DE102020211324A1 - high-pressure fuel pump - Google Patents

Abstract

High-pressure fuel pump (10) for a fuel system for an internal combustion engine, the high-pressure fuel pump (10) having a pump housing (12) having a pump body (12a) and a pump cover (12b) mounted on the pump body (41), wherein the high-pressure fuel pump (10) has a delivery chamber (16) which is arranged in the pump body (12a) and is delimited by a displaceable pump piston (18), the high-pressure fuel pump (10) having an inlet valve (14) which has a low-pressure area ( 71) of the fuel pump (10) to the pumping chamber (16) opens towards, wherein the high-pressure fuel pump (10) has an outlet valve (20) from the pumping chamber (16) in the direction of an outlet (34) of the high-pressure fuel pump ( 10) opens towards, wherein between the pump body (12a) and the pump cover (42) for the low-pressure area (71) belonging damper chamber (72) is formed, in which a welded together at their edges Metallm damper box (30a) formed by membranes (73), characterized in that the damper box (30a) is braced against the pump cover (12b) on the one hand and against the pump body (12a) on the other by at least two retaining ring springs (30b, 30c) of identical construction.

Description

State of the art

The invention is based on a high-pressure fuel pump, which has a pump housing in which a pressure damper is arranged, as for example from the WO2018054628 A1 is known. In the known high-pressure fuel pump, the pressure damper is fixed between a pump body and a pump cover by two approximately ring-shaped components.

Disclosure of Invention

The invention is based on the desire to simplify the known device and its manufacture in an expedient manner. According to the invention, it is provided that the damper box is braced against the pump cover on the one hand and against the pump body on the other hand by at least two retaining ring springs that are identical in construction to one another.

Because the retaining ring springs are structurally identical to one another, the number of different components that make up the pressure damper or that brace the damper box against the pump cover on the one hand and against the pump body on the other is significantly reduced compared to the prior art. This is accompanied by a corresponding simplification in the manufacture of the pump, in particular through simplified handling and simplified logistics.

In the present case, a retaining ring spring is understood to mean, in particular, a structure with an at least essentially ring-shaped shape, which is intended to hold a damper box formed from two metal membranes welded together at their edges against the pump cover on the one hand and against the pump body on the other hand and, due to a certain spring effect inherent in it, also in able to brace the axial direction.

Advantageously, it can be provided that the retaining ring springs also have an elasticity or spring effect in the radial direction, by means of which they can be clamped, for example, in the pump body or in the pump cover and thus, for example, during the manufacture of the high-pressure fuel pump before the final completion of the fuel -High-pressure pump can be pre-assembled.

This can be achieved, for example, by the retaining ring springs being open at a position along their circumference, for example over a range of 5° or 10° of the angle of circumference or the like.

The axial elasticity of the retaining ring springs can result from the fact that each retaining ring spring has a profile in radial cross section which consists of a rounded connecting section and two legs protruding from the connecting section in the same radial direction. The legs can be moved towards one another by a force in the axial direction, which acts in the region of the legs, which in turn results in a spring-back reaction of the retaining ring spring in the axial direction.

It is preferred that the rounded connecting section is arranged radially on the outside of the retaining ring spring and rests against the pump body or the pump cover in the radial direction. This ensures that the retaining ring spring lies flat against the pump body or the pump cover and the required forces acting in the radial direction can act reliably and reproducibly between the retaining ring spring and the pump cover or pump body.

Provision is therefore made in particular for the protruding legs to be arranged radially on the inside of the rounded connecting section. In a further development it can be provided that each of the legs has a first section and a second section, the first section being arranged between the second section and the connecting section. The two first sections of a retaining ring spring can be arranged radially on the inside and on opposite axial sides, as viewed from the connection section. It can advantageously be provided that the first two sections are conically shaped. The retaining ring spring then continuously increases in height or potential spring deflection towards the inside in the area of the first sections.

Due to the fact that the two second sections of a retaining ring spring lie in planes parallel to one another in the state in which no forces are acting on the retaining ring spring and/or that in the state in which the retaining ring spring is braced against the damper box, the two second sections with their Pointing radially inward ends in the axial direction results in that between the first and second portions of a leg a rounded abutment portion is formed, which is located beyond the first and second portion in the axial direction as viewed from the connecting portion. It is in particular this contact section via which the retaining ring springs rest against the components that are axially adjacent to them. For example, it is possible that the two retaining ring springs, each with a facility cut on the edge of a metal membrane of the damper box and/or that the retaining ring spring arranged towards the pump body rests with its contact surface arranged towards the pump body on the pump body. In this way, there is a flat and reproducible contact between the adjacent components.

Provision can also be made for the fuel pump to have more than two identical retaining ring springs. For example, two or more retaining ring springs can already be arranged between the damper box and the pump cover. These then preferably also come into contact with one another via their contact surfaces.

Likewise, two or more retaining ring springs can also already be arranged between the damper box and the pump housing. These then also preferably come into contact with one another via their contact surfaces.

Such variants are particularly preferred for pump covers that are relatively high and/or that have, for example, a fuel connection on their radial outside.

It is particularly advantageous if the retaining ring spring arranged towards the pump cover bears against the pump cover with the first section of its leg pointing towards the pump cover, in particular over a large area. In this way, a safe and reproducible system is created.

It is preferably provided that the retaining ring spring has through holes through the first sections. In this way, the entire damper chamber can be traversed and pressure equalization is possible without restrictions in the entire damper chamber.

It is advantageous if each retaining ring spring is essentially rotationally symmetrical about its longitudinal axis.

Substantially rotationally symmetrical means in particular that the retaining ring spring can also be open at one position along its circumference and that in particular it should not be ruled out that the retaining ring spring can have through holes through the first sections, which represent breaks in the rotational symmetry in the strict mathematical sense.

This results in the advantage that the retaining rings do not have to be aligned with respect to their orientation about the longitudinal axis during assembly in the high-pressure fuel pump.

It is advantageous if each retaining ring spring is essentially play-symmetrical to a plane that is perpendicular to its longitudinal axis.

Substantially game-symmetrical includes smaller symmetry breaks, for example due to different or deviating arrangement of through-holes in particular.

This results in the advantage that the retaining rings cannot be installed incorrectly with regard to their orientation in the axial direction.

• 1 eine an sich bekannte Kraftstoff-Hochdruckpumpe in einer Gesamtansicht;
• 2 eine Teilansicht einer gemäß einem ersten Ausführbeispiel erfindungsgemäß modifizierten Kraftstoff-Hochdruckpumpe;
• 3 einen vergrößerten Ausschnitt aus 3;
• 4 eine Teilansicht einer gemäß einem zweiten Ausführbeispiel erfindungsgemäß modifizierten Kraftstoff-Hochdruckpumpe.

Exemplary embodiments of the invention are explained below with reference to the drawing. Show in the drawing:

• 1 a known high-pressure fuel pump in an overall view;
• 2 a partial view of a modified according to a first embodiment of the invention high-pressure fuel pump;
• 3 an enlarged section 3 ;
• 4 a partial view of a modified according to a second embodiment of the invention high-pressure fuel pump.

In 1 carries a high-pressure fuel pump for an internal combustion engine, not shown, overall reference numeral 10. The high-pressure fuel pump 10 has an overall substantially cylindrical pump housing 12, in or on which the essential components of the high-pressure fuel pump 10 are arranged. Thus, the high-pressure fuel pump 10 has an inlet/quantity control valve 14 , a delivery piston 18 arranged in a delivery chamber 16 and capable of reciprocating movement by a drive shaft (not shown), an outlet valve 20 and a pressure-limiting valve 22 .

In the housing 12 there is a first duct 24 which extends coaxially to the delivery chamber 16 and to the delivery piston 18 and which leads from the delivery chamber 16 to a second duct 26 formed by a recess which is at an angle of 90° to the first duct 24 is arranged and in which the pressure relief valve 22 is accommodated. A longitudinal axis of the pump housing 12 carries in 1 overall reference number 28, a longitudinal axis or longitudinal direction of the pressure relief valve 22 reference number 29. In 1 A pressure damper 30 is arranged at the top in the pump housing 12, between the pump cover 12b on the one hand and the pump body 12b.

In operation, fuel is supplied by the delivery piston 18 during an intake stroke via the inlet and quantity control valve 14 into the delivery chamber 16 sucks. During a delivery stroke, the fuel in delivery chamber 16 is compressed and ejected via outlet valve 20, for example, into a high-pressure region 32, for example to a fuel collection line (“rail”), where the fuel is stored under high pressure. The high-pressure area 32 is connected to the high-pressure fuel pump 10 via an outlet connection 34 . The amount of fuel that is ejected during a delivery stroke is set by the electromagnetically actuated inlet and quantity control valve 14 . In the event of an impermissible excess pressure in the high-pressure area, the pressure-limiting valve 22 opens, as a result of which fuel can flow from the high-pressure area into the pumping chamber 16 .

the 2 and 3 show an example of a modification according to the invention of 1 shown pump. while showing 2 the upper section of the pump housing 12, namely the upper section of the pump body 12a and the pump cover 12b fixed on it. 3 shows enlarged the in 2 section marked III, the profile of the retaining ring spring 30b, 30c in detailed radial cross-section. In the 3 is the profile in the as in 2 State shown dark when installed in the high-pressure fuel pump. Dem is in the 3 the profile of the retaining ring spring 30b, 30c in the relaxed state, in which no forces act on the retaining ring spring 30b, 30c, is brightly contrasted.

A pressure damper 30 according to the invention is arranged between the pump body 12a and the pump cover 12b. It comprises a damper box 30a, which consists of two metal membranes 73 welded together at their edges along a circumferential weld seam 93, and two identical retaining ring springs 30b, 30c, which brace the damper box 30a against the pump cover 12b on the one hand and against the pump body 12a on the other.

The retaining ring springs 30b, 30c have a profile in radial cross section which consists of a rounded connecting section 85 and two legs 84, 86 projecting radially inwards from the connecting section.

The legs 84, 86 each have a first section 83, 87 and a second section 81, 89, with the first section 83, 87 being arranged between the second section 81, 89 and the connecting section 85.

In the example, it is provided that the two first sections 83, 87 of a retaining ring spring 30b, 30c are arranged radially inwards and on opposite axial sides, viewed from the connecting section 85—above and below the connecting section 85 in the figures.

The two first sections 83, 87 are conically shaped in this example, so that they appear as straight sections in the cross sections shown in the figures. Through bores 90 are provided through the first sections 83, 87, so that the damper chamber 72 can be flowed through overall or pressure equalization within the damper chamber 72 can be produced.

It is also provided in the example that the retaining ring spring 30b arranged towards the pump cover 12b bears flat against the pump cover 12b with the first section 87 of its leg 86 pointing towards the pump cover 12b.

In this example, it is further provided that the two second sections 81, 89 of each retaining ring spring 30b, 30c in the state in which no forces are acting on the retaining ring spring 30b, 30c (bright in 3 ), lie in mutually parallel planes, in particular perpendicular to the longitudinal axis 28.

A force acting downwards on the upper leg and upwards on the lower leg, for example in the state in which the retaining ring springs 30b, 30c brace the damper box 30a within the high-pressure fuel pump 10, causes the legs 84, 86 to be light and elastic on one another to be deformed according to the elasticity of the retainer ring springs 30b, 30c in the axial direction. Furthermore, between the first 83, 87 and the second sections 81, 89 of a leg 84, 86, a rounded contact section 82, 88 is formed which, seen from the connecting section 85, extends in the axial direction beyond the first 83, 87 and the second section 81 , 89 is arranged.

The two retaining ring springs 30b, 30c each rest with a contact section 82, 88 on the edge of a metal membrane 73 of the damper box 30a, in particular on the circumferential weld 93 on the edge of the metal membranes 73.

The retaining ring spring 30b, 30c arranged towards the pump body 12a rests with its contact surface 82 arranged towards the pump body 12a on the pump body 12a.

the 4 shows an alternative embodiment of the invention. The damper box 30a is braced against the pump cover 12b on the one hand and against the pump body 12a on the other by more than two retaining ring springs 30b, 30b′, 30c, 30c′, 30c″ of the same construction. In the example, five retaining ring springs 30b, 30b', 30c, 30c', 30c'', two above and three below the damper can 30a.

In this example, the retaining ring springs 30b, 30b', 30c, 30c', 30c'' are open at a position 7 along their circumference, so that they have elasticity in the radial direction, ie in the radial direction into the pump cover 12b as in the examples or alternatively can be clamped in the pump body 12a.

In the example of 4 a comparatively high pump cover 12b is realized. A fluid connection 91, for example an inlet for a fuel such as petrol, is provided on its radial outer surface. A filter 92 is housed inside the inlet.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was 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.

Patent Literature Cited

• WO 2018054628 A1 [0001]

Claims (14)

High-pressure fuel pump (10) for a fuel system for an internal combustion engine, the high-pressure fuel pump (10) having a pump housing (12) having a pump body (12a) and a pump cover (12b) mounted on the pump body (12a), wherein the high-pressure fuel pump (10) has a delivery chamber (16) which is arranged in the pump body (12a) and is delimited by a displaceable pump piston (18), the high-pressure fuel pump (10) having an inlet valve (14) which has a low-pressure region ( 71) of the fuel pump (10) to the pumping chamber (16) opens towards, wherein the high-pressure fuel pump (10) has an outlet valve (20) from the pumping chamber (16) in the direction of an outlet (34) of the high-pressure fuel pump ( 10) opens towards it, a damper chamber (72) belonging to the low-pressure area (71) being formed between the pump body (12a) and the pump cover (12b), in which a damper chamber (72) welded together at their edges is formed damper box (30a) formed by membranes (73), characterized in that the damper box (30a) is braced against the pump cover (12b) on the one hand and against the pump body (12a) on the other by at least two retaining ring springs (30b, 30c) of identical construction. High-pressure fuel pump (10) after claim 1 , characterized in that the retaining ring springs (30b, 30c) are open at a position (7) along their circumference, so that the retaining ring springs (30b, 30c) have elasticity in the radial direction. High-pressure fuel pump (10) after claim 1 or 2 , characterized in that the retaining ring springs (30b, 30c) are clamped in the radial direction in the pump body (12a) or the pump cover (12b). High-pressure fuel pump (10) one of Claims 1 until 3 , characterized in that each retaining ring spring (30b, 30c) has a profile in radial cross section which consists of a rounded connecting section (85) and two legs (84, 86) projecting from the connecting section in the same radial direction, so that the retaining ring spring ( 30b, 30c) has elasticity in the axial direction. High-pressure fuel pump (10) after claim 4 , characterized in that the rounded connecting section (85) is arranged radially on the outside of the retaining ring spring (30b, 30c) and bears against the pump body (12a) or the pump cover (12b) in the radial direction. High-pressure fuel pump (10) after claim 4 or 5 , characterized in that the projecting legs (84, 86) are disposed radially inward of the rounded connecting portion, each of the legs (84, 86) having a first portion (83, 87) and a second portion (81, 89), wherein the first section (83, 87) being arranged between the second section (81, 89) and the connecting section (85), the two first sections (83, 87) having a retaining ring spring (30b, 30c) from the connecting section (85). viewed radially inwards and on opposite axial sides. High-pressure fuel pump (10) after claim 6 , characterized in that the first two sections (83, 87) are conically shaped. High-pressure fuel pump (10) after claim 6 or 7 , characterized in that the two second sections (81, 89) of a retaining ring spring (30b, 30c) in the state in which no forces are acting on the retaining ring spring (30b, 30c) lie in mutually parallel planes. High-pressure fuel pump (10) according to one of Claims 6 until 8th , characterized in that in the state in which the retaining ring spring (30b, 30c) the damper box (30a) are braced, the two second sections (81, 89) with their ends pointing radially inwards point towards one another in the axial direction, so that between the first (83, 87) and the second sections (81, 89) of a leg (84, 86) a rounded contact section (82, 88) is formed which, seen from the connecting section (85) in the axial direction beyond the first (83, 87) and second section (81, 89). High-pressure fuel pump (10) after claim 9 , characterized in that the two retaining ring springs (30b, 30c) each have a contact section (82, 88) on the edge of a metal membrane (73) of the damper box (30a), in particular on the weld (93). High-pressure fuel pump (10) after claim 9 or 10 , characterized in that the retaining ring spring (30b, 30c) arranged towards the pump body (12a) rests with its contact surface (82, 88) arranged towards the pump body (12a) on the pump body (12a). High-pressure fuel pump (10) according to one of Claims 6 until 11 , characterized in that the pump cover (12b) arranged towards the retaining ring spring (30b, 30c) with the first section (83, 87) of its leg (84, 86) pointing towards the pump cover (12b), in particular flat, rests against the pump cover (12b). High-pressure fuel pump (10) according to one of Claims 6 until 12 , characterized in that the retaining ring spring (30b, 30c) has through bores (90) through the first sections (83, 87), so that the damper chamber (72) can be flowed through overall. High-pressure fuel pump (10) according to one of Claims 1 until 13 characterized in that each retaining ring spring (30b, 30c) is substantially rotationally symmetrical about its longitudinal axis and substantially mirror symmetrical about a plane perpendicular to its longitudinal axis.

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