DE102016205428A1 - Pressure damping device for a fluid pump, in particular for a high pressure pump of a fuel injection system - Google Patents

Abstract

A pressure damping device (10) for a fluid pump (10), in particular for a high-pressure pump of a fuel injection system with at least one damping element (30), which is arranged in a fluid chamber (15), is proposed. The fluid pump (10) has a housing (11). A separate housing body (21) is provided, in which the fluid space (15) for receiving the damping element (30) is formed. The separate housing body (21) is attached to the housing (11) of the fluid pump (10).

Description

The invention relates to a pressure damping device for a fluid pump, in particular for a high pressure pump of a fuel injection system of an internal combustion engine according to the preamble of claim 1.

State of the art

In fuel injection systems, high pressure pumps are used as fluid pumps that compress fuel to a high pressure and deliver it to a high pressure accumulator. The pressure in the high-pressure accumulator serves as injection pressure, with which the fuel is injected into a combustion chamber of an internal combustion engine. In order to dampen pressure fluctuations in a low-pressure line via which the fuel is supplied to the high-pressure pump, pressure damping devices are provided.

As pressure damping devices, for example, diaphragm dampers or diaphragm cans are used. As a rule, the diaphragm dampers form separate components that are attached to the high-pressure pump. A diaphragm damper attached to the high-pressure pump is known, for example, from the document DE 10345725 A1 known. The diaphragm damper is accommodated in a fluid space, which forms between a flat end face of the housing of the high-pressure pump and a housing cover. Through the fluid space, the fuel is passed on the low-pressure side to the intake valve of the high-pressure pump, so that the pressure pulsations emanating from the high-pressure pump are damped in the direction of the low-pressure circuit.

Based on the above-mentioned prior art, the present invention seeks to provide a pressure damping device for a fluid pump, in particular for a high-pressure pump of a fuel injection system, which is simple in construction and requires only small space.

Disclosure of the invention

To solve the problem, a pressure damping device with the characterizing features of claim 1 is proposed. The fact that the damping element is arranged in a separate housing body, it is possible that the pressure damping device can be attached as an independent component outside the housing of the fluid pump. For the separate housing body can be found on the housing of the fluid pump a suitable place to allow a space-saving design. By means of the pressure damping device, the pressure pulsations in the low-pressure region of the fuel injection system is counteracted.

Advantageous developments of the inventions will become apparent from the features of the dependent claims.

An easily realizable pressure damping device is possible if the separate housing body comprises two housing parts. For this purpose, the two housing parts are preferably each plate-shaped and each have a recess with a peripheral edge for receiving the at least one damping element.

For positioning the at least one damping element within the housing body, at least one of the two housing parts supporting segments, on which the damping element rests with an edge, wherein the damping element is held by means of a spring element on the support segments. An influx of the damping element is achieved when between the support segments flow openings are formed, which allow a sufficient flow through the fluid space.

In order to form the flow openings on the second housing part, in a first embodiment the second housing part has a peripheral edge with undercuts, wherein the support segments are formed between the undercuts and the gaps between the support segments form the flow openings. In this embodiment, the second housing part rests with a substantially flat bearing surface on a first end face of the fluid pump. In this embodiment, the attachment of the separate housing body to the fluid pump without modification of the housing of the fluid pump is possible. Preferably, a connecting piece for a supply line is formed on the first housing part.

According to a second embodiment, the second housing part is designed as a cylindrical bottom part, which is hydraulically sealed in the first cylindrical recess of the first housing part. In this case, the cylindrical bottom part preferably has a closed contact surface, with which the bottom part rests against a second substantially planar end face of the housing, wherein the second planar end face is formed substantially perpendicular to the first planar end face on the housing of the fluid pump.

To attach the separate housing body to the housing of the fluid pump, the first housing part is equipped with at least two projections in the second embodiment, with which the Housing body is screwed to the first end face of the housing of the fluid pump.

A particularly advantageous embodiment is when on a narrow side of the housing body, in particular on a narrow side of the first housing part, a first connection piece for a supply line is formed. By this lateral connection for the supply line and by a preferably further lateral connection for the inlet channel takes place a lateral pressurization of the at least one damping element, whereby the pressure load can be equally distributed over the active surfaces of the damping element.

embodiments

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description.

Show it:

1 1 is a partial perspective view of a fluid pump with a pressure damping device according to a first embodiment,

2 an enlarged perspective sectional view of the pressure damping device 1 .

3 3 a perspective partial view of a fluid pump with a pressure damping device according to a second exemplary embodiment,

4 a perspective sectional view of the pressure damping device in 3 .

5 a second perspective sectional view of the pressure damping device in 3 and

6 a perspective view of the pressure damping device in 5 ,

In the 1 to 6 is a pressure damping device 20 for a fluid pump 10 shown. In the present embodiments, the fluid pump is 10 each to a high-pressure pump of a fuel injection system of an internal combustion engine. The high pressure pump 10 has a housing 11 with a first flat face 12 on. In the case 11 is an inlet channel 13 formed over which the fuel one in the housing 11 arranged and not shown pump working space is supplied for example via an inlet valve. In the pump working chamber, the fuel is compressed by means of a pump piston, also not shown. The compressed fuel is pumped via an outlet, not shown, into a high-pressure accumulator of the fuel injection system. The housing 11 is screwed to an engine block, not shown, of the internal combustion engine.

For damping of pressure pulsations, the pressure damping device 20 at least one damping element 30 on that in a fluid room 15 is arranged. The fluid space 15 is at a direction indicated by an arrow low-pressure side supply line 19 hydraulically connected to the fuel injection system. Through the fluid space 15 the fuel is the low pressure side via the inlet channel 13 and the inlet valve, not shown, the pump working space of the high-pressure pump 10 supplied by the high pressure pump 10 outgoing pressure pulsations via the inlet channel 13 back to the fluid space 15 and thereby in the direction of the low pressure line 19 Act. By means of the pressure damping device 20 is the pressure pulsations in the fluid space 15 and thus counteracted in the low pressure region of the fuel injection system. This improves the function of the fuel injection system.

The fluid space 15 is in one outside the case 11 the high pressure pump 10 arranged separate, preferably flat housing body 21 formed, which, as will be described in more detail later, on the housing 11 the high pressure pump 10 is attached. In the housing body 21 this is at least one damping element 30 held with a biasing device.

In the first embodiment in 1 and 2 stands on the housing 10 the high pressure pump 10 the first flat face 12 with a sufficiently large area available, which allows the flat housing body 21 with a flat broadside on the face 12 with the housing 11 can be connected.

The housing body 21 has two plate-shaped housing parts, namely a first, outer housing part 21.1 and a second, housing-side housing part 21.2 , The two housing parts 21.1 . 21.2 , which are made for example of plastic, preferably made of thermosetting plastic, limit the fluid space 15 so that the separate housing body 21 the at least one damping element 30 absorbs for damping hydraulic pressure pulsations.

In the first embodiment, the first housing part 21.1 according to 2 with a first, preferably cylindrical recess 22 with a top surface 23 executed. The first recess 22 is from a first circumferential edge 24 with a first, preferably annular end face 25 surround. On the first housing part 21.1 is according to 1 a first connecting piece 41 for connecting the supply line 19 formed. The connecting piece 41 leads with an opening, not shown, on the top surface 23 in the fluid space 15 ,

The second housing part 21.2 indicates according to the first embodiment 2 a second, preferably cylindrical recess 26 with a floor surface 27 on. Furthermore, the second housing part 21.2 a housing-side flat bearing surface 28 on, with which the second housing part 21.2 on the planing face 12 of the housing 11 lies flat and by means of fastening screws 16 is attached. In the floor area 27 There is an opening with the inlet channel 13 communicates and the between the end face 12 and the bearing surface 28 to the inlet channel 13 is sealed off with a sealing ring. On the second housing part 21.2 is another connecting piece 42 formed for example, a return line.

On the second housing part 21.2 is still a second cylindrical recess 26 enclosing second edge 32 formed, which from an outer circumferential annular surface 29 is surrounded. In the circumferential ring surface 29 For example, a sealing ring is embedded. When attaching the separate housing body 21 on the housing 11 pushes the first housing part 21.1 with the first circumferential end face 25 on the ring surface 29 , creating a hydraulically tight connection between the two housing parts 21.1 and 21.2 arises.

The second circumferential edge 32 forms with one in the fluid space 15 pointing step 31 and with undercuts distributed over the circumference 34 over the circumference of the second edge 32 distributed support segments 35 with support surfaces 33 out. On the support surfaces 33 the support segments 35 lies the damping element 30 in the form of a membrane can with a rim 36 on. On the opposite side presses a coil spring 37 on the edge 36 , where the coil spring 37 with its other end on the top surface 23 of the first housing part 21.1 supported. This will make the damping element 30 in the housing body 21 held or braced. The undercuts 34 form on the second circumferential edge 32 between the support segments 35 flow openings 38 so that the fuel is the fluid space 15 can flow through

At one in the 3 to 6 The second embodiment shown is the high-pressure pump 10 for example, with a metering unit 40 equipped on the first face 12 is positioned. As a result, stands on the front surface 12 no adequate space for attaching the separate housing body 21 to disposal. Accordingly, in the in the 3 to 6 illustrated second embodiment, the housing 11 the high pressure pump 10 and the housing body 21 the pressure damping device 20 modified accordingly. For this purpose, according to 5 and 6 the housing 11 the high pressure pump 10 a second plane face 17 on, preferably perpendicular to the first end face 12 on the housing 11 runs. The housing body 21 is on the case 11 another third face 18 assigned. The other end face 18 runs thereby on the housing 11 also preferably at right angles to the second end face 17 ,

The housing body 21 has in the second embodiment, a cuboid shape, which requires a modification of the connecting piece. The first connection piece 41 for the supply line 19 the fuel injection system is laterally on a first narrow side 44 on the first housing part 21.1 formed. At a right angle extending second narrow side 45 , which on the third end face 18 rests, is another connecting piece 46 molded, with a sealing ring in the housing 11 trained inlet channel 13 hydraulically tight. Due to the lateral connection of the supply line 19 and the inlet channel 13 there is a better lateral flow through the fluid space 15 , whereby the at least one damping element 30 flows around radially with fuel. This achieves a better damping of the pulsation waves. The flow direction here is not the direction of flow of the fuel, but the direction of the pressure pulsations emanating from the pump working space of the high-pressure pump and back into the fluid space 15 Act. In addition, an integration of further feed interfaces in the form of further connecting pieces is possible. Optionally, a temperature sensor can be provided.

How out 5 and 6 shows, in the second embodiment, the pressure damping device 20 for example, two damping elements 30.1 and 30.2 each in the form of a membrane can. The two damping elements 30.1 . 30.2 be by means of a spiral spring 53 as a biasing device in the housing parts 21.1 and 21.2 held or braced. On the first housing part 21.1 are on the deck area 23 the first recess 22 first support segments 48 each with a first support surface 49 arranged in a circle. On the support surfaces 49 is that the case 11 remote first damping element 30.1 with a border 36.1 on.

How out 5 and 6 continues to show, was due to space reasons, the second housing part 21.2 in the first recess 22 of the first housing part 21.1 sunk. This is the second housing part 21.2 as a cylindrical bottom part 50 with another peripheral edge 51 executed where the outer diameter of the peripheral edge 51 to the inner diameter of the first cylindrical recess 22 of the first housing part 21.1 is adjusted. The bottom part 50 also has a flat, for example, closed outer bearing surface 58 on. With the support surface 58 becomes the case body 21 at the second end face 17 of the housing 11 aligned. The outer peripheral surface of the peripheral edge 51 is provided with a groove for receiving a sealing ring, so that the second circumferential edge 51 of the cylindrical bottom part 50 with the peripheral surface in the first recess 22 hydraulically sealed. This arises within the housing body 22 the required fluid space 15 ,

Furthermore, the second circumferential edge 51 of the bottom part 50 in the first cylindrical recess 22 pointing second support segments 54 each with second frontal support surfaces 55 on. On the second support surfaces 55 the second support segments 54 lies the housing-side second damping element 30.2 with a border 36.2 on. The second support segments 54 are similar to the first support segments 48 spaced from each other so that there are gaps therebetween, the second flow openings 56 form.

The for clamping the two damping elements 30.1 . 30.2 serving spiral spring 53 is between the two damping elements 30.1 . 30.2 arranged. This is supported by one end of the coil spring 53 on the edge 36.1 of the first damping element 30.1 and the other end of the coil spring 53 on the edge 36.2 of the second damping element 30.2 from. When attaching the case body 21 on the housing 11 the high pressure pump 10 the bias of the spring element takes place 53 by the bottom part 50 in the first recess 22 of the first housing part 21.1 is pressed, with the bottom part 50 with its support surface 58 at the second end face 17 supported. For attaching the case body 21 on the housing 11 is according to 3 and 4 the housing body 21 for example, with two moldings 43 equipped with the fixing screws 16 at the first end face 12 of the housing 11 are attached.

The use of the damping device according to the invention 20 is not on the described application for a high-pressure pump 10 a fuel injection system limited. The damping device according to the invention 20 can also be applied to other functional elements of the fuel injection system, in which a flat housing body 21 on a housing 11 the functional unit can be attached.

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

• DE 10345725 A1 [0003]

Claims (10)

Pressure damping device ( 20 ) for a fluid pump ( 10 ), in particular for a high pressure pump of a fuel injection system with at least one damping element ( 30 ) stored in a fluid space ( 13 ), wherein the fluid pump ( 10 ) a housing ( 11 ), characterized in that a separate housing body ( 20 ) is provided, in which the fluid space ( 15 ) for receiving the at least one damping element ( 30 ) is formed, and that the separate housing body ( 20 ) on the housing ( 11 ) of the fluid pump ( 10 ) is attached. Pressure damping device ( 20 ) according to claim 1, characterized in that the separate housing body ( 20 ) two housing parts ( 21.1 and 21.2 ), that the two housing parts ( 21.1 . 21.2 ) each have a recess ( 22 . 26 ) for receiving the at least one damping element ( 30 ), and that the at least one damping element ( 30 ) by means of a biasing device between the two housing parts ( 21.1 . 21.2 ) is braced. Pressure damping device ( 20 ) according to claim 2, characterized in that at least one of the two housing parts ( 21.1 . 21.2 ) Support segments ( 35 . 48 . 54 ), on which the damping element ( 30 . 30.1 . 30.2 ) with a border ( 36 . 36.1 . 36.2 ) rests. Pressure damping device ( 20 ) according to claim 3, characterized in that between the support segments ( 35 . 48 . 54 ) Flow openings ( 38 . 56 ) are formed. Pressure damping device ( 20 ) according to claim 2, characterized in that the second housing part ( 21.2 ) one around the second recess ( 26 ) running peripheral edge ( 36 ) with undercuts ( 34 ) that between the undercuts ( 34 ) the support segments ( 35 ) and that the undercuts ( 34 ) the flow openings ( 38 ) on the second housing part ( 21.2 ) form. Pressure damping device ( 20 ) according to claim 5, characterized in that the second housing part ( 21.2 ) with a substantially flat bearing surface ( 28 ) on a first end face ( 11 ) of the fluid pump ( 10 ) rests. Pressure damping device ( 20 ) according to claim 2, characterized in that on the first housing part ( 21.1 ) a connecting piece ( 41 ) for the supply line ( 19 ) is formed. Pressure damping device ( 20 ) according to claim 2, characterized in that the second housing part ( 21.2 ) as a cylindrical bottom part ( 50 ), which is in the first cylindrical recess ( 22 ) of the first housing part ( 20.1 ) is hydraulically sealed. Pressure damping device ( 20 ) according to claim 8, characterized in that the cylindrical bottom part ( 50 ) a closed bearing surface ( 58 ), with which the bottom part ( 50 ) on a second end face ( 17 ) of the housing ( 11 ) is applied, and that the first housing part ( 21.1 ) at least two formations ( 43 ), with which the separate housing body ( 21 ) at a first end face ( 12 ) of the housing ( 11 ), wherein the two end faces ( 12 . 17 ) substantially at right angles to each other on the housing ( 11 ) are arranged. Pressure damping device ( 20 ) according to claim 9, characterized in that on a narrow side ( 44 ) of the housing body ( 21 ) a first connecting piece ( 41 ) for the supply line ( 19 ) is formed.

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