EP2619886A2

EP2619886A2 - Pump having an electric motor

Info

Publication number: EP2619886A2
Application number: EP11749428.6A
Authority: EP
Inventors: Josef Frank; Alexander Fuchs; Ralf Rainer; Robert Pichler
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2010-09-23
Filing date: 2011-08-31
Publication date: 2013-07-31
Also published as: WO2012038214A3; CN105960749B; WO2012038214A2; CN105960749A; DE102010041240A1

Abstract

The invention relates to a pump having an electric motor, in particular for a motor vehicle, for conveying a fluid, comprising an impeller having conveying elements, by which a rotational movement about an axis of rotation can be executed, a working chamber present on the impeller, an electric motor having a stator (13) and a rotor, wherein the stator (13) comprises a soft magnetic core (32), in particular a laminated stack (33), windings (14) as electromagnets (15) and electric contact elements (34), a housing, wherein the impeller having the conveying elements and the electric motor is arranged within the housing and the pump is preferably integrated in the electric motor or vice versa, by the rotor being formed by the impeller, wherein the electric contact elements (34) are enclosed by a plug-in collar (55) as a sealing sleeve (31) and the plug-in collar (55) is sealed off with respect to the housing by at least one seal (53) on the plug-in collar (55).

Description

description

title

Pump with electric motor

The present invention relates to a pump with electric motor according to the preamble of claim 1, a method for producing a pump with electric motor according to the preamble of claim 1 1 and a

High-pressure injection system according to the preamble of claim 15.

State of the art

Pumps with electric motor are used for a wide variety of technical

Applications for conveying a fluid used. For example, fuel pumps are used to deliver fuel to an internal combustion engine. The electric motor of the pump comprises a stator and a rotor with

Permanent magnets. In this case, the electric motor and the pump is arranged within a housing. Within the housing thus creates a space, in particular a working space in which there is the fluid to be pumped. Outside the housing materials may be arranged, for example

Liquids, such as salt water, whose penetration is to be prevented within the housing of the pump, because they can cause damage to the stator by corrosion, for example. Also solids, such as

Dust or minute particles can cause damage to both the electric motor and the pump as it enters the enclosure enclosed by the housing. For this reason, it is necessary to seal the pump with the electric motor permanently fluid-tight, on the one hand to prevent leakage of the fluid to be pumped, for example, fuel outside the housing and on the other hand harmful substances or media from penetrating into the housing enclosed interior with the pump and the electric motor to prevent.

DE 299 13 367 U1 shows an internal gear pump with at least one internally toothed ring gear and a meshing, externally toothed

Impeller, with or without a sickle, and with an electric drive, which is formed by the ring gear is arranged inside a rotor of a brushless electric motor and the rotor adjacent to a stator, wherein the rotor containing the ring gear outside of a bearing or a

Sliding bearing is rotatably supported, wherein the stator is shielded and sealed relative to the rotor and the interior of the pump characterized in that the located between the stator and rotor bearings or bearings for liquid impermeable and is sealed at its two end faces each with a cover.

DISCLOSURE OF THE INVENTION Advantages of the invention Pump having an electric motor, in particular for a motor vehicle, for conveying a fluid, comprising an impeller with conveying elements, of which a rotational movement about a rotation axis is executable, an existing on the impeller working space, an electric motor with a stator and a rotor, wherein the stator comprises a soft magnetic core, in particular a laminated core, windings as electromagnets and electrical contact elements, a housing, wherein the impeller with the conveying elements and the electric motor are arranged within the housing and preferably the pump is integrated in the electric motor or vice versa in that the rotor is formed by the impeller, wherein the electrical contact elements are enclosed by a plug-in collar as a sealing sleeve and is sealed with at least one seal on the plug collar of the plug collar with respect to the housing.

Thus, the plug collar can be easily sealed with the electrical contact elements independent of the remaining seal of the housing. In this case, the electrical contact elements on the plug collar are preferably only partially enclosed by the plug collar or the sealing sleeve, so that the Ends of the electrical contact elements protrude out of the plug collar and form an electrical interface or a plug for making electrical contact with the electrical contact elements. In an additional embodiment, the stator is complementary to the

Plug-in collar at least partially, in particular completely, enclosed by a sealing sheath and / or the sealing sheath is as an encapsulation or

Formed on shrinkage and / or the sealing sleeve is materially connected to the stator. The sealing sheath, in particular the plug-in collar, is applied to the stator by means of injection molding during an encapsulation or by shrinking, for example as a shrink tube or a shrinkage structure.

In particular, the plug collar is designed as a plastic extrusion. The stator is enclosed by the sealing sleeve or an encapsulation and thereby the stator, that is to say at least one component of the stator, for example a soft magnetic core and / or windings and / or electrical

Contact elements, enclosed by the sealing sheath and thereby at least one component of the stator is sealed fluid-tight with respect to the fluids surrounding the stator. Thus, the fluid to be delivered, for example fuel, can not advantageously penetrate the stator and, in addition, non-damaging media or substances, for example salt water, can penetrate to the stator components because the at least one component of the sealing envelope enclosed and thereby sealed fluid-tight.

Pumps with an electric motor are used in particular as well as prefeed pumps on a high-pressure injection system of an internal combustion engine. For this purpose, the electric feed pump is arranged on a high pressure pump and the high pressure pump is in turn attached to the engine. Due to this attachment of the electric feed pump indirectly to the

Combustion engine is the electric feed pump as a pump with

Electric motor high mechanical loads, especially due to vibration and thermal stresses exposed. this leads to

Relative movements between components of the stator. Due to the

Enclosure or encapsulation surrounding the stator, these components of the stator are mechanically fastened, so that Relative movements between the components of the stator can be essentially excluded and thereby a resulting

Wear of the stator can be reduced, which significantly extends the life of the pump with the electric motor.

In a supplementary variant, the sealing envelope consists at least partially, in particular completely, of a, preferably thermoplastic,

Plastic and / or the plug collar is arranged in a recess or opening of the housing, in particular of the housing pot. The plug collar is thus positively connected to the housing and at high

mechanical stresses or high accelerations of the pump, the plug collar can be supported on the housing, so that essentially no deformations occur at the seal and a reliable and secure sealing of the plug collar is ensured with respect to the housing.

In a supplementary embodiment, the sealing sleeve has at least one functional geometry, for. Example, a groove or a recess for receiving a seal, and preferably, the groove and / or the recess has a greater distance from the axis of rotation than the windings and / or the seal is integrated in the sealing sheath. When integrating the seal, z. As a sealing ring, the seal is not inserted into the functional geometry and positively connected to the sealing sheath, but integrally connected to the sealing sheath, z. B. in which the seal is encapsulated by the sealing sheath or is or is glued to the sealing sheath.

In a further embodiment, the housing is completely sealed with the at least one seal, in particular a sealing ring on the sealing sheath or the seal on the sealing sheath is formed only on the plug collar and between the housing pot and a housing cover, a further seal is arranged. In a complete sealing of the housing with the at least one seal, the seal is preferably formed as at least one sealing ring, so that the sealing ring can completely seal the housing. In this case, two sealing rings opposite to the sealing cover may be present. In an arrangement of the seal in the area or on the sealing sleeve only on the plug collar (as part of the sealing shell) is a additional seal between two parts of the housing required to seal the housing in the remaining area.

In a supplementary embodiment, permanent magnets are integrated in the impeller, so that the rotor is formed by the impeller.

In a further embodiment, the conveying elements are blades or teeth of a gear.

In a supplementary variant, the pump is a gear pump, in particular internal gear pump.

In an additional embodiment of the soft magnetic core and / or the windings are at least partially, in particular completely, enclosed by the sealing sleeve and the electrical

Contact elements are partially enclosed by the sealing sheath as a plug-in collar, so that a part of the contact elements outside the sealing sheath is arranged as a plug-in collar.

In a supplementary embodiment, the stator, in particular the soft magnetic core, the windings and partly the electrical

Contact elements, fluid-tight enclosed by the sealing sheath.

Method according to the invention for producing a pump, in particular a pump with an electric motor described in this patent application, for conveying a fluid, comprising the steps of: providing an impeller with conveying elements, providing a housing, providing an electric motor with a stator and a motor Rotor for driving the pump, wherein the impeller is arranged with the conveying elements and the electric motor within the housing, mounting the impeller with

Conveying elements and the electric motor within the housing to the pump with electric motor, wherein the electrical contact elements of a

Plug collar are enclosed as a sealing sheath and sealed with a seal on the plug collar of the plug collar with respect to the housing. In an additional embodiment, the stator in addition to the plug collar at least partially, in particular completely, enclosed by the sealing sheath and / or the stator is enclosed by injection molding or shrinking with the sealing sheath.

Preferably, the sealing sheath is produced with a, preferably thermoplastic, plastic and / or the stator is fluid-tight, in particular completely, enclosed by the sealing sheath.

In a further embodiment, at least one seal, in particular a sealing ring, arranged on the sealing sheath and with the at least one seal on the sealing sheath, the housing is completely sealed, even on the plug collar, or on the sealing sheath, the seal is arranged only on the plug collar and between the housing pot and the housing cover, a further seal is arranged to seal the rest of the housing. With the further seal thus the housing is sealed outside the Aussparrung or opening of the housing.

In a supplementary embodiment, a soft magnetic core and windings are completely enclosed by the sealing sleeve as electromagnets of the stator and the electrical contact elements are partially enclosed by the sealing sleeve.

Inventive high-pressure injection system for an internal combustion engine, in particular for a motor vehicle, comprising a high-pressure pump, a high-pressure rail, an electric feed pump for conveying a fuel from a fuel tank to the high-pressure pump, wherein the electric

Pre-feed pump is designed as a pump described in this patent application.

In a further embodiment, the impeller forms the rotor and / or on or in the impeller, the permanent magnets are arranged or integrated, d. H.

Preferably, the pump is integrated in the electric motor or vice versa. In a further embodiment, the pump is integrated in the electric motor or vice versa, preferably, the pump and the electric motor are inseparable units.

In a further embodiment, the rotor is partially made of sheet metal plates. Preferably, the metal plates are surrounded by an insulating layer. The insulation around the metal plates and the formation of the rest of the rotor made of sheet metal plates has the task that no or only very small eddy currents occur in the rotor.

In a further embodiment, the rotor consists at least partially, in particular completely, of sintered steel.

Suitably, the at least one seal is elastic, z. B. as an elastomer, and / or consists of plastic.

In a further variant, the pump with electric motor comprises a

Inlet opening and an outlet opening for the fluid, which open into the working space.

In a further embodiment, the pump is an external gear pump or a centrifugal pump or a vane cell pump.

Suitably, the pump with, preferably integrated, electric motor comprises a, preferably electronic, control unit for controlling the energization of the electromagnets.

In an additional embodiment, the pump is a turbomachine.

Suitably consists of the housing of the prefeed pump and / or the housing of the high-pressure pump and / or the inner and / or outer gear at least partially, in particular completely, made of metal, for. As steel or aluminum.

In particular, the delivery rate of the electrical feed pump can be controlled and / or regulated. Brief description of the drawings

Hereinafter, embodiments of the invention below

With reference to the accompanying drawings described in more detail. It shows:

1 is a highly schematic view of a high-pressure injection system,

2 is a perspective view of a prefeed pump without housing and a stator without sealing sheath,

3 is an exploded view of the feed pump with the housing in a first embodiment,

Fig. 4 shows a section of the stator with sealing sheath in a first

Embodiment,

5 shows an exploded view of the prefeed pump with the housing in a second embodiment,

Fig. 6 is a first perspective view of the stator with sealing sheath

in a second embodiment,

Fig. 7 is a second perspective view of the stator with sealing sheath

in the second embodiment,

Fig. 8 is a perspective view of the stator with sealing sheath

in a third embodiment and

9 is a view of a motor vehicle.

Embodiments of the invention

FIG. 1 shows a pump arrangement 1 of a high-pressure injection system 2. An electric prefeed pump 3 delivers from a fuel tank 41 through a fuel line 35 fuel. Subsequently, the fuel is conveyed from the electric prefeed pump 3 to a high-pressure pump 7. The high-pressure pump 7 is of an internal combustion engine 39 by means of a

Drive shaft 44 driven.

The electric prefeed pump 3 has an electric motor 4 and a pump 5 (FIGS. 2 and 3). In this case, the electric motor 4 of the pump 5 is integrated into the pump 5 and further, the electric prefeed pump 3 at the

High pressure pump 7 arranged directly. The high-pressure pump 7 delivers fuel under high pressure, for example, a pressure of 1000, 3000 or

4000 bar, by a high-pressure fuel line 36 to a high-pressure rail 42. Of the high-pressure rail 42, the fuel under high pressure from an injector 43 a combustion chamber, not shown

Internal combustion engine 39 supplied. The non-combustion fuel is returned to the by means of a return fuel line 37

Fuel tank 41 returned. The porting openings 28 (FIG. 2) of the electric prefeed pump 3 are connected to the high-pressure pump 7 without an external connection. The mounting position of the electric prefeed pump 3 to the high-pressure pump 7 is chosen to the effect that by short

hydraulic connections of the fuel from the pressure side of the feed pump

3 can be passed to the suction side of the high-pressure pump 7. In the

Fuel line 35 from the fuel tank 41 to the electrical

Pre-feed pump 3, a fuel filter 38 is installed. As a result, the fuel line 35 can be formed inexpensively from the fuel tank 41 to the electric prefeed pump 3 in an advantageous manner, since they are none

Must withstand overpressure. The electric motor 4 (FIGS. 2 and 3) of the electric prefeed pump 3 is operated with three-phase current or alternating current and can be controlled and / or regulated in power. The three-phase current or alternating current for the electric motor 4 is from a power electronics, not shown, from a DC voltage network of a vehicle electrical system of a motor vehicle 40 for

Provided. The electric prefeed pump 3 is thus an electronically pumped prefeed pump 3rd

The electric prefeed pump 3 has a housing 8 with a housing pot 10 and a housing cover 9 (FIGS. 3 and 5). Within the housing 8 of the prefeed pump 3, the pump 5 as internal gear 6 and Gear pump 26 and the electric motor 4 is arranged. The housing pot 10 is provided with a recess 57 (FIG. 5) or an opening 58 (FIG. 3). The electric motor 4 has a stator 13 with windings 14 as electromagnets 15 and a soft iron core 45 as a soft magnetic core 32, which is formed as a laminated core 33. Within the stator 13, the pump 5 is as

Internal gear pump 6 with an internal gear 22 with an internal gear 23 and an external gear 24 with an external gear 25 positioned. The inner and outer gear 22, 24 thus represents a gear 20 and an impeller 18 and the inner and outer toothed ring 23, 25 have teeth 21 as conveying elements 19. Between the inner and outer gear 22, 24 forms a working space

47 off. In the external gear 24 permanent magnets 17 are installed, so that the external gear 24 also forms a rotor 16 of the electric motor 4. The electric motor 4 is thus integrated into the pump 5 or vice versa. The

Electromagnets 15 of the stator 13 are alternately energized, so that due to the resulting magnetic field to the electromagnet 15 of the

Rotor 16 and the external gear 24 is set in a rotational movement about an axis of rotation 27.

The housing cover 9 serves as a bearing 1 1 or thrust bearing 1 1 or slide bearing 1 1 for the inner or outer gear 22, 24. Further, in the housing cover 9 a

Suction porting opening 29 and a pressure porting opening 30, each as

Porting openings 28, incorporated. Through the suction port opening 29, the fluid to be delivered, namely fuel, flows into the prefeed pump 3 from the pressure port opening 30, the fuel flows out of the prefeed pump 3 again. In addition, the housing pot 9 and the housing cover 10 each have three

Holes 46, in which not shown screws for

Screwing together the housing pot 9 and the housing cover 10 are positioned. 3 and 4, a first embodiment of the stator 13 is shown, which is surrounded by a sealing sheath 31 as encapsulation substantially completely. Otherwise, the electric prefeed pump 3 corresponds to the structure in Fig. 2. The stator 13 is cut only half in the illustration of FIG. 4. In this case, the sealing envelope 31 constitutes an encapsulation 31 or an injection 31 and is produced by means of injection molding in an injection molding tool and in this connection is connected to the stator 13 in a materially bonded manner. Thereby are from the sealing sheath 31 as components of the stator 13, both the electromagnets 15 and the soft iron core 45 of the stator 13 of the sealing sheath 31 completely enclosed. The electrical contact element 34 as a further component of the stator 13 comprises the contact pin 48 and the contact line 49. At the stator 13, a plurality of contact pins 48 are provided with associated contact lines 49, so that the stator 13 so that several electrical

Contact elements 34 has. In Fig. 4, only one electrical contact element 34 is shown. By means of the electrical contact elements 34, the windings 14 of the stator 13 are energized. The contact pins 48 are partially not enclosed by the sealing sleeve 31 made of thermoplastic material, so that at this, not enclosed by the sealing sleeve 31 part of the electrical

Contact elements 34 can be brought into mechanical and electrical connection with mating contact elements, not shown in the

Energization of the windings 14 with winding wires 56 of the stator 13 and thus the plug collar 55 with the contact pins 55 forms a plug. The

Sealing sheath 31 also has a plug-in collar 55. The plug-in collar 55 (FIGS. 3 and 4) is in the opening 58 as a bore with an arbitrary cross-section of the after the assembly of the electric prefeed pump 3

Housing pot 10 arranged (not shown). The plug-in collar 55 is further provided with a functional geometry 50. The functional geometry 50 can be produced during injection molding simply based on the shape of the injection molding tool. In the illustrated in Fig. 4 first embodiment of the stator 13 with the sealing sheath 31, only the plug collar 55 has a groove 51 as a functional geometry 50 for receiving a respective sealing ring 54. By means of the plug collar 55 completely circumferential sealing ring 54 as a seal 53 and the

Grooves 51, the plug collar 55 with respect to the housing pot 10 and the housing cover 9 at the opening 58 are sealed fluid-tight. Further, between the housing pot 10 and the housing cover 9, an additional seal 53 as a sealing ring 54 (not shown) to seal the rest of the housing 8 outside the opening 58. The sealing rings 54 thus prevent on the one hand the penetration of harmful media in the enclosure enclosed by the housing 8 and on the other hand, the from the

Internal gear pump 6 funded fluid, namely fuel, do not get outside of the housing 8. On the sealing sleeve 31, the external gear 24 (not shown in Fig. 4) directly to a sliding bearing 52 of the sealing sleeve 31st stored. Due to the partial section of the stator 13 in Fig. 4, the circular slide bearing 52 is cut only once and thus only visible once in Fig. 4.

FIGS. 5 to 7 show a second exemplary embodiment of the housing 8 and of the stator 13. Otherwise, the electric prefeed pump 3 corresponds to the structure in FIG. 2. In the following, essentially only the differences from the first exemplary embodiment according to FIGS. 3 and 4 will be explained

described. The stator 13 is only partially of the injection molding

produced sealing sleeve 31 enclosed as encapsulation. The plug collar 55 is arranged in a recess 57 of the housing pot 10. Here are at the

Sealing sheath 31 opposite two completely circumferential grooves 51 present, in each of which a sealing ring 54 is arranged. The sealing rings 54 lie in each case on the housing pot 10 and the housing cover 9 and thus seal the housing 8 completely. The functional geometries 50, namely the grooves 51, in this case has to the rotation axis 27 a larger one

The grooves 51 are thereby arranged on an outer diameter of the stator 13 and the sealing sleeve 31, so that thereby no additional radial space between the windings 14 and the outer gear 24 is required for the grooves 51.

8, a third embodiment of the housing 8 and the stator 13 is shown. In the following, only the differences from the second exemplary embodiment according to FIGS. 5 to 7 will be described essentially. The sealing sheath 31 is provided with a seal 53 in a groove 51, wherein due to the geometry of the seal 53, the housing 8 completely, also on the

Plug collar 55, can be sealed. The seal 53 revolves around the

Plug collar 55 complete and due to the arrangement of the seal 53 at a support area as a completely circumferential sealing line between the housing pot 9 and the housing cover 10 and the rest of the housing 8 with the seal 53 can be completely sealed.

Overall, significant advantages are associated with the pump 5 according to the invention with electric motor 4. With the seal 53 on the plug collar 55, the plug collar 53 can be reliably sealed as part of the sealing sleeve 31 with little effort, because during the injection molding of the sealing sleeve 31st With plug-in collar 55, the groove 51 can be easily manufactured without additional costs merely due to the shape of the injection molding tool.

Claims

claims

1 . Pump (5) with electric motor (4), in particular for a motor vehicle (40), for conveying a fluid

- An impeller (18) with conveying elements (19), of which by a

Rotation axis (27) is a rotational movement executable,

a working space (47) on the impeller (18),

- An electric motor (4) having a stator (13) and a rotor (16), wherein the stator (13) has a soft magnetic core (32), in particular a laminated core (33), windings (14)

Electromagnets (15) and electrical contact elements (34) comprises,

a housing (8),

- Wherein the impeller (18) with the conveying elements (19) and the

Electric motor (4) within the housing (8) are arranged and

- Preferably, the pump (5) in the electric motor (4) is integrated or vice versa, by the rotor (16) of the impeller (18) is formed, characterized in that the electrical contact elements (34) of a plug collar (55) as Sealing sheath (31) are enclosed and with at least one seal (53) on the plug collar (55) of the plug collar (55) with respect to the housing (8) is sealed.

2. Pump with electric motor according to claim 1, characterized in that the stator (13) in addition to the plug collar (55) at least partially, in particular completely, by the sealing sheath (31) is enclosed

and or the sealing sheath (31) is designed as an encapsulation (31) or shrinkage (31)

and or

the sealing sheath (31) is materially connected to the stator (13). Pump with electric motor according to claim 1 or 2, characterized in that the sealing sheath (31) at least partially, in particular completely, consists of a, preferably thermoplastic, plastic

and or

the plug-in collar (55) is arranged in a recess (57) or an opening (58) of the housing (8), in particular a housing pot (10).

Pump with electric motor according to one or more of the preceding claims, characterized in that the sealing sheath (31) at least one functional geometry (50), z. B. has a groove (51) for receiving at least one seal (53) and / or

the seal (53) is integrated in the sealing sheath (54).

Pump with electric motor according to one or more of the preceding claims, characterized in that with the at least one seal (53), in particular a sealing ring (54) on the sealing sheath (31), the housing (8) is completely sealed or

the seal (53) is formed on the sealing sheath (31) only on the plug collar (55) and between the housing pot (10) and a

Housing cover (9) a further seal (53) is arranged.

6. Pump with electric motor according to one or more of the preceding claims, characterized in that in the impeller (18) permanent magnets (17) are integrated, so that the rotor (16) of the impeller (18) is formed.

7. Pump with electric motor according to one or more of the preceding claims, characterized in that the conveying elements (19) teeth (21) of a toothed wheel (20).

8. Pump with electric motor according to one or more of the preceding claims, characterized in that the pump (5) is a gear pump (26), in particular

Internal gear pump (6), is.

9. Pump with electric motor according to one or more of the preceding claims, characterized in that the soft magnetic core (32) and / or the windings (14) as electromagnets (15) at least partially, in particular completely, of the sealing sheath (31) are enclosed and the electrical ones

Contact elements (34) are partially enclosed by the sealing sheath (31) as a plug-in collar (55), so that a part of the contact elements (34) outside of the sealing sheath (31) is arranged as a plug-in collar (55).

10. Pump with electric motor according to one or more of the preceding claims, characterized in that the stator (13), in particular the soft magnetic core (32), the windings (14) and partially the electrical contact elements (34), fluid-tight from the sealing sheath ( 31) are included.

1 1. Method for producing a pump (5) with electric motor (4),

in particular a pump (5) with electric motor (4) according to one or more of the preceding claims, for conveying a fluid, with the steps:

- Providing an impeller (18) with conveying elements (19),

providing a housing (8),

- Providing an electric motor (4) with a stator (13) and a rotor (16) for driving the pump (5), wherein the stator (13) has a soft magnetic core (32), in particular

Laminated core (33), windings (14) as electromagnets (15) and electrical contact elements (34),

- Wherein the impeller (18) with the conveying elements (19) and the

Electric motor (4) within the housing (8) is arranged,

- Mounting the impeller (18) with conveying elements (19) and the electric motor (4) within the housing (8) to the pump (5) with electric motor (4), characterized in that the electrical contact elements (34) of a plug collar ( 55) as a sealing sheath (31) are enclosed and with a seal (53) on the plug collar (55) of the plug collar (55) with respect to the housing (8) is sealed.

12. The method according to claim 1 1, characterized in that the stator (13) in addition to the plug collar (55) of the sealing sheath (31) at least partially, in particular completely, is enclosed

and or

the stator (13) is enclosed by injection molding or shrinking with the sealing sheath (31).

13. The method of claim 1 1 or 12, characterized in that the sealing sheath (31) is made with a, preferably thermoplastic, plastic

and or

the stator (13) of the sealing sheath (31) fluid-tight, in particular

completely enclosed.

14. The method according to one or more of claims 1 1 to 13, characterized in that at least one seal (53), in particular a sealing ring (54) on the sealing sheath (31) is arranged and with the at least one seal (53) the sealing sheath (31) the housing (8) completely, also on the plug collar (55) is sealed

or

on the sealing sheath (31), the seal (53) is arranged only on the plug collar (55) and between the housing pot (10) and the

Housing cover (9) a further seal (53) is arranged to seal the remaining housing (8).

15. High-pressure injection system (2) for an internal combustion engine (39), in particular for a motor vehicle (40)

a high pressure pump (7),

a high pressure rail (42),

- An electric prefeed pump (3) for conveying a fuel from a fuel tank (41) to the high-pressure pump (7), characterized in that the electric prefeed pump (3) as a pump (5) according to one or more of claims 1 to 10 is formed is.