Pump housing having a fastening structure

Abstract

An electric motor-vehicle coolant pump includes a pump housing with a flow housing part and a separate motor housing part, a spiral flow channel with an axial inlet and a tangential outlet, a rotatably supported fluid-conveying element, an electric drive motor which drives the rotatably supported fluid-conveying element, and a mounting structure which mounts the pump housing to a vehicle structure. The mounting structure is only arranged on the flow housing part. The flow housing part at least partially surrounds the spiral flow channel and at least partially surrounds the rotatably supported fluid-conveying element. The separate motor housing part surrounds the electric drive motor.

Claims

1. A motor-vehicle electric coolant pump comprising: a pump housing comprising a flow housing part and a separate motor housing part; a spiral flow channel comprising an axial inlet and a tangential outlet; a rotatably supported fluid-conveying element; an electric drive motor configured to drive the rotatably supported fluid-conveying element; and a mounting structure configured to mount the pump housing to a vehicle structure, the mounting structure only being arranged on the flow housing part, wherein, the flow housing part at least partially surrounds the spiral flow channel and at least partially surrounds the rotatably supported fluid-conveying element, the separate motor housing part surrounds the electric drive motor, the mounting structure is formed integrally with the flow housing part, the rotatably supported fluid-conveying element comprises a rotation axis, the mounting structure is arranged in parallel with the rotation axis in a longitudinal direction, and a mechanical fixation of the electric coolant pump to the vehicle structure is effected exclusively via the mounting structure without a further support.

2. The motor-vehicle electric coolant pump as recited in claim 1, wherein the mounting structure comprises a support arm which projects from the flow housing part.

3. The motor-vehicle electric coolant pump as recited in claim 2, wherein the support arm is a flange comprising at least one reinforcement rib.

4. The motor-vehicle electric coolant pump as recited in claim 1, wherein the mounting structure comprises at least three mounting points which are configured to provide a spot mounting on the vehicle structure.

5. The motor-vehicle electric coolant pump as recited in claim 4, wherein the at least three mounting points are arranged in a plane which is parallel to the rotation axis.

6. The motor-vehicle electric coolant pump as recited in claim 5, wherein the at least three mounting points are arranged in a plane in a right triangle with respect to each other.

7. The motor-vehicle electric coolant pump as recited in claim 1, wherein the mounting structure is fixed on the vehicle structure using at least one of a frictional connection and a positive connection.

8. The motor-vehicle electric coolant pump as recited in claim 1, wherein the mounting structure comprises at least one vibration damper.

9. The motor-vehicle electric coolant pump as recited in claim 8, wherein, the mounting structure further comprises an opening, and the vibration damper is an elastomer ring which is configured to rest in the opening on the mounting structure.

10. The motor-vehicle electric coolant pump as recited in claim 1, wherein the flow housing part comprises a centering structure configured to align the motor housing part with respect to the flow housing part.

11. The motor-vehicle electric coolant pump as recited in claim 1, wherein the flow housing part comprises at least one of an axial gap sealing surface and a radial gap sealing surface at a contact surface to the rotatably supported fluid-conveying element.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present invention is described in greater detail below on the basis of embodiments and of the drawings in which:

(2) FIG. 1 schematically shows a side view of an assembled electric coolant pump; and

(3) FIG. 2 schematically shows a perspective view of a flow housing part with a mounting structure.

DETAILED DESCRIPTION

(4) According to the present invention, the mounting structure is arranged on the pump side exclusively on the flow housing. The interfaces for the fluidic and mechanical connection of the coolant pump to a vehicle structure can thus be restricted to the flow housing part alone, thereby simplifying the design of the coolant pump. In particular the design and the specification of the interfaces between the pump and the vehicle can be restricted to only the design of the flow housing part. In contrast thereto, depending on the vehicle model and the requirements connected therewith, for example, with respect to a model variant and/or the pump capacity, the motor housing part can have various structural forms and sizes and can be manufactured entirely independent of the interfaces and connection conditions of the pump existing in the vehicle. The manufacture and assembly of the coolant pump can thereby be significantly simplified and can therefore be relatively economic.

(5) The mounting structure may basically be a separate part, such as a clamp or a support arm, wherein the mounting structure may be adapted individually to the shape of the flow housing part. The mounting structure is advantageously formed integrally with the flow housing part. The number of components can thus be reduced and the coolant pump can be fixed on the vehicle structure in a relatively simple manner.

(6) The mounting structure is advantageously arranged in parallel with the rotation axis in the longitudinal direction. A particularly stable and relatively secure fixation of the coolant pump to the vehicle structure is thus made possible. The pump thus also has a relatively compact structure.

(7) In an embodiment of the present invention, the mounting structure can, for example, have a support arm projecting outward from the flow housing part. This allows for a reduction of the number of components and for a relatively simple fixation of the coolant pump on the vehicle structure. The support arm advantageously comprises (in particular at its distal end) an opening or bore through which a screw, a rivet, a bolt or another mounting element may extend to mount the support arm to the vehicle structure. The support arm may also comprise an outward protruding centering pin for aligning the support arm with respect to the vehicle structure.

(8) The support arm may be designed as a flange and may comprise at least one reinforcement rib. The reinforcement rib may in particular be formed on the flange in the longitudinal direction of the flange. The support arm thus has a particularly high stability.

(9) The mounting structure can, for example, comprise at least three mounting points for a spot mounting of the pump housing on the vehicle structure. A mounting point can, for example, be an opening through which a screw extends for mounting. Exactly three such mounting points can, for example, be provided. A relatively stable and secure fixation of the coolant pump on the vehicle structure can thereby be provided.

(10) The mounting points can, for example, be arranged in a plane parallel to the rotation axis. A common contact plane is thereby formed via which the mounting structure can abut against and be fixed on a contact surface of the vehicle structure in a relatively simple manner.

(11) The mounting points can, for example, be arranged in a right triangle with respect to each other in the plane. This allows for a particularly stable fixation of the pump on the vehicle structure, wherein the pump is in particular fixed against tilting and/or turning.

(12) In an embodiment of the present invention, the mounting structure can, for example, be fixed on the vehicle structure using a frictional and/or a positive connection. The mounting structure can thereby be fixed on the vehicle structure, in particular in a releasable manner, using, for example, a screw. This is advantageous in particular in case of a repair or a replacement of the pump.

(13) The mounting structure advantageously comprises at least one vibration damper, for example, at a mounting point. The vibration damper may in particular be suited to dampen undesirable vibrations of the coolant pump, and to thereby prevent a loosening of the pump's mounting on the vehicle structure, and to dampen noise.

(14) The vibration damper can, for example, be designed as an elastomer ring resting in an opening, for example, a mounting point, on the mounting structure. The elastomer ring, for example, a rubber ring, may be placed or inserted in an opening or recess provided in the mounting structure for this purpose. This provides a relatively reliable damping of the coolant pump and simplifies the assembly of the coolant pump.

(15) The flow housing part can, for example, comprise a centering structure for aligning the motor housing part with respect to the flow housing part. The centering structure may be a shoulder or a recess into which a pin can, for example, be inserted. A shoulder is advantageously formed on the flow housing part where the motor housing part can be inserted in only one defined rotational orientation. A pump rotor carrying the fluid-conveying element may also be inserted in a shoulder of the flow housing part and may be rotatably supported thereon for supporting purposes. The coolant pump may thereby be of a relatively compact structure.

(16) The flow housing part can, for example, comprise an axial and/or radial gap sealing surface towards the fluid-conveying element. Fluid conveying can therefore occur in a relatively loss-free manner so that the efficiency of the coolant pump can be augmented.

(17) The present invention will be explained below in greater detail under reference to the drawings.

(18) FIG. 1 shows an electric motor-vehicle coolant pump 1 in the mounted state 100. Specifically, the coolant pump 1 is mechanically fixed to a purely schematically illustrated vehicle structure 6 via a mounting structure 5.

(19) The coolant pump 1 comprises a pump housing 2 which in the present instance comprises a flow housing part 3 and a separate motor housing part 4. A spiral-shaped flow channel 30 and a rotatable fluid-conveying element 33 situated therein are arranged inside the flow housing part 3, the fluid-conveying element 33 being shown in FIG. 1 in a cutaway view. The flow channel 30 has an axial inlet 31 and a tangential outlet 32. The fluid-conveying element 33 is supported on a drive shaft 11 that extends into the motor housing part 4. Inside the motor housing part 4, a drive motor 40 is arranged for driving the fluid conveying element 33 via the drive shaft 11, which is also shown in a cutaway view in FIG. 1.

(20) At a connecting site 20, the flow housing part 3 and the motor housing part 4 are aligned with each other and are fixed to each other by a plurality of screw connections 21. The screw connection 21 is designed to be stable enough for the flow housing part 3 to support the motor housing part 4 and the components arranged therein without further support.

(21) A fluidic connection between the coolant pump 1 and the vehicle (which is not shown in detail in the drawings) is established via a supply channel 61 (which is also not shown in detail in the drawings) at the inlet 31 and a discharge channel 62 at the outlet 32 of the (pump-side) flow channel 30.

(22) A mechanical fixation of the coolant pump 1 to the vehicle structure 6 is effected exclusively via the mounting structure 5, which in the present case, as can in particular be seen in FIG. 2, is formed by two support arms 50. Each support arm 50 is designed as a flange with a reinforcement rib 51 in the present case. Each support arm 50 is formed integrally with the flow housing part 3 and projects outward from the flow housing part 3. Each support arm 50 also has a plurality of bores 52 at a distal end through which a respective screw 53 extends for the fixation of the flow housing part 3 on the vehicle structure 6. The entire coolant pump 1 can be fixed on the vehicle structure 6 via this arrangement.

(23) FIG. 2 shows the flow housing part 2 in a non-mounted state. As can be seen particularly clearly in FIG. 2, the mounting structure 5 is formed by two support arms 50 arranged at the flow housing part 3 and projecting therefrom.

(24) On a side facing the drive motor 40, the flow housing part 3 has a centering structure 35 for aligning the motor housing part 4 with respect to the flow housing part 3. In the present case, the centering structure 35 is in particular a shoulder arranged coaxially with respect to the rotation axis 10. A seal (which is not shown in detail in the drawings) is also provided at the centering structure 35 via which the interior of the pump housing 2 can be sealed from the surroundings.

(25) At a further shoulder or a contact surface 36 of a side also facing the drive motor 40, the flow housing part 3 has an axial and radial gap sealing surface 34 at which the fluid-conveying element 33 can be supported. Fluid can thus be conveyed in a relatively loss-free manner so that the efficiency of the coolant pump 1 can be augmented.

(26) It should be clear that the present invention is not restricted to the embodiments described herein; reference should be had to the appended claims.

LIST OF REFERENCE NUMERALS

(27) 1 motor-vehicle coolant pump 10 rotational axis 11 drive shaft 2 pump housing 20 housing connection, connecting site 21 screw connection 3 flow housing part 30 flow channel 31 inlet 32 outlet 33 fluid conveying element 34 gap sealing surface 35 centering structure 36 contact surface 4 motor housing part 40 drive motor 5 mounting structure 50 support arm, flange 51 reinforcement rib 52 opening, bore 52a mounting point, mounting element 52b mounting point, mounting element 52c mounting point, mounting element 53 screw 55 vibration damper 6 vehicle structure 61 supply channel 62 discharge channel 100 mounted state