DE102018209333A1 - High-pressure fuel pump - Google Patents

Abstract

A high-pressure fuel pump for a fuel injection system of an internal combustion engine comprises a pump housing, which comprises a housing cover, and an inlet connector (30), which is fastened to the housing cover and in which a filter device (32) is arranged. It is proposed that the filter device (32) be held axially in the inlet connection (30) with radial play (72).

Description

State of the art

The invention relates to a high-pressure fuel pump according to the preamble of claim 1.

From the market, high-pressure fuel pumps are known, which belong to a fuel injection system of an internal combustion engine. These high-pressure fuel pumps comprise a generally cylindrical housing body in which a delivery piston is movably guided. On the front side, a hood-like housing cover is attached to the housing body, below which a pressure damper, usually a diaphragm damper, is arranged. The housing cover may be formed as a thin-walled sheet metal part. The supply of the fuel to the high pressure fuel pump via an inlet nozzle, which is attached to the housing cover, for example by soldering. In the inlet nozzle, a filter device is arranged and held in the inlet nozzle in a press fit.

Disclosure of the invention

Object of the present invention is to provide a high-pressure fuel pump, which is robust in operation and can be produced inexpensively.

This object is achieved by a high-pressure fuel pump with the features of claim 1. Advantageous developments of the invention are specified in subclaims. For the invention essential features are also found in the following description and in the accompanying drawings.

The high-pressure fuel pump according to the invention for a fuel injection system of an internal combustion engine comprises a pump housing, which in turn comprises a housing cover. The housing cover may be formed as a hood-like and thin-walled metallic sheet metal part, and usually it sits frontally on a substantially cylindrical housing body in which a delivery piston is movably guided. In the enclosed between the housing body and the housing cover space, a pressure damper may be accommodated, which should dampen low-pressure side pressure pulsations.

The fuel high-pressure pump also includes an inlet nozzle, which is attached to the housing cover. For example, the inlet nozzle may be made of metal and protrude from the housing cover in the radial or in the axial direction of the high-pressure fuel pump. During operation of the high-pressure fuel pump, the inlet connection is connected to a low-pressure-side fuel supply, for example an outlet of a preferably electric prefeed pump. About the inlet port of the high-pressure fuel pump is thus supplied to the fuel. In order to protect the high-pressure fuel pump against contaminants present in the fuel, a filter device is arranged in the inlet connection. According to the invention it is proposed that the filter device is held axially in the inlet nozzle with radial clearance.

According to the invention, the filter device in the inlet connection is thus dispensed with in order to fix the previously used radial press connection of the filter device in the inlet connection and instead holds the filter device with a - usually very small - radial play in the inlet connection. This has the advantage that a temperature-induced distortion, in particular of the inlet nozzle, caused by a thermal method when connecting the inlet nozzle to the housing cover has no effect on the mounting of the filter device in the inlet nozzle. Since the outer diameter of the filter device no longer has a sealing and fixing function, a corresponding outer tolerance of at least that portion of the filter device by means of which the filter device is held in the inlet nozzle, can be chosen much more generous, whereby the manufacturing costs are reduced. Nevertheless, sufficient holding forces of the filter device can be realized in the inlet nozzle, and it ensures the integrity of a filter fabric of the filter device. It is advantageous if an axial support of the filter device to compensate for axial changes in length of the filter device to a certain extent in a position.

A development of the invention is characterized in that the filter device rests at least on a first axial side against an annular first holding element, which is fixed relative to the inlet nozzle at least in a first axial direction. Thus, the course of the inner wall of the inlet nozzle can be formed comparatively simple, whereby the production costs are kept low.

A development of the invention is characterized in that the filter device additionally bears on a second axial side, which is opposite from the first axial side, on a second holding element, which is annular and at least in a second axial direction, which is the first axial Direction is opposite, relative to the inlet nozzle is fixed. Thus, the filter device is held in the axial direction between two holding elements, whereby the inner wall of the inlet nozzle can be particularly simple, whereby the manufacturing costs are kept low.

A development of the invention is characterized in that at least one of the retaining elements is formed by a snap ring, which is held in a circumferential groove in an inner wall of the inlet nozzle. Such a groove can be introduced very inexpensively into an inner wall of the inlet nozzle. The proposed snap ring allows by its split shape reliable fixation even with large fluctuations in the inner diameter of the inlet nozzle.

A development of the invention is characterized in that at least one of the holding elements is formed by a compression sleeve which is pressed against the inner wall of the inlet nozzle. As an alternative or in addition to a retaining element designed as a snap ring, this provides a possibility of fixing a retaining element without a groove in the inner wall of the inlet neck, thereby further reducing the production costs.

A development of the invention is characterized in that at least one of the holding elements comprises an annular sealing element, preferably formed by such. In this way, a reliable seal between the filter device and the inlet nozzle is created, so that it is ensured that contaminants in the fuel can not pass the filter device into the interior of the high-pressure fuel pump. Advantageously, in such a case, the sealing element is designed as an axially acting sealing element.

A development of the invention is characterized in that the annular sealing element comprises an axial seal and is partially received in a groove which is formed in an axial shoulder of an inner wall of the inlet nozzle. This also reduces the manufacturing costs, since a simple O-ring can be used as the sealing element, which acts on the filter device against the other holding element due to its spring elasticity, so that the filter device is held securely and immovably in the axial direction. In this case, the sealing of the filter device relative to the inlet connection due to the axial seal is independent of, for example, temperature-induced distortion of the inlet connection.

A development of the invention is characterized in that the filter device has a cylindrical base portion and a filter section extending therefrom, wherein the above-mentioned first axial side and / or the above-mentioned second axial side are provided on the base portion. Thus, in the filter device, the holding function is separated from the filter function, so that damage to the filter section and thus a restriction of the filter function are avoided by the holder of the filter device in the inlet nozzle. Usually, the base portion is formed as a rigid and solid ring, whereas the filter portion is formed as an axially extending from the base portion cup-shaped portion whose peripheral wall is at least partially made of a filter fabric.

A development of the invention is characterized in that a radial seal is arranged between an inner wall of the inlet nozzle and an outer wall of the filter device. In addition or as an alternative to the above-mentioned axial sealing, a simple seal between the filter device and the inner wall of the inlet nozzle can be realized in this way, for example when using two retaining elements formed by snap rings or press sleeves.

A development of the invention is characterized in that the inlet pipe is welded, soldered or pressed to the housing cover. These connection methods are inexpensive and ensure a reliable and long-lasting fluid-tight connection between the inlet nozzle and the housing cover.

• 1 einen teilweisen Schnitt durch eine Kraftstoff-Hochdruckpumpe mit einer ersten Ausführungsform eines Einlassstutzens und einer in diesem angeordneten Filtereinrichtung;
• 2 einen Schnitt durch einen Bereich des Einlassstutzens und der Filtereinrichtung von 1;
• 3 eine Darstellung ähnlich zu 2 einer zweiten Ausführungsform eines Einlassstutzens und einer in diesem angeordneten Filtereinrichtung; und
• 4 eine Darstellung ähnlich zu 2 einer dritten Ausführungsform eines Einlassstutzens und einer in diesem angeordneten Filtereinrichtung.

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

• 1 a partial section through a high-pressure fuel pump with a first embodiment of an inlet nozzle and arranged therein filter device;
• 2 a section through a portion of the inlet nozzle and the filter device of 1 ;
• 3 a representation similar to 2 a second embodiment of an inlet nozzle and arranged therein filter device; and
• 4 a representation similar to 2 a third embodiment of an inlet nozzle and arranged in this filter device.

In the following figures, functionally equivalent elements and regions in different embodiments bear the same reference numerals.

In 1 carries a fuel high-pressure pump for an internal combustion engine, not shown in detail, the reference numeral 10 , The fuel high pressure pump 10 has an overall substantially cylindrical pump housing 12 on, in or on which the essential components of High-pressure fuel pump 10 are arranged. So points the high-pressure fuel pump 10 an intake / quantity control valve 14 , a part in a pump room 16 arranged, displaceable by a drive shaft, not shown, in a reciprocating motion delivery piston 18 , an outlet valve 20 and a pressure relief valve 22 on.

The pump housing 12 comprises a substantially cylindrical housing body 24 and a front side on this patch and with this fluid-tightly connected housing cover 26 , The housing body 24 and the housing cover 26 are made of metal, the housing body 26 while a thin-walled sheet material. In the between the housing cover 26 and the housing body 24 formed space (without reference numeral) is an example here as a diaphragm damper trained pressure damper 28 arranged, and on the housing cover 26 is a cylindrical and tubular inlet nozzle 30 attached, which in the present example protrudes radially to the side. In the inlet pipe 30 is a filter device 32 arranged. This will be further discussed below with reference to 2 be discussed in greater detail. The inlet nozzle 30 is with a low pressure area 34 connected, for example, the outlet of an electric feed pump.

In operation, the delivery piston 18 at a suction stroke fuel - in the present example, gasoline - via the inlet nozzle 30 and the intake and quantity control valves 14 in the pump room 16 sucked. In a delivery stroke of the delivery room 16 compressed fuel and via the exhaust valve 20 For example, in a high-pressure area 36 , For example, to a fuel rail ("Rail") ejected, where the fuel is stored under high pressure. The high pressure area 32 is via an outlet 38 with the high-pressure fuel pump 10 connected. The amount of fuel that is expelled during a delivery stroke, thereby by the solenoid-operated intake and quantity control valve 14 set.

Now it will open 2 Reference is made in which a portion of the inlet nozzle 30 and the filter device 32 enlarged and shown in more detail. First to the filter device 32 This includes a cylindrical base section 40 and a projecting from this cylindrical and pot-like filter section 42 , During the base section 40 is formed as a solid plastic part or metal part, is the filter section 42 at least partially, for example in the region of its peripheral wall, produced by a filter fabric made of plastic or metal. The filter device 32 can be made as an integral part. The base section 40 has a larger outer diameter than the filter section 42 , In this way, on a first axial side 44 of the base section 40 in a first axial direction 46 shows, one in the first axial direction 46 pointing end face ring surface 48 educated. The base section 40 has a second axial side 50 on, from the first axial side 44 is opposite and in a second axial direction 52 shows. The second axial direction 52 is opposite to the first axial direction 46 , On the second page 50 is at the base section 40 one in the second direction 52 showing circular end face 54 educated.

Now to the inlet pipe 30 : This has a present stepped inner wall 56 on. In this is a circumferential circumferential groove 58 introduced into which a snap ring 60 is used. Furthermore, by the stepped inner wall 56 in the second axial direction 52 pointing annular heel 62 formed in which an axial groove 64 is available. In this is an annular elastic sealing element 66 in the form of an axial seal, namely an O-ring used.

One recognizes 2 in that the base portion is on the first axial side 44 with its existing ring surface 48 on the sealing element 66 is applied, so that this is a first holding element 68 forms. It also recognizes 2 in that the base portion is on the second axial side 50 at the snap ring 60 rests, so this of a second holding element 70 for the filter device 32 forms. Due to the elasticity of the sealing element 66 this presses the base section 40 against the snap ring 60 , In this way, the filter device 32 fixed, that is essentially immobile, between the two holding elements 68 and 70 in the inlet nozzle 30 held. It also recognizes 2 in that seen in the radial direction between the inner wall 56 of the inlet nozzle 30 and the outer wall (not numbered) of the base portion 40 a radial game 72 is available.

The embodiment of the 3 is different from that of 2 in that the second retaining element 70 not by a snap ring, but by a compression sleeve 74 is formed, the press fit in the radial direction against the inner wall 56 is pressed.

In the embodiment of the 4 turn on a stepped inner wall 56 waived. Instead, both are holding elements 68 and 70 through snap rings 60a and 60b formed in circumferential grooves 58a and 58b are arranged. The seal between the filter device 32 and the inlet nozzle 30 takes place in that in the inner wall 56 another circumferential groove 76 exists in which a radial seal 66 is used in the form of an O-ring. This radial seal 66 is between the inner wall 56 of the inlet nozzle 30 and the outer wall (not numbered) of the base portion 40 the filter device 32 arranged.

In all embodiments, the inlet port 30 on the housing cover 26 be attached by soldering, welding or pressing.

Claims (10)

A high-pressure fuel pump (10) for a fuel injection system of an internal combustion engine, comprising a pump housing (12), which comprises a housing cover (26), and with an inlet port (30) which is fixed to the housing cover (26) and in which Filter device (32) is arranged, characterized in that the filter device (32) is held axially in the inlet nozzle (30) with radial play (72). High-pressure fuel pump (10) after Claim 1 , characterized in that the filter device (32) at least on a first axial side (44) against an annular and at least in a first axial direction (46) relative to the inlet nozzle (30) fixed first holding element (68). High-pressure fuel pump (10) after Claim 2 characterized in that the filter means (32) is additionally provided on a second axial side (50) opposite from the first axial side (44) in an annular and at least a second axial direction (52) to the first axial direction (46) is opposite, relative to the inlet nozzle (30) fixed second holding element (70). High-pressure fuel pump (10) after at least one of Claims 2 or 3 characterized in that at least one of the retaining elements (70) is formed by a snap ring (60) held in a circumferential groove (58) in an inner wall (56) of the inlet nozzle (30). High-pressure fuel pump (10) after at least one of Claims 2 - 4 , characterized in that at least one of the retaining elements (70) is formed by a compression sleeve (74) which is pressed against the inner wall (56) of the inlet nozzle (30). High-pressure fuel pump (10) after at least one of Claims 2 - 5 , characterized in that at least one of the holding elements (68) comprises an annular sealing element (66), preferably formed by such. High-pressure fuel pump (10) after Claim 6 , characterized in that the annular sealing member (66) comprises an axial seal and is partially received in a groove (64) formed in an axial shoulder (62) of an inner wall (56) of the inlet nozzle (30). High-pressure fuel pump (10) after at least one of Claims 2 - 7 characterized in that the filter means (32) comprises a cylindrical base portion (40) and a filter portion (42) extending therefrom, the first axial side (44) and / or the second axial side (50) being secured to the base portion (40). 40) are present. High-pressure fuel pump (10) according to at least one of the preceding claims, characterized in that between a inner wall (56) of the inlet nozzle (30) and an outer wall of the filter device (32) a radial seal (66) is arranged. High-pressure fuel pump (10) according to at least one of the preceding claims, characterized in that the inlet nozzle (30) with the housing cover (26) is welded, soldered or pressed.

Images