DE102013224797A1 - Fuel pump with a piston, at its end facing a drive end a spring divider is arranged - Google Patents

Abstract

The invention relates to a fuel pump (10) with a piston (34), at the end section of which a drive (62) a spring plate (44) is arranged, on which a piston spring (40) engages, which drives the piston (34) ( 62) acted upon. According to the invention, a holding section (50) is arranged at the end section of the piston (34) against which the spring plate (44) is supported at least indirectly towards the drive (62), the holding section (50) being arranged axially relative to the piston (34) is, so that the drive (62) facing support surface (46) of the spring plate (44) and the drive (62) facing end face (48) of the piston (34) in a drive (62) facing the end position of the spring plate (44 ) are essentially flat with each other. In particular, lateral forces transmitted from the spring plate (44) to the piston (34) can be reduced. The risk of possible seizure can be reduced.

Description

State of the art

The invention relates to a fuel pump according to the preamble of claim 1, and a method according to the independent claim.

From the market known fuel pumps for fuel systems for internal combustion engines, in which a piston can be moved axially by means of a drive formed by a cam or an eccentric disc. A required restoring force of the piston is generated by means of a compression spring. For example, an acted upon by a compression spring spring plate is pressed rigidly onto an end portion of the piston, but in operation, possible undesirable transverse forces of the compression spring can act on the piston. Patent publications in this field are, for example, the DT 24 25 733 A1 , the EP 1834089 B1 and the EP 1076174 B1 ,

Disclosure of the invention

The problem underlying the invention is achieved by a fuel pump according to claim 1, and by a method according to the independent claim. Advantageous developments are specified in subclaims. Features which are important for the invention can also be found in the following description and in the drawings, wherein the features, both alone and in different combinations, can be important for the invention, without being explicitly referred to again.

The invention relates to a fuel pump with a piston, on whose end portion facing a drive, a spring plate is arranged, on which a piston spring acts, which acts on the piston towards the drive. According to the invention a holding section is arranged at the end portion of the piston, at which the spring plate is supported at least indirectly to the drive, wherein the holding portion is arranged axially relative to the piston so that a support surface facing the drive of the spring plate and a drive end face of the piston are in a drive-facing end position of the spring plate are substantially flat to each other.

Thereby, an operation of the fuel pump can be improved and an operating noise can be reduced. As "end position" of the spring plate is understood to be effected by means of the pressure force of the piston spring axial concerns of the spring plate on the holding portion. In this case, the spring plate is supported only to the drive from, away from the drive, however (ie against the compressive force of the piston spring), the spring plate may optionally lift off the holding portion axially. By means of the spring plate thus the piston spring can be axially supported on the holding portion and guided radially. By the support surface of the spring plate and the end face of the piston are flat, are transmitted from the drive, such as a roller tappet, axial forces on the spring plate and thereby reduces the axial force with which the spring plate on the holding portion and on this acts on the piston, which also the lateral forces transmitted from the spring plate to the piston are reduced.

Furthermore, the invention enables a simple production or assembly of the fuel pump, wherein - depending on a respective inventive embodiment of the fuel pump - positive force applications are made possible and thus optionally a press-fit can be saved. Preferably, the spring plate is designed as a low-cost deep-drawn punching part.

In particular, it can be provided according to the invention that the holding section comprises a ring pressed onto the piston, a groove incorporated in the piston, or a snap ring fixed to the piston. Thereby, three different embodiments of the invention are described, which simplify the production.

In one embodiment of the fuel pump, the spring plate with respect to the piston on a radial clearance. As a result, the transverse forces acting on the spring plate described above can be better kept away from the piston, whereby a fatigue strength of the fuel pump can be improved.

In a further embodiment of the fuel pump, the spring plate has a radially extending insertion slot. As a result, an assembly of the spring plate can be simplified and the production of the fuel pump can thus be cheapened.

In a further embodiment of the fuel pump, a spring section is arranged between the holding section and the spring plate. The spring portion may be a plate spring, for example. As a result, any axial tolerances of the fuel pump can be compensated. Preferably, the plate spring is biased in the axial direction, whereby an operating noise can be reduced.

Furthermore, the drive, which faces the support surface of the spring plate and the end face of the piston, comprise a roller tappet against which the spring plate and the piston at least temporarily. By the invention is allows in particular that the support surface of the spring plate and the end face of the piston can lie substantially flat on the roller tappet. This allows a low-friction and therefore efficient operation.

In one embodiment of the fuel pump, a radially inner portion of the spring plate resting against the holding section is designed such that it can spring in an axial direction. As a result, a production and assembly simplifying cost-effective alternative by eliminating the disc spring described above is possible. In addition, it can be provided that the radially inner portion of the spring plate comprises at least one resilient tab. This allows a particularly good elasticity, whereby the fatigue strength of the spring plate improved and an operating noise can be reduced.

Furthermore, the invention relates to a method for producing the piston pump. According to the invention, in a first step, the holding section is pressed onto the end section of the piston such that the end face of the piston facing the drive has an axial oversize in relation to the support surface of the spring plate facing the drive. In a following second step, the holding section is displaced axially such that the support surface facing the drive of the spring plate and the end face of the piston facing the drive are mutually substantially planar. Thus, the fuel pump according to the invention can be made particularly simple, precise and inexpensive.

In addition it can be provided that the holding portion for the said displacement process is acted upon by an axial force by firstly applied to the drive facing away from the surface of the spring plate and secondly the drive facing end face of the piston with a respective force.

The term "in the essential plan" initially falls in particular a completely planar arrangement. In particular, however, minor deviations of a few microns, for example a maximum of 5 microns may be included.

Hereinafter, exemplary embodiments of the invention will be explained with reference to the drawings. In the drawing show:

1 a longitudinal section through a conventional fuel pump of a fuel system for an internal combustion engine;

2 a partial view of a longitudinal section through a fuel pump according to the invention in a first embodiment and in a first manufacturing state;

3 the partial view of the fuel pump of 2 in a second manufacturing state together with a drive;

4 a partial view of a longitudinal section through a fuel pump according to the invention in a second embodiment;

5 a perspective view of a spring plate for the fuel pump of 4 ;

6 a partial view of a longitudinal section through a fuel pump according to the invention in a third embodiment;

7 a partial view of a longitudinal section through a fuel pump according to the invention in a fourth embodiment; and

8th a flowchart for a method of manufacturing the fuel pump according to the 2 and 3 ,

The same reference numerals are used for functionally equivalent elements and sizes in all figures, even in different embodiments.

1 shows a high pressure fuel pump 10 a (not shown) fuel delivery device, for example, for a common rail fuel system for a likewise not shown internal combustion engine in an axial sectional view. The fuel pump 10 from 1 corresponds to the prior art and is at least partially rotationally symmetric about a longitudinal axis 12 executed.

The fuel pump 10 includes a housing 14 , which by means of a flange 16 on a - not shown - engine block of the internal combustion engine is screwed. The housing 14 also has several hydraulic channels 18 . 20 and 22 on. I'm in the 1 Upper area includes the fuel pump 10 a lid 24 and a pressure damper 26 and a first inlet 28 for connection to a fuel line (not shown).

In a left in the drawing area, the fuel pump points 10 a second inlet 30 for connection to the fuel line. Furthermore, the fuel pump includes 10 : A workroom 32 , a piston 34 and a liner 36 , In one in the 1 lower area includes the fuel pump 10 Furthermore: An approximately cup-shaped spring receptacle 38 , a pressure-loaded piston spring 40 , a piston seal 42 and one at an end portion of the piston 34 pressed spring plate 44 ,

2 shows a partial view of a longitudinal section through a fuel pump according to the invention 10 in a first embodiment. The fuel pump 10 according to 2 differs in one area of the piston 34 , the piston spring 40 and the spring plate 44 from the prior art embodiment according to 1 , A drive 62 (please refer 3 ) for the fuel pump 10 , which in a mounted state of the fuel pump 10 in the 2 below one of the drive 62 facing support surface 46 of the spring plate 44 and one to the drive 62 facing end face 48 of the piston 34 is arranged in the 2 not shown.

Furthermore, the fuel pump includes 10 from 2 a substantially cylindrical ring 50a executed holding section 50 , The holding section 50 is at one in the 2 lower end portion of the piston 34 on a lateral surface of the piston 34 pressed. This is in the 2 illustrated by two arrows (not numbered). The spring plate 44 is in the embodiment according to 2 formed substantially hat-shaped and axially between the spring retainer 38 and the holding section 50 arranged. The holding section 50 is radially substantially inside the spring plate 44 arranged. The spring plate 44 includes a central opening through which the piston 34 is guided. In this case, a diameter of the central opening is larger than a diameter of the piston 34 so that the spring plate 44 opposite the piston 34 having a radial clearance.

The representation of 2 corresponds to a first manufacturing state of the fuel pump 10 , Here is the holding section 50 such on the end portion of the piston 34 pressed on the face 48 of the piston 34 in relation to the support surface 46 of the spring plate 44 an axial oversize 52 in the 2 down.

3 shows the fuel pump 10 from 2 in a second production state following the first production state. In addition, the shows 3 schematically a roller tappet 54 , one in the roller tappet 54 guided role 56 , an eccentric disc 58 (or cam) and an eccentric disc 58 driving wave 60 which elements together drive 62 form. The spring plate 44 and the piston 34 lie during operation of the fuel pump 10 at least temporarily on the roller tappet 54 at.

The Indian 3 shown second manufacturing state of the fuel pump 10 is starting from the first manufacturing state according to 2 achieved as follows: The end face 48 of the piston 34 is on a plane stop surface - in place of in the 3 shown roller tappet 54 - posted. Then, accordingly in the 3 shown arrows (without reference numeral) one the drive 62 opposite axial surface of the spring plate 44 subjected to a pressing force. The pressing force is chosen so large that the holding section 50 axially along the mantle surface of the piston 34 in the 3 is moved down.

This displacement inevitably ends when the drive 62 facing support surface 46 of the spring plate 44 and the drive 62 facing end face 48 of the piston 34 in a drive 62 facing end position of the spring plate 44 are essentially plan to each other. Then according to the excess 52 essentially zero. The said "end position" of the spring plate 44 is understood as a by means of the pressure force of the piston spring 40 causes axial concerns of the spring plate 44 at the holding section 50 ,

4 shows a partial view of a longitudinal section through the fuel pump 10 in a second embodiment, wherein the holding portion 50 a radial groove 50b in the end portion of the piston 34 includes. The groove 50b has a greater axial extent than an axial thickness of the spring plate 44 equivalent. The spring plate 44 is in the roller tappet 54 guided radially and points in the 4 - Instead of the central opening according to 2 and 3 A radially extending insertion slot 64 according to 5 on.

An Indian 4 lower axial end portion of the groove 50b - Or an axial dimension of the spring plate 44 - is dimensioned such that the drive 62 facing support surface 46 of the spring plate 44 and the drive 62 facing end face 48 of the piston 34 in the drive 62 facing end position of the spring plate 44 are essentially plan to each other.

In one embodiment of the fuel pump 10 from 4 have the drive 62 facing support surface 46 of the spring plate 44 and the drive 62 facing end face 48 of the piston 34 in the said end position on an axial offset, such that the support surface 46 of the spring plate 44 an axial projection with respect to the end face 48 of the piston 34 having.

5 shows the spring plate 44 from 4 in a perspective view. In particular, the radially extending insertion slot 64 on the spring plate 44 clearly visible.

6 shows a partial view of a longitudinal section through the fuel pump 10 in a third embodiment, wherein the holding portion 50 a snap ring 50c includes. Between the snap ring 50c and the spring plate 44 is in addition a spring section 50d arranged, which in the present case is designed as a plate spring. In particular, it allows the spring section 50d , an axial play between the piston 34 and the spring plate 44 compensate, so that at maximum compressed diaphragm spring 50d the face 48 of the piston 34 and the support surface 46 of the spring plate 44 essentially plan to each other on the roller tappet 54 can be present.

7 shows a partial view of a longitudinal section through the fuel pump 10 in a further embodiment in which a on the holding portion 50 adjoining radially inner portion of the spring plate 44 is designed such that it can spring in an axial direction. In the present case, the radially inner portion of the spring plate comprises 44 to at least one resilient tab 44a ,

8th shows a flowchart for a method of manufacturing the fuel pump 10 according to the embodiment of the 2 and 3 , In a first process step 66 becomes the fuel pump 10 essentially fully assembled, but with the retaining section 50 such on the end portion of the piston 34 is pressed on, that the face 48 of the piston 34 in relation to the support surface 46 of the spring plate 44 an axial oversize 52 (please refer 2 ) having.

In a subsequent second process step 68 becomes the end face 48 of the piston 34 struck on a plane stop surface of a (not shown) manufacturing device. Then one becomes the drive 62 opposite axial surface of the spring plate 44 subjected to a pressing force. The pressing force is chosen so large that the holding section 50 axially along the mantle surface of the piston 34 (in the 3 down) until the drive 62 facing support surface 46 of the spring plate 44 and the drive 62 facing end face 48 of the piston 34 are essentially plan to each other. This indicates the fuel pump 10 a second manufacturing state and is thus completed.

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

• DT 2425733 A1 [0002]
• EP 1834089 B1 [0002]
• EP 1076174 B1 [0002]

Claims (10)

Fuel pump ( 10 ) with a piston ( 34 ), on whose one drive ( 62 ) facing end portion of a spring plate ( 44 ) is arranged, on which a piston spring ( 40 ) which engages the piston ( 34 ) to the drive ( 62 ), characterized in that at the end portion of the piston ( 34 ) a holding section ( 50 ) is arranged, on which the spring plate ( 44 ) at least indirectly to the drive ( 62 ) is supported, wherein the holding section ( 50 ) relative to the piston ( 34 ) is axially arranged so that a the drive ( 62 ) facing support surface ( 46 ) of the spring plate ( 44 ) and a drive ( 62 ) facing end face ( 48 ) of the piston ( 34 ) in a drive ( 62 ) facing end position of the spring plate ( 44 ) are essentially flat with each other. Fuel pump ( 10 ) according to claim 1, characterized in that the holding section ( 50 ) one on the piston ( 34 ) pressed on ring ( 50a ), one in the piston ( 34 ) incorporated groove ( 50b ), or one on the piston ( 34 ) specified snap ring ( 50c ). Fuel pump ( 10 ) according to one of the preceding claims, characterized in that the spring plate ( 44 ) opposite the piston ( 34 ) has a radial clearance. Fuel pump ( 10 ) according to one of the preceding claims, characterized in that the spring plate ( 44 ) a radially extending insertion slot ( 64 ) having. Fuel pump ( 10 ) according to at least one of the preceding claims, characterized in that between the holding section ( 50 ) and the spring plate ( 44 ) a spring section ( 50d ) is arranged. Fuel pump ( 10 ) according to one of the preceding claims, characterized in that the drive ( 62 ), the support surface ( 46 ) of the spring plate ( 44 ) and the end face ( 48 ) of the piston ( 34 ), a roller tappet ( 54 ), on which the spring plate ( 44 ) and the piston ( 34 ) at least temporarily. Fuel pump ( 10 ) according to at least one of the preceding claims, characterized in that one on the holding section ( 50 ) abutting radially inner portion of the spring plate ( 44 ) is designed such that it can spring in an axial direction. Fuel pump ( 10 ) according to claim 7, characterized in that the radially inner portion of the spring plate ( 44 ) at least one resilient tab ( 44a ). Method for producing a fuel pump ( 10 ) according to at least one of the preceding claims, characterized in that in a first step the holding section ( 50 ) in such a way on the end portion of the piston ( 34 ) is pressed, that the drive ( 62 ) facing end face ( 48 ) of the piston ( 34 ) an axial excess ( 52 ) in relation to the drive ( 62 ) facing support surface ( 46 ) of the spring plate ( 44 ), and that in a second step the holding section ( 50 ) is moved axially such that the drive ( 62 ) facing support surface ( 46 ) of the spring plate ( 44 ) and the drive ( 62 ) facing end face ( 48 ) of the piston ( 34 ) are substantially planar to each other. Method according to claim 9, characterized in that the holding section ( 50 ) is applied to the displacement operation with an axial force, by first one of the drive ( 62 ) facing away from the surface of the spring plate ( 44 ) and secondly the drive ( 62 ) facing end face ( 48 ) of the piston ( 34 ) are each subjected to a force.

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