DE102019211828A1 - Pump arrangement - Google Patents

Abstract

The invention relates to a pump arrangement (1), comprising: a pump (6) with at least one pump rotor, and an electric motor (2), comprising a stator (16) and a rotor (4), the rotor (4) of the The electric motor (2) is firmly connected to the at least one pump rotor via a toothing and forms a rotor unit.

Description

The most commonly used electric motor in the automotive sector is the radial, brushless DC motor. This type of motor is used in a wide range of products in the automotive industry, for example as an actuator for drive elements, control units and pump drives for cooling and control functions. For example, a radial, brushless DC motor can be used to operate a volumetric pump (gerotor pump) for different applications (oil cooling, hydraulic control functions).

The U.S. 5,145,329 A discloses a homoplanar brushless electric rotor comprising a housing assembly defining a substantially closed cavity and a fluid inlet opening. Inner and outer gerotor pump gears are eccentric to relative rotation within the cavity, whereby a working fluid received at the inlet port at a low pressure is discharged from the outlet port at a high pressure. A plurality of alternately radially polarized, circumferentially aligned permanent magnets are carried by one of the pump gears for rotation therewith. A stator with windings which are distributed in the circumferential direction and axially spaced from the permanent magnets cooperate electromagnetically with them in order to cause their rotation when the windings are electrically excited by a drive circuit.

The object of the present invention is to provide an improved pump arrangement.

• - eine Pumpe mit zumindest einem Pumpenrotor, und
• - einen Elektromotor, umfassend einen Stator und einen Rotor,

wobei der Rotor des Elektromotors mit dem zumindest einen Pumpenrotor über eine Verzahnung fest verbunden ist und eine Rotoreinheit bildet.The object is achieved according to the invention by the features of claim 1. A pump arrangement according to the invention comprises:

• - a pump with at least one pump rotor, and
• - an electric motor comprising a stator and a rotor,

wherein the rotor of the electric motor is firmly connected to the at least one pump rotor via a toothing and forms a rotor unit.

In the prior art, a shaft on the rotor is provided for the transmission of rotary movements from a radial, brushless DC motor to a pump, which shaft is held in a tightly tolerated position by means of bearings, the bearings being held in specially provided receptacles in a housing or bearing bracket or end shield will.

The fixed connection of the rotor of the electric motor to the at least one pump rotor via a toothing and the rotor unit formed in this way means that a shaft between the rotor of the motor and a pump rotor can be omitted. As a result, there is also no need for shaft bearings.

The elimination of bearings means that no bearing bracket or end shield is required. This reduces the number of individual parts required and the pump arrangement becomes smaller, simpler and more cost-effective. The smaller number of individual parts simplifies the assembly process and the pump arrangement can be made smaller than in the prior art.

In one embodiment, the electric motor is designed as a radial, brushless direct current motor, the rotor of which is arranged radially inside the stator.

In one embodiment, the pump is designed as a gerotor pump with an outer gear and an inner gear meshing with it, the outer gear being firmly connected as a pump rotor to the rotor of the electric motor.

In one embodiment, one or more permanent magnets are arranged in or on the rotor.

In one embodiment, the rotor comprises an annular arrangement of angularly spaced apart permanent magnets, which are held on a frame.

In one embodiment, a radial outer side of the outer gear has ribs which are aligned in the axial direction, between which spaces for receiving the permanent magnets are formed in this way.

In one embodiment, a rotor protection ring is provided for radial reception of the rotor and / or a stator protection ring is provided for radial reception in the interior of the stator.

In one embodiment, the rotor guard ring has axially extending slots to engage the ribs of the outer gear so that the rotor, rotor guard ring and outer gear are coupled for common rotation.

In one embodiment, the rotor protection ring is formed as part of the outer gear and / or the stator protection ring is formed as part of a housing which receives the stator.

In one embodiment, a sensor magnet is arranged in or on the inner gear, a sensor for detecting a magnetic flux caused by the sensor magnet being provided in order to determine a rotational position and speed of the inner gear.

In one embodiment, an electronic voltage supply and control module is also provided, which is at least electrically connected to the stator. Furthermore, the electronic voltage supply and control module can be connected to an external control and voltage supply via an interface, for example a plug connector.

In one embodiment, the electronic power supply and control module is also connected to the sensor.

In one embodiment, the electronic power supply and control module is arranged in a chamber which is arranged axially on one side of the pump.

In one embodiment, the electronic voltage supply and control module is arranged to the side of the pump.

The pump arrangement can be used, for example, for oil cooling or for hydraulic actuating functions in a vehicle.

• 1 eine schematische Querschnittsansicht einer Pumpenanordnung,
• 2 eine schematische Ansicht einer Ausführungsform einer Pumpenanordnung,
• 3 eine schematische Explosionsdarstellung der Pumpenanordnung,
• 4 eine weitere schematische Explosionsdarstellung eines Teils der Pumpenanordnung, und
• 5 eine schematische Explosionsdarstellung eines Teils einer weiteren Ausführungsform der Pumpenanordnung.

Embodiments of the invention are explained in more detail with reference to drawings. Show:

• 1 a schematic cross-sectional view of a pump arrangement,
• 2 a schematic view of an embodiment of a pump arrangement,
• 3 a schematic exploded view of the pump arrangement,
• 4th a further schematic exploded view of part of the pump arrangement, and
• 5 a schematic exploded view of part of a further embodiment of the pump arrangement.

Corresponding parts are provided with the same reference symbols in all figures.

1 Figure 10 shows a cross-sectional view of a pump assembly 1 , comprising a radial, brushless DC motor 2 in one housing 3 , for example a die-cast housing that is also used, for example, as a heat sink for electronic assemblies. The DC motor 2 includes one within a stator 16 running permanent magnet rotor 4th standing on a wave 5 is attached to a pump 6 , for example drives a gerotor pump. The wave 5 is in the housing 3 by means of two bearings 7.1 , 7.2 stored, for example one in the housing 3 bearing held by means of a press fit 7.1 on one side and by means of one in a bearing bracket 8th held camp 7.2 on the other hand. The pump 6 is between the housing 3 of the DC motor 2 and a pump housing flanged to it 9 locked in. An electronic power supply and control module 10 is on the housing 3 attached and has a connector 11 for power supply and communication as well as a sensor for determining the rotational position and speed of the shaft 5 via a sensor magnet 12 on. The electronic power supply and control module 10 is with a cover 13 , for example made of sheet metal, covered. All contact points between components, where substances between the environment and the inside of the device can be replaced, are provided with seals, for example wet seals or O-rings.

2 Figure 3 is a schematic view of one embodiment of a pump assembly 1 , comprising a radial, brushless DC motor 2 with an integrated pump 6 . The DC motor 2 is in a housing 3 , for example a die-cast housing, which can be used, for example, as a heat sink for electronic assemblies. The DC motor 2 includes one within a stator 16 running permanent magnet rotor 4th . The rotor 4th of the DC motor 2 is with an outer gear 15th the pump designed as a gerotor pump 6 connected for common rotation. The pump functionality is achieved by means of the magnetic flux from the stator 16 to in or on the outer gear 15th arranged permanent magnets 14th achieved, the outer gear 15th an internal gear 17th rotates to pump a working fluid. A sensor magnet 12 is in the inner gear 17th arranged to create a magnetic flux in a sensor in an electronic power supply and control module 10 to determine the rotational position and speed of the inner gear 17th to cause. The electronic power supply and control module 10 is on a pump cover 13 attached and has a connector 11 for power supply and communication as well as a sensor for determining the rotational position and speed of the inner gear 17th over the sensor magnet 12 on. The pump cover 13 separates the electronic power supply and control module 10 from the pump 6 . The electronic power supply and control module 10 is with another cover 26th , for example made of sheet metal, covered. All contact points between components at which substances could be exchanged between the environment and the interior of the device can be sealed with seals 21st be provided, for example wet seals or O-rings.

Unlike the in 1 The embodiment shown requires the in 2 embodiment shown neither the shaft 5 nor the corresponding bearings 7.1 , 7.2 since the stator 16 , the rotor 4th , the outer gear 15th and the inner gear 17th in one and the same housing 3 are arranged, which of the pump cover 13 is closed, the stator 16 against the pump 6 and the working fluid therein is sealed. In the case 3 are two connections 23 the pump 6 provided, which can serve as inlet and outlet.

3 Figure 3 is an exploded schematic view of the pump assembly 1 . This is shown down to the connections 23 closed housing 3 , the outer gear 15th with the internal gear arranged therein 17th and the sensor magnet 12 . The rotor 4th comprises an annular arrangement of angularly spaced permanent magnets 14th working on a scaffolding 29 can be held. A radial outside of the outer gear 15th is due to ribs aligned in the axial direction 30th divided, between which in this way gaps are created to accommodate the permanent magnets 14th are provided. The rotor 4th is this way with the outer gear 15th interlocked. A rotor protection ring 27 is designed so that it has the rotor 4th can accommodate and has axially extending slots to the ribs 30th of the outer gear 15th engage so that the rotor 4th , the rotor protection ring 27 and the outer gear 15th rotate together.

The stator 16 can be formed at least approximately in the form of a hollow cylinder, such that a stator protection ring in its interior 28 can be included, within which the rotor 4th with the rotor protection ring 27 and the outer gear 15th can be included. The stator protection ring 28 can be used to seal against the housing 3 and opposite the pump cover 13 be designed so that the stator 16 before inside the stator protection ring 28 located fluids is protected. Furthermore, the electronic power supply and control module 10 who have favourited cover 26th , the connector 11 as well as a number of screws 22nd for assembling the pump arrangement 1 pictured.

Between the pump cover 13 and the case 3 can be a sealing ring 21st be provided. Furthermore, a sealing ring 21st between the pump cover 13 and the cover 26th be provided. Two more sealing rings 21st can between the stator 16 and the case 3 on one axial side of the stator 16 and between the stator 16 and the pump cover 13 on an opposite axial side of the stator 16 be provided.

4th Figure 3 is another exploded schematic view of part of the pump assembly 1 .

The pump arrangement 1 can be divided into the following sub-units: - a rotor unit comprising the outer gear 15th , the rotor 4th with the permanent magnets 14th and the scaffolding 29 , as well as the rotor protection ring 27 ; - A stator unit comprising the stator 16 with a metal core and turns, for example copper turns, and the stator protection ring 28 ; an internal pump unit comprising the internal gear 17th with a recess for the sensor magnet 12 , as well as the sensor magnet 12 .

For assembling the pump arrangement 1 becomes the rotor 4th with the outer gear 15th the pump 6 connected by the permanent magnets 14th with the spaces between the ribs 30th be brought into engagement, for example, pressed in. Then the rotor protection ring 27 above the rotor 4th arranged.

The stator protection ring 28 gets into the stator 16 used, for example pressed in. The role of the rotor protection ring 27 and the stator protection ring 28 is to create a separation area that allows contact between the stator 16 , for example overmolding of the stator 16 , and the permanent magnet 14th of the rotor 4th prevented so that they do not wear out due to friction.

5 Figure 3 is an exploded schematic view of part of another embodiment of the pump assembly 1 .

The embodiment shown is similar to that in FIGS 2 to 4th embodiment shown. However, the rotor protection ring 27 and the stator protection ring 28 not designed as separate parts. Instead is the rotor protection ring 27 as part of the outer gear 15th formed and the stator protection ring 28 is as part of the housing 3 educated. With the rotor protection ring 27 therefore the slots running in the axial direction can be omitted.

• Der Rotor 4 wird mit dem äußeren Zahnrad 15 der Pumpe 6 verbunden, indem die Permanentmagnete 14 in den Rotorschutzring 27 eingeführt und mit den Zwischenräumen zwischen den Rippen 30 in Eingriff gebracht werden, beispielsweise eingepresst werden.

The assembly of this embodiment is simplified accordingly:

• The rotor 4th is with the outer gear 15th the pump 6 connected by the permanent magnets 14th into the rotor protection ring 27 inserted and with the spaces between the ribs 30th be brought into engagement, for example, pressed in.

The stator 16 is in the housing 3 used, for example, pressed in, with this Way at the same time the stator protection ring 28 in the stator 16 is used.

The inner gear 17th is in the outer gear 15th used.

This in 5 illustrated embodiment is therefore simpler than that in the 2 to 4th illustrated embodiment and comes with fewer parts. In addition, at least one sealing ring can be used 21st be waived.

In embodiments not shown, the sensor magnet 12 and the sensor can be dispensed with.

In embodiments that are not shown, a vane pump or a centrifugal pump can be provided instead of a gerotor pump.

In all embodiments, the cover 26th be waived. Instead, for example, the electronic voltage supply and control module 10 be arranged in a potting.

List of reference symbols

1

Pump arrangement

2

DC motor

3

casing

4th

rotor

5

wave

6th

pump

7.1

camp

7.2

camp

8th

Bearing bracket

9

Pump housing

10

electronic power supply and control module

11

Connectors

12

Sensor magnet

13

Pump cover

14th

Permanent magnet

15th

outer gear

16

stator

17th

inner gear

21st

Sealing ring, seal

22nd

screw

23

connection

26th

cover

27

Rotor protection ring

28

Stator protection ring

29

framework

30th

rib

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• US 5145329 A [0002]

Claims (10)

Pump arrangement (1) comprising: - A pump (6) with at least one pump rotor, and - An electric motor (2), comprising a stator (16) and a rotor (4), the rotor (4) of the electric motor (2) being firmly connected to the at least one pump rotor via a toothing and forming a rotor unit. Pump arrangement (1) according to Claim 1 wherein the electric motor (2) is designed as a radial, brushless direct current motor (2), the rotor (4) of which is arranged radially inside the stator (16). Pump arrangement (1) according to one of the Claims 1 or 2 , wherein the pump (6) is designed as a gerotor pump with an outer gear (15) and an inner gear (17) meshing with it, the outer gear (15) as a pump rotor with the rotor (4) of the electric motor (2 ) is firmly connected. Pump arrangement (1) according to one of the preceding claims, wherein one or more permanent magnets (14) are arranged in or on the rotor (4). Pump arrangement (1) according to Claim 4 wherein the rotor (4) comprises an annular arrangement of angularly spaced permanent magnets (14) which are held on a frame (29). Pump arrangement (1) according to Claim 5 , wherein a radial outer side of the outer gear (15) has ribs (30) aligned in the axial direction, between which spaces for receiving the permanent magnets (14) are formed in this way. Pump arrangement (1) according to one of the preceding claims, wherein a rotor protection ring (27) is provided for radial reception of the rotor (4) and / or wherein a stator protection ring (28) is provided for radial reception inside the stator (16). Pump arrangement (1) according to Claim 7 wherein the rotor protection ring (27) has axially extending slots to engage the ribs (30) of the outer gear (15) so that the rotor (4), the rotor protection ring (27) and the outer gear (15 ) are coupled for common rotation. Pump arrangement (1) according to Claim 7 , wherein the rotor protection ring (27) is formed as part of the outer gear (15) and / or the stator protection ring (28) is formed as part of a housing (3) which receives the stator (16). Pump arrangement (1) according to one of the Claims 3 to 9 , wherein a sensor magnet (12) is arranged in or on the inner gear (17), a sensor for detecting a magnetic flux caused by the sensor magnet (12) for determining a rotational position and speed of the inner gear (17).

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