EP1828613A1

EP1828613A1 - Delivery unit

Info

Publication number: EP1828613A1
Application number: EP05801511A
Authority: EP
Inventors: Fevzi Yildirim; Ulrich Mueller; Benjin Luo
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2004-12-17
Filing date: 2005-10-17
Publication date: 2007-09-05
Also published as: CN101080574A; DE102004060904A1; KR20070086257A; JP2008523317A; US20090238680A1; WO2006063887A1

Abstract

In prior art, delivery units comprise a running wheel which is arranged in a pump chamber and which can be driven in a rotated manner by means of an actuator and comprise two front sides whereby a front wall of the pump chamber is arranged opposite thereto, and also comprises several recesses for storing, in a hydrodynamic manner, in both front sides of the running wheel. One disadvantage of the delivery unit is that dirt particles can collect in the recesses. When the dirt particles are flushed out from the recesses, they produce, in the region between the recesses which are arranged in a circular manner, increased friction and also stress marks and the axial gap between the running wheel and the pump chamber is smaller than in the region of the recesses. The inventive delivery unit reduces the friction acting upon the running wheel and increases efficiency. According to the invention, at least two adjacent recesses (38) of the at least one front side (28,29) and/or the at least one front wall (15,16) are connected together by, respectively at least one groove (42).

Description

Fδrderaggregat

State of the art

The invention relates to a delivery unit according to the preamble of the main claim. It is already a delivery unit known from EP 1 091 127 Al, with an impeller arranged in a pump chamber, which is driven in rotation by means of an actuator and has two end faces, which faces in each case an end wall of the pump chamber, and with several recesses for hydrodynamic storage in both end faces of the impeller. The disadvantage is that dirt particles can accumulate in the depressions. When the dirt particles are flushed out of the depressions, they generate increased friction in the area between the annularly arranged depressions and, as a result, grinding marks, because there the axial gap between the impeller and the pump chamber is smaller than in the region of the depressions.

Advantages of the invention

The delivery unit according to the invention with the characterizing features of the main claim has the advantage that in a simple manner an improvement is achieved in that at least two adjacent recesses of the at least one end face and / or the at least one end wall are connected to each other via at least one groove , In this way, the axial gap is increased in the area between the recesses, so that the dirt particles there no increased friction and

Can cause sanding marks.

The measures listed in the dependent claims advantageous refinements and improvements of the main claim conveying unit are possible. According to an advantageous embodiment, the recesses and grooves are arranged annularly and extend arcuately, partially annular, oblong-shaped or similar. The depressions and the grooves are advantageously arranged on a common ring.

Furthermore, it is advantageous if the recesses have a greater depth than the grooves, since in this way oblique surfaces can be formed, which achieve a hydrodynamic bearing of the impeller.

It is particularly advantageous that the recesses each have at least one with respect to the end sides and / or end walls inclined surface for hydrodynamic bearing of the impeller, since in this way the axial position of the impeller is set such that the two axial gaps between the impeller and the End walls of the pump chamber are at least almost equal. As a result, the friction acting on the impeller is reduced and increases the efficiency of the delivery unit. The at least one inclined surface per recess is provided in the arrangement of the recesses on the impeller each at a trailing with respect to a direction of rotation of the impeller end of the recess and in the arrangement of the recesses on the end walls of Pumpenkamer each at a downstream end of the recess.

It is also advantageous if the recesses each have a lowest point, which runs parallel to at least one end face and / or an end wall.

Furthermore, it is advantageous if the depressions of one end face of the impeller face the depressions of the other end face of the impeller mirror-symmetrically with respect to a central surface, wherein the mirror-symmetrically opposite depressions are connected to one another via a pressure equalization channel. In this way it is achieved that in each case the pressure in the two connected via the pressure equalization channel wells is compensated.

drawing

Embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description. 2 shows a section of the impeller along the line III-III in Figure 2, Figure 4 is a sectional view of the 5 shows a sectional view of the delivery unit along the line VV in Fig.l according to a second exemplary embodiment and Figure 6 shows a sectional view with the impeller and arranged in an end wall of the pump chamber recesses according to the second embodiment.

Description of the exemplary embodiments

Fig.l shows an inventive delivery unit.

The delivery unit according to the invention serves to demand a liquid, for example fuel, from a reservoir, for example via a pressure line to an internal combustion engine.

The delivery unit according to the invention is as a flow pump, for example a

Peripheral pump or side channel pump, and has a pump housing 1, which has a pump part 2 and a motor part 3.

The pump part 2 has a pump chamber 4, in which an impeller 5 rotates about a rotationally symmetrical pump axis 8. The impeller 5 is of a in the

Motor part 3 provided actuator 9 driven by a drive shaft 10. The actuator 8 is for example an electric motor and arranged in an engine compartment 7 of the motor part 3.

An area upstream of the pump chamber 4 is referred to as a suction side, and an area downstream of the pump chamber 4 is referred to as a pressure side of the unit.

The pump chamber 4 has a pump chamber inlet 11 and a pump chamber outlet 12. The pump chamber 4 is bounded by two opposite in the direction of the pump axis 8 end walls, a first end wall 15 and a second end wall 16, wherein in the first end wall 15 of the pump chamber inlet 11 and in the second end wall 16 of the pump chamber outlet 12 is provided, and in the radial Direction with respect to the pump axis 8 of an annular wall 17th

The impeller 5 has a plurality of impeller vanes 5.1, between each of which a vane chamber 5.2 is formed. The blade chambers 5.2 are towards the end walls 15,16 - A -

open and closed, for example radially outward with respect to the pump axis 8 by a ring 5.3, which is arranged at the radially outer ends of the impeller blades 5.1. The vane chambers 5.2 can, however, also be explicitly open radially outwards and have no ring 5.3.

In the end walls 15,16 annular conveying channels 14 are arranged, which are arranged in the radial region of the impeller blades 5.1.

The first end wall 15 is for example part of a suction cover 18 and the second end wall 16 and the annular wall 17 are for example part of a pressure cover 19. In the suction cover 18, an input channel 22 is provided, which opens via the pump chamber inlet 11 into the pump chamber 4, wherein the subsidized Liquid of the delivery unit leaves the pump chamber 4 via the pump chamber outlet 12. For example, the pump chamber 4 is flow-connected to the engine compartment 7 via the pump chamber outlet 12 and an outlet channel 23 provided in the pressure lid 19.

The pressure lid 19 has a passage opening 24. The drive shaft 10, which is mechanically coupled to the actuator 9, projects from the engine compartment 7, through the passage opening 24 of the pressure cover 19, into the pump chamber 4.

The axial width of the pump chamber 4 is greater than the axial width of the impeller 5, so that in each case an axial gap 20 of about ten to thirty micrometers between the impeller 5 and the end walls 15,16 consists. The difference between the width of the pump chamber 4 and the width of the impeller 5 is defined as Gesamtaxialspalt.

The impeller 5 is placed, for example, on the projecting into the pump chamber 4 drive shaft 10, for which the impeller 5 has an impeller opening 25 into which the drive shaft 10 projects at least to be positively and / or non-positively connected to the impeller. The impeller 5 is mounted on the drive shaft 10, for example, such that it is axially movable between the first end wall 15 and the second end wall 16.

The impeller 5 has a first end face 28, which faces the first end wall 15 of the pump chamber 4, and a second end face 29, which faces the second end wall 16 of the pump chamber 4. In at least one of the end faces 28,29 of the impeller 5 and / or at least one of the end walls 15,16 of the pump chamber 4 a plurality of recesses 38 for hydrodynamic bearing of the impeller 5 are provided. In Fig.l the recesses 38 are arranged, for example, on the end faces 28,29 of the impeller 5. But they can also be provided according to a second embodiment of the end walls 15,16 of the pump chamber 4. The recesses 38 are formed such that they act as a hydrodynamic bearing and set in this way the axial position of the impeller 5 between the first end wall 15 and the second end wall 16 of the pump chamber 4 such that two equal axial gaps 20 between the impeller 5 and the end walls 15,16 result. As a result, only low frictional forces act on the impeller 5, so that the efficiency of the delivery unit is improved.

The delivery unit sucks, for example, liquid from a reservoir 32 via the inlet channel 22, the pump chamber inlet 11, the pump chamber 4, the pump chamber outlet 12, the outlet channel 23, the engine compartment 7 of the motor part of the pump housing 1 and promotes the liquid, for example fuel, via a Pressure line 33, for example, to an internal combustion engine 34. In the pressure line 33, for example, a check valve 35 is provided to maintain a predetermined pressure in the pressure line 33 after switching off the delivery unit.

2 shows an impeller of the delivery unit with recesses according to a first embodiment of the delivery unit according to the invention.

In the case of the impeller according to FIG. 2, the parts which remain the same or function with respect to the delivery unit according to FIG. 1 are identified by the same reference numerals.

The recesses 38 are provided, for example, radially inside the impeller blades 5.1 of the impeller 5 and arranged lying on an imaginary circular ring. The ring is, for example, provided centrally with respect to the pump axis 8. For example, four recesses 38 are evenly distributed over the circumference of the ring. However, it is expressly possible for any number of depressions 38 to be provided. The recesses 38 extend, for example, arcuately, partially annular, oblong-shaped or similar. The depressions 38 each have at least one inclined surface 39 with respect to the end faces 28, 29 for the hydrodynamic mounting of the impeller 5. The inclined surface 39 for hydrodynamic bearing is on a trailing with respect to a direction of rotation 41 of the impeller 5 end of the recess 38th arranged. The depression rings 38 each have a deepest point 40, which for example runs parallel to the end faces 28, 29. For example, the lowest point 40 of the recesses 38 is adjacent to two inclined surfaces 39, one leading and one trailing. According to the first exemplary embodiment, the leading sloping surface 39 has a shorter length, for example a shorter arc length, than the inclined in the direction of rotation oblique surface 39. The leading in the direction of rotation inclined surface 38 may also be omitted and replaced by a step-shaped paragraph, as they have no Contribution to the hydrodynamic bearing supplies.

According to the invention, at least two adjacent depressions 38 of the at least one end face 28, 29 and / or the at least one end wall 15, 16 are connected to one another via in each case at least one groove 42. According to the first embodiment, both end faces 28,29 of the impeller 5 are provided with recesses 38. For example, each recess 38 is connected to the adjacent recess 38 via a groove 42. The grooves 42 extend, for example, arc-shaped, annular or similar, so that the recesses 38 and the grooves 42 together form a common ring. However, the recesses 38 and the grooves 42 remain distinguishable at least in that the depth of the grooves 42 is less than the depth of the lowest point 40 and the inclined surfaces 39 of the recesses 38 (Figure 3). The width Bn of the grooves 42 measured in the radial direction with respect to the pump axis 8 is, for example, the same as the width Bv of the depressions 38 measured in the radial direction with respect to the pump axis 8, but may also be different.

The oblique surfaces 39 of the recesses 38 are formed by the fact that the depth of the recesses 38 decreases from the lowest point 40, starting from the adjacent groove 42 toward, for example, continuously.

3 shows a sectional view of the impeller along the line III-III in Figure 2.

The recesses 38 extend in the region of the lowest point 40, for example, at least approximately parallel to the end faces 28,29. Then they run against the

Direction of rotation 41 seen over a trailing inclined surface 39 while reducing the depth in the direction of a trailing in the direction of rotation 41 groove 42 and open into it. Viewed in the direction of rotation, the depth of the recess 38 is reduced either via a step-shaped step 43 shown in dashed lines or via an anticipatory inclined surface 39 and ends in a leading groove 42. The recesses 38 of the one end face 28 of the impeller 5 are the recesses 38 of the other end face 29 of the impeller 5, for example, with respect to a mirror surface relative to a central surface 45, wherein the mirror-symmetrically opposite recesses 38 are connected to each other via a pressure equalization channel 46. In this way, an equally high pressure is formed in the two recesses 38 connected via the pressure equalization channel 46. The pressure equalization channel 46 opens, for example, in the region of the lowest point 40 in the recess 38th

The liquid located in the axial gap 20 is taken in the rotation of the impeller 5 in the direction of rotation 41 and has a counter to the direction of rotation 41 directed relative speed to the impeller 5. Therefore, the recesses 38 and the grooves 42 are flowed through by the liquid in the axial gap 20 counter to the direction of rotation 41. In the region of the trailing oblique surface 39, the flow cross-section between the end face 28,29 of the impeller 5 and the end wall 15,16 of the pump chamber 4 narrows wedge-shaped, so that an increasingly higher pressure builds up in the liquid, which on the respective end face 28, 29 of the impeller 5 acts and in this way adjusts the axial position of the impeller 5 such that equal axial gaps 20 result.

4 shows a sectional view of the delivery unit along the line IV-IV in Fig.l and Figure 5 is a sectional view of the delivery unit along the line V-V in Fig.l according to a second embodiment.

In the delivery unit according to Fig.4 and Fig.5 are compared to the delivery unit according to Fig.l to Fig.3 consistent or equivalent parts characterized by the same reference numerals.

The second embodiment of Figure 4 differs from the first embodiment according to Fig.l to Fig.3 therein that the recesses 38 not at the two end faces 28,29 of the impeller 5, but at the two end walls 15,16 of

Pump chamber 4 are arranged. The pressure equalization channels 46 omitted. The recesses 38 are flowed through in the arrangement on the end walls 15, 16 of the pump chamber 4 in contrast to the arrangement on the impeller 5 in the direction of rotation of the impeller 5. Therefore, the inclined surfaces 39 are to be arranged for hydrodynamic bearing respectively at a downstream with respect to the flow direction in the axial gap 20 end of the recess 38. The depression rings 38 are arranged in the second embodiment radially within the conveying channel 14 with respect to the pump axis 8. The recesses 38 run in the region of the lowest point 40, for example, at least approximately parallel to the end walls 15,16. Downstream they extend over a with respect to the flow direction in the axial gap 20 rear inclined surface 39 for hydrodynamic storage while reducing the depth up to a downstream groove 42 and open into it. After upstream, the depth of the recess 38 is reduced either via a stepped shoulder 43 or via an upstream inclined surface 39 and opens into a groove 42 which is upstream in the flow direction.

The recesses 38 of the one end wall 15 of the pump chamber 4 are the recesses 38 of the other end wall 16 of the pump chamber 4, for example, mirror symmetry with respect to a lying in the middle between the end walls 15,16 and parallel to this center surface.

6 shows a sectional view with the impeller and arranged in an end wall of the pump chamber recesses according to the second embodiment.

In the delivery unit according to FIG. 6, the parts which are the same or have the same effect in relation to the delivery unit according to FIGS. 1 to 5 are designated by the same reference numerals.

Claims

26.11.2004 Hue / OyROBERT BOSCH GMBH, 70442 Stuttgart claims

1. delivery unit with a arranged in a pump chamber impeller which is driven in rotation by means of an actuator and has two end faces, each facing an end wall of the pump chamber, with a plurality of wells for hydrodynamic bearing in at least one of the end faces of the impeller and / or at least one of End walls of the pump chamber, characterized in that at least two adjacent recesses (38) of the at least one end face (28,29) and / or the at least one end wall (15,16) via a respective groove (42) are interconnected.

2. delivery unit according to claim 1, characterized in that the recesses (38) and / or the grooves (42) are arranged annularly.

3. delivery unit according to claim 1, characterized in that the recesses (38) and / or the grooves (42) arc-shaped, partially annular, elongated hole-shaped or similar.

4. delivery unit according to claim 1, characterized in that the recesses (38) and the grooves (42) form a common ring.

5. delivery unit according to claim 1, characterized in that the recesses (38) have a greater depth than the grooves (42).

6. delivery unit according to claim 1, characterized in that the recesses (38) each have at least one with respect to the end faces (28,29) and / or end walls (15,16) inclined surface (39) for hydrodynamic bearing of the impeller (5) ,

7. delivery unit according to claim 5, characterized in that the at least one inclined surface (39) in the arrangement of the recesses on the impeller (5) respectively at a relative to a rotational direction (41) of the impeller (5) trailing end of the recess (38) is provided.

8. delivery unit according to claim 5, characterized in that the at least one inclined surface (39) in the arrangement of the recesses on the end walls (15,16) of the Pumpenkamer (4) is provided in each case at a downstream end of the recess (38).

9. delivery unit according to claim 6, characterized in that the recesses (38) each have a deepest point (40) which extends parallel to at least one end face (28,29) and / or end wall (15,16).

10 conveying device according to claim 1, characterized in that the recesses (38) of one end face (28) of the impeller (5) the recesses (38) of the other end face (16) of the impeller (5) mirror-symmetrically with respect to a central surface (45). opposite, wherein the mirror-symmetrically opposite recesses (38) via a pressure equalization channel (46) are interconnected.