DE102013226974A1 - Tumble pump with shaft mounted in the stator - Google Patents

Abstract

A tumble pump (10) comprises a pump stator (28) attached to a housing (12) of the tumble pump and a pump rotor (48) guided in the pump stator (28), which is driven by a drive shaft (34) by means of an oblique face (46) in that it wobbles with its rotor axis about a drive axis of the drive shaft (34), wherein the drive shaft (34) projects through the pump rotor (48) through a passage opening (49) and is mounted in a bearing of the pump stator (28).

Description

Field of the invention

The invention relates to a tumble pump.

Background of the invention

An embodiment of a tumble pump is from the WO 2008/110155 A1 known. In this case, an offset obliquely on a pump shaft of the tumble pump rotor is rotated by rotation of the pump shaft relative to a pump stator in a tumbling motion, so that formed between the pump rotor and the pump stator pump chambers are increased in volume and reduced. These chambers are connected to an input and an output of the tumble pump, so that a fluid is conveyed by the tumble pump.

On the pump shaft act radial and axial forces, for example, as in the WO 2008/110155 A1 shown to be received by a radial plain bearing for the pump shaft. The sliding bearing gap also serves to seal against the compressed fluid, resulting in a relatively long sliding bearing.

Summary of the invention

With the invention, a tumble pump can be provided with a shortened length. Furthermore, friction losses can be reduced with the tumble pump according to the invention.

These advantages can be achieved with the subject matter of the independent claims. Further embodiments of the invention will become apparent from the dependent claims and from the following description.

The invention relates to a tumbling pump for conveying fluid, for example fuel.

According to one embodiment of the invention, the tumble pump comprises a pump stator attached to a housing of the tumble pump and a pump rotor guided in the pump stator. which is driven by a drive shaft by means of an oblique end face such that it wobbles with its rotor axis about a drive axis of the drive shaft. The drive shaft protrudes through the pump rotor through a through hole and is mounted in a bearing of the pump stator.

A rotation of the drive shaft may lead to a tumbling of the pump rotor with respect to the pump stator, whereby pump chambers formed between the pump stator and the pump rotor by a toothing be enlarged and reduced so that a fluid is conveyed by the tumble pump. For example, the pump stator and the pump rotor may have a cycloid-shaped toothing.

In the tumble pump, the drive shaft is mounted in the pump stator. This storage can be done in the radial and optionally in the radial direction. At a further end (the bearing in the pump stator opposite), the drive shaft may be mounted in a housing part of the pump housing. Both bearings, or at least the bearing in the pump stator, can be designed as plain bearings. Thus, on the one hand radial forces can be absorbed by the two bearings and on the other hand, the sealing function can be decoupled between the mounted on the drive shaft pump shaft and the pump housing from the storage.

Since the drive shaft can be stored at its ends (and not in the middle), a tilting of the drive shaft can be reduced.

The bearing in the stator (and also the other bearings) can be designed with a smaller radius than the radius of the pump shaft, which is intended as a sealing point. This can lead to lower slide bearing speeds, which can counteract the generation of heat and friction.

According to one embodiment of the invention, the oblique face is provided by a pump shaft, which is positively placed on the drive shaft. A positive connection of the pump shaft directly to the drive shaft can spare a driver. Since it is possible to run the pump shaft without contact in the housing, the friction can be reduced. The arrangement may also be more resistant to particles that can pass the pump shaft passing through a sealing point, since the use of a metallic sleeve in the housing is possible.

The drive shaft may have an additional sliding bearing (for example at an end opposite the pump stator). As a result, radial forces of a drive motor can be decoupled from radial forces on the pump shaft.

According to one embodiment of the invention, the drive shaft carries a rotor of an electric motor as a drive. The drive shaft may then be mounted in a housing part of the tumble pump, which carries a stator of the electric motor. For example, the drive shaft may be a one-piece shaft, which is mounted at its two ends in the stator and in a housing part.

According to one embodiment of the invention, the tumble pump further comprises a spring for pressing the drive shaft in the direction of the pump stator. In this way, the sealing function between the spherical surfaces of the pump rotor and the pump stator and the toothing can be adjusted or increased, since the pump rotor is pressed via the drive shaft and the pump shaft in the direction of the pump stator.

For example, this axial force can be generated by carbon brushes of the electric motor (which have a spring).

According to one embodiment of the invention, the stator of the electric motor is offset in relation to the rotor of the electric motor in the axial direction such that when operating the motor, the drive shaft is moved by electromagnetic forces in the direction of the pump stator. The axial force can also be generated directly by the electric motor, so that it is possible to dispense with a separate spring.

According to one embodiment of the invention, the drive shaft on two coupled drive shaft parts. A part of the drive shaft (a motor shaft) may support the rotor of an electric motor. Another, second part of the drive shaft can carry the pump shaft. For example, the second part of the drive shaft may be mounted in the pump stator and in a further housing part. The two parts of the drive shaft can be positively coupled by means of a pin. In a two-piece drive shaft radial forces and tilting moments can be particularly well received, since they can be distributed to several bearings for the drive shaft parts.

According to one embodiment of the invention, the passage opening has inside larger diameter than the drive shaft. Thus, the pump rotor can tumble around the drive shaft.

According to a first embodiment of the invention, the oblique end face of a drive of the tumble pump away. In this case, the oblique end face is arranged on a side facing away from the electric motor of the tumble pump pump shaft. In this first embodiment, the toothing of the pump stator faces the electric motor. For example, the pump shaft and the pump rotor are accommodated (in this order) between a drive of the pump and the pump stator. In this case, the spherical surfaces of the pump rotor away from the drive.

According to a second embodiment of the invention, the oblique end face to a drive of the tumbling pump. In this case, the oblique end face is arranged on a side facing the electric motor of the tumble pump side of the pump shaft. In this second embodiment, the toothing of the pump stator is arranged on the side facing away from the electric motor. For example, the pump stator, the pump shaft and the pump rotor are accommodated (in this order) between a drive and a housing end part. In this case, the spherical surfaces of the pump rotor point towards the drive.

One end of the drive shaft may be supported in the housing end part. Further, it is possible that one end of the drive shaft or a drive shaft part is mounted in a further housing part, which also receives a drive of the tumble pump, such as an electric motor.

Brief description of the figures

Embodiments of the invention will now be described in detail with reference to the accompanying drawings.

1 shows a cross section through a tumble pump according to an embodiment of the invention.

2 shows a cross section through a tumble pump according to another embodiment of the invention.

3 shows a cross section of a portion of a tumble pump according to another embodiment of the invention.

Basically, identical or similar parts are provided with the same reference numerals.

Detailed description of embodiments

1 shows a tumbling pump 10 that a housing 12 comprising, which is composed of a plurality of housing parts, an end portion 14 has an inlet 16 the tumble pump 10 on. A carrier part 16 that in the end part 14 plugged in, carries a drive (electric motor) 18 for the tumble pump 10 , A sealing part 20 provides a seal between a low pressure area 24 and a high pressure area 22 ready and another end part 26 at the same time serves as a pump stator 28 , The housing parts 14 . 16 . 20 and 26 be from a sheet metal ring 30 held together.

A wave arrangement 32 includes a drive shaft 34 , which at one end in the carrier part 16 and at the other end in the pump stator 28 by means of plain bearings 36 . 38 is stored. The one-piece drive shaft 34 carries a rotor 40 of the electric motor 18 standing in one on the support part 16 added stator 42 is included. Next carries the drive shaft 34 a pump shaft 44 , the form-fitting on the drive shaft 34 is plugged. The pump shaft 44 is in the sealing part 20 guided such that a seal between the high pressure area 22 and the low pressure area 24 is reached. Between the pump shaft 44 and the sealing part 20 can be another plain bearing 45 be formed.

The pump shaft 34 makes a weird (see 2 ) Face 46 ready with a pump rotor 48 cooperates and is mechanically coupled with this. The pump rotor 48 and the pump stator 28 make spherical surfaces 50 . 52 ready, which can slide on each other, being between the inner spherical surfaces 50 and the outer spherical surfaces 52 by a toothing between the pump rotor 48 and pump stator 28 chambers 54 (please refer 3 ) formed upon rotation of the pump rotor 48 in the pump stator 28 zoom in and out and thus develop a pumping action, so that a fluid from the low pressure area 24 in the high pressure area 22 is encouraged.

The pump rotor 48 indicates at its end face 46 facing away from a toothing on one on the pump stator 28 trained toothing combs. Between the toothing of the pump rotor 48 and the teeth of the pump stator 28 are the chambers 54 educated. The toothing of the pump rotor 48 and the teeth of the pump stator 28 For example, are designed as a cycloid teeth, but can also be a different teeth.

The pump rotor has a passage opening 49 on, through which the drive shaft 34 protrudes. The passage opening 49 has a larger diameter than the drive shaft 34 in this area, the drive shaft 34 can, as in the 1 shown to have a smaller diameter in this area, as in the area of the pump shaft 44 ,

The drive shaft 34 Can by a spring 51 be acted upon in the axial direction with force, so that on the (positively connected) pump shaft 44 the pump rotor 48 against the pump stator 28 is pressed. This may alternatively or additionally by a corresponding offset of the rotor 40 of the electric motor 18 opposite the stator 42 respectively.

The 2 shows a second embodiment of the tumble pump 10 in which the components pump shaft 34 , Pump rotor 48 and pump stator 28 compared to the 1 are arranged vice versa. Next, the drive shaft 34 two shaft parts 34a and 34b on. High pressure and low pressure areas are therefore also arranged in reverse.

The housing 12 has a support part 16 ' on, that's the drive 18 or the stator 42 , the pump stator 28 and an end part 20 ' carries on which the pump stator 28 seated. The opposite end part 14 with the inlet 16 is with the carrier part 16 ' by means of an essay 56 connected.

The end part 20 ' has another seal for the high pressure area 24 towards the environment, for example, with a between the support part 16 ' and the end part 20 ' extending sealing ring 58 can be realized.

The drive shaft 34 includes a first part 34a who is the rotor 40 of the electric motor 18 wears and with a second part 34b that is the pump rotor 48 carries over a pin 60 is positively coupled. The first part 34a is by means of a sliding bearing 36 in the case 12 stored. The second part 34b is in the stator 28 in a first sliding bearing 38 and in the end part 20 ' stored in a second sliding bearing.

The 3 shows a section of a tumble pump analogous to 2 , It can be seen that the pen 60 on the drive shaft part 34b on the stator 28 can be discontinued, so that the drive shaft part 34b in an axial direction (from the drive 18 away).

In the 3 is also shown that the pump shaft at least one channel 64 having, with the high pressure area 22 communicates and at least one channel 66 that with the low pressure area 24 communicates.

Upon rotation of the rotor 48 can remove fluid from the low pressure area via the duct 66 in a pump chamber 54 is transported by the rotor about the axis of the shaft and then by reducing the pump chamber 54 because of the pump rotor 48 stands diagonally in the canal 64 pressed.

In addition, it should be noted that "encompassing" does not exclude other elements or steps, and "a" or "an" does not exclude a multitude. It should also be appreciated that features or steps described with reference to any of the above embodiments may also be used in combination with other features or steps of other embodiments described above. Reference signs in the claims are not to be considered as limiting.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2008/110155 A1 [0002, 0003]

Claims (10)

Tumble pump ( 10 ), comprising: one on a housing ( 12 ) of the tumble pump attached pump stator ( 28 ); one in the pump stator ( 28 ) guided pump rotor ( 48 ), which is driven by a drive shaft ( 34 ) by means of an oblique face ( 46 ) is driven such that it with its rotor axis about a drive axis of the drive shaft ( 34 ) staggers; characterized in that the drive shaft ( 34 ) the pump rotor ( 48 ) through a passage opening ( 49 ) and in a bearing of the pump stator ( 28 ) is stored. Tumble pump ( 10 ) according to claim 1, wherein the oblique face ( 46 ) from a pump shaft ( 44 ) is provided which positively on the drive shaft ( 34 ) is attached. Tumble pump ( 10 ) according to one of claims 1 or 2, wherein a drive shaft ( 34 ) a rotor ( 40 ) of an electric motor ( 18 ) and the drive shaft ( 34 ) in a housing part ( 16 . 16 ' ) of the tumble pump, which has a stator ( 42 ) of the electric motor ( 18 ), is stored. Tumble pump ( 10 ) according to one of the preceding claims, further comprising: a spring ( 51 ) for pushing the drive shaft ( 34 ) in the direction of the pump stator ( 28 ). Tumble pump ( 10 ) according to claim 3 or 4, wherein the stator ( 42 ) of the electric motor ( 18 ) so opposite to the rotor ( 40 ) of the electric motor ( 18 ) is offset in the axial direction that during operation of the electric motor, the drive shaft ( 34 ) by electromagnetic forces in the direction of the pump stator ( 28 ) is moved. Tumble pump ( 10 ) according to one of the preceding claims, wherein the passage opening ( 49 ) has a larger diameter than the drive shaft ( 34 ). Tumble pump ( 10 ) according to one of the preceding claims, wherein the drive shaft ( 34 ) two coupled drive shaft parts ( 34a . 34b ) having. Tumble pump ( 10 ) according to one of the preceding claims, wherein the oblique face ( 46 ) on an electric motor ( 18 ) of the tumble pump facing or facing away from the pump shaft ( 44 ) is arranged. Tumble pump ( 10 ) according to one of the preceding claims, wherein the pump stator ( 28 ), the pump shaft ( 44 ) and the pump rotor ( 48 ) seen in the direction of the drive shaft between the electric motor ( 18 ) and a housing termination ( 20 ' ) are included; and / or wherein the drive shaft ( 34 ) in the housing end part ( 20 ' ) is stored. Tumble pump ( 10 ) according to one of the preceding claims, wherein the pump stator ( 28 ) a plain bearing ( 38 ) for the drive shaft ( 34 ) having.

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