26c in the outer diameter is formed larger than the upper-side annular disc 26d , The conveyor blades 27 extend into the supernatant region of the lower annular disc 26c over the outer edge of the adjacent, upper annular disc 26d to the outer edge of the annular disc 26c , By this measure, the delivery rate can be improved and a flow deflection in the axial direction favored. Inside the housing part 9 extends the lower annular disc 26c close to the housing wall of the housing part 9 ,

7 shows a perspective view of a stator 10 with a view of its side in functional position. It can be seen that the outer diameter of the upper annular disc 28b larger than that of the lower annular disc 28a of the stator 10 and that the inner diameter of the functional upper ring disc 28b larger than that of the lower annular disc 28a , The inner diameter of the upper annular disc 28b of the stator 10 corresponds approximately to the inner diameter of the lower annular disc 26a of the impeller 5 , Between the two washers 28a , b are guide vanes 29 arranged, which also like the conveyor blades 27 the wheels 5 . 5a spiral, but here in the opposite sense.

The blades, so both the conveyor blades 27 as well as the guide scoop 29 are located between the respective annular discs 26a , b, c, d, 28a , b and serve as a spacer as well as for the mechanical connection of the two washers. The shovels 27 . 29 are at least positively connected to the annular discs, preferably also cohesively. For the positive connection, the blades have projections on their sides facing the annular disks 30 on that in appropriately assigned breakthroughs 48 in the washers 26 . 28 intervention. In addition, the. Shovels and the annular discs cohesively, for example, be connected by welding.

The number of conveyor blades 27 can equal the number of guide vanes 29 may be, but optionally also more Leit-blades 29 as conveyor blades 27 be provided.

In 8th it can be seen that the stationary guide wheels 10 with their respective upper washers 28b with the outside of the bottom of the upper adjoining housing part 9 for example, are connected by spot welding.

The wheels 5 are with their upper washers 26b respectively 26d each with a hub-like intermediate piece 31 ( 11 . 12 ) connected to the drive shaft 6 attached and rotatably connected with it. For every impeller 5 is an intermediate piece 31 provided, wherein these are formed at their ends so that they engage in rotation with each other. At the bottom is an end adapter 31a ( 13 . 14 ) is provided, the lower end of a in the drive shaft 6 screwed fastening screw 32 is charged.

The topmost intermediate piece 31 engages with its upper end in a recess 33 a sleeve-shaped shaft recording 34 9 . 10 ). This wave recording 34 is located in the passage area of the drive shaft 6 in the pump part 4 and is non-rotatable with the drive shaft 6 connected. The wave recording 34 limited with their outside 35 one between this and one in the dip tube 3 located bearing bush 36 located sealing gap. This bushing 36 can be made of high-temperature resistant plastic, which can also be used for extremely high temperatures. The bearing bush 36 is in the lower end of the dip tube 3 pressed.

The wave recording 34 has at its lower end an enlarged diameter section 38 which is dimensioned in its outer diameter so that between its outer end face and the inner ends of the radially spaced hole wall of the pressure-side housing part, a passage gap 39 ( 8th ) is formed. With the size of this passage gap 39 can be a hydraulic adjustment to the engine power of the drive part 2 be made. The light passage of the passage gap 39 can be correspondingly larger at high engine power. With this passage gap, the maximum flow rate can be adjusted.

Between the lower ring disc 26 the wheels 5 and the bottom of the housing part 9 is a gap 37 ( 8th ), which may for example be 0.5 millimeters. This gap 37 forms a throttle gap through which a return flow of the fluid from the pressure to the suction side is largely avoided. The throttle effect is comparatively large, since the gap 37 over the radial length of the impeller 5 extends. This counteracts axial thrust forces.

The pump housing 8th is upper side by the end plate 11 locked. The end plate 11 has a central opening into which the dip tube 3 is screwed. Also, in the end plate 11 a passage opening 40 provided, at which the discharge nozzle 12 located.

The upper end of the dip tube 3 is with a flange part 42 connected, in turn, with a connection plate 41 connected is ( 1 and 2 ). The connection plate 41 forms the upper end of the bath tank, not shown here. At the connection plate 41 are still a level gauge 43 and a temperature meter 44 appropriate.

The housing parts 9 , the wheels 5 as well as the guide wheels 10 are expediently made of sheet metal, in particular stainless steel. The housing parts 9 are preferably formed as one-piece deep-drawn parts.

Claims (22)

Submersible pump unit ( 1 ) with a drive part ( 2 ) and one with this via a dip tube ( 3 ) connected, multistage pump part ( 4 ), wherein in the pump part at least one via a drive shaft ( 6 ) Wheels connected to the drive part ( 5 ) and a guide wheels ( 10 ) and wherein in the passage region of the drive shaft in the pump part, a shaft seal is provided, wherein the pump part ( 4 ) a pump housing ( 8th ) with at least two more identical, partially interlocking housing parts ( 9 ), wherein in at least one housing part ( 9 ) with the drive shaft ( 6 ) connected impeller ( 5 ) and a stator connected to the housing part ( 10 ) are located as a return and wherein between the suction side of the impeller and its pressure side a gap ( 37 ), characterized in that the pump part ( 4 ) one of several with at least two identical, cup-shaped and stackable housing parts ( 9 ) formed pump housing ( 8th ), that these housing parts ( 9 ) which are formed as one-piece deep drawn parts and have a stepped cross-section, are plugged into each other, partially engage each other and in these areas in stacking position directly sealingly against each other that clamping elements ( 24 ) are provided for holding together the housing parts arrangement and that between the suction side of the respective impeller ( 5 ) and its pressure side provided gap as a sealing gap ( 37 ) is formed between the suction side, an annular disc ( 26a ) forming impeller side and a substantially extending over the surface of the annular disc housing part is formed and extends in the radial direction from the suction side to the pressure side, that the impeller ( 5 ) and the stator ( 10 ) two spaced, planar annular discs ( 26a . 26b ; 26c . 26d ; 28a . 28b ) with blades in between ( 27 . 29 ) and that at the pump end of the dip tube ( 3 ) in the passage area of the drive shaft ( 6 ) into the pump part ( 4 ) a bearing bush ( 36 ) for supporting the drive shaft ( 6 ) is provided and in the pump part ( 4 ) protruding shaft portion is free of bearings. Submersible pump unit according to claim 1, characterized in that the housing parts ( 9 ) and the impeller ( 5 ) and the stator ( 10 ) made of sheet metal, in particular made of stainless steel. Submersible pump unit according to claim 1 or 2, characterized in that an annular disc ( 28b ) of the stator ( 10 ) with the outside of the bottom of the subsequent in the flow direction housing part ( 9 ) connected is. Submersible pump unit according to one of claims 1 to 3, characterized in that the housing parts ( 9 ) a bottom part ( 14 ) with central opening ( 16 ) as well as to the bottom part ( 14 ) subsequent upper part ( 15 ) with a larger outer diameter and with an inwardly pointing annular flange ( 47 ) exhibit. Submersible pump unit according to claim 4, characterized in that the clear inner diameter of the annular flange ( 47 ) the outer diameter of the bottom part ( 14 ) and that the inner end face ( 17 ) of the annular flange ( 47 ) and at least partially formed as a mating surface outer wall ( 18 ) of the bottom part ( 14 ) in stacking position sealingly against each other. Submersible pump unit according to claim 4 or 5, characterized in that between the bottom part ( 14 ) and the subsequent upper part ( 15 ) of the housing parts ( 9 ) a radially oriented support wall ( 19 ) is provided, on the outside ( 20 ) the annular flange ( 47 ) of a stacking position adjacent housing part ( 9 ) lies sealingly flat side. Submersible pump unit according to one of claims 4 to 6, characterized in that the radially oriented outer side ( 20 ) of the annular flange ( 47 ) edited later to increase the accuracy of fit, preferably over-turned. Submersible pump unit according to one of claims 1 to 7, characterized in that the annular discs ( 26a . 26b ) of the impeller ( 5 ) have approximately the same outer diameter and different inner diameter and that the associated stator ( 10 ) facing annular disc ( 26b ) of the impeller ( 5 ) rotatably with the drive shaft ( 6 ) and the other annular disc ( 26a ) has a reduced inner diameter to form a suction opening. Submersible pump unit according to one of claims 1 to 7, characterized in that the annular discs ( 26c . 26d ) of the impeller ( 5 ) have different outer diameter, that the suction side, a cover disc forming annular disc ( 26a ) extends with its outer edge to close to the housing wall and that the blades ( 27 ) in the supernatant region of the cover disc ( 26c ) over the outer edge of the adjacent annular disc ( 26d ), preferably extend to the outer edge of the cover plate. Submersible pump unit according to one of claims 1 to 9, characterized in that the annular discs ( 28a . 28b ) of the stator ( 10 ) have different inner and outer diameter that with the outside of the bottom of the housing part ( 9 ) connected annular disc ( 28b ) is formed approximately congruent to the ground and arranged on this and that the other annular disc ( 28a ) of the stator ( 10 ) approximately congruent to the adjacent annular disc ( 26b ) of the impeller ( 5 ) is formed and arranged. Submersible pump unit according to one of claims 1 to 10, characterized in that the respective spaced between the two spaced annular discs ( 28a . 28b ; 26a . 26b ) of the stator ( 10 ) and the impeller ( 5 ) arranged guide vanes ( 29 ) or conveying blades ( 27 ) Form connecting elements for the two annular discs, which are positively and preferably materially connected to the annular discs. Submersible pump unit according to one of claims 1 to 11, characterized in that the guide vanes ( 29 ) and the conveyor blades ( 27 Have on their sides facing the annular discs projections for positive engagement in openings of the annular discs. Submersible pump unit according to claim 11 or 12, characterized in that the cohesive connection between the annular discs and the blades by welding, for example by laser welding, inert gas welding, beam welding, resistance pressure welding or the like is provided. Submersible pump unit according to one of claims 1 to 13, characterized in that the number of conveying blades ( 27 ) of the impeller ( 5 ) is less than or equal to the number of guide vanes ( 29 ) of the stator ( 10 ) and that preferably per impeller ( 5 ) five blades and per stator ( 10 ) seven blades are provided. Submersible pump unit according to one of claims 1 to 14, characterized in that the pump housing ( 8th ) an upper end plate ( 11 ), on which the housing parts ( 9 ) are attached and the one passage opening ( 40 ) with a discharge nozzle ( 12 ) having. Submersible pump unit according to one of claims 1 to 15, characterized in that as clamping elements clamping bolt ( 24 ) for holding the housing parts arrangement and the end plate ( 11 ) are provided, which the flange-like projecting end plate ( 11 ) and with a housing parts arrangement underside support plate ( 21 ) are connected. Submersible pump unit according to one of claims 1 to 16, characterized in that in the passage area of the drive shaft in the pump part ( 4 ) a sleeve-shaped shaft receptacle ( 34 ) is arranged, the non-rotatably with the drive shaft ( 6 ) and with its outside ( 35 ) one between this and one in the dip tube ( 3 ) located bushing ( 36 ) limited sealing gap. Submersible pump unit according to claim 17, characterized in that the bearing bush ( 36 ) in the lower end of the dip tube ( 3 ) is pressed. Submersible pump unit according to claim 17 or 18, characterized in that the bearing bush ( 36 ) consists of high temperature resistant plastic. Submersible pump unit according to one of claims 17 to 19, characterized in that the projecting into the pump chamber part of the sleeve-shaped shaft receiving ( 34 ) a diameter predeterminable section ( 38 ) for determining the passage gap ( 39 ) between this section and the radially spaced hole wall of the pressure-side housing part ( 9 ) having. Submersible pump unit according to one of claims 17 to 20, characterized in that the pump part ( 4 ) projecting, inner end of the sleeve-shaped shaft receptacle ( 34 ) for coupling with at least one intermediate piece ( 31 . 31a ) for holding the impeller ( 5 ) is trained. Submersible pump unit according to one of claims 17 to 21, characterized in that the shaft receptacle ( 34 ) at its inner end and the intermediate piece ( 31 . 31a ) Have coupling elements for positive coupling with each other and optionally with a further intermediate piece at both ends.

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