EP3430261A1

EP3430261A1 - High-pressure pump having a fluid damper

Info

Publication number: EP3430261A1
Application number: EP17701506.2A
Authority: EP
Inventors: Daniel Keilbach
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2016-03-14
Filing date: 2017-01-26
Publication date: 2019-01-23
Anticipated expiration: 2037-01-26
Also published as: CN108779766A; WO2017157554A1; CN108779766B; DE102016204128A1; KR20180121982A; EP3430261B1

Abstract

The invention relates to a high-pressure pump, having a pump housing (2), on which a pump cylinder head (4) having a a pump cylinder (3) is arranged, wherein a pump push rod (26) is arranged in a pump cylinder guide (27) of the pump cylinder (3), which pump push rod interacts with a pump working chamber (36) and with a drive unit compartment (8) arranged in the pump housing (2), and wherein the pump working chamber (36) is fluidically connected to the drive unit chamber (8) by means of an electromagnetically actuatable suction valve (6) and the high-pressure pump has a fluid damper. According to the invention, a high-pressure pump is provided which is improved with respect to damping of the pressure fluctuations or pressure pulsations of a fluid to be conveyed. This is achieved in that the fluid damper is designed as at least one membrane (38a, 38b), which is inserted into a damper chamber (19) recessed into the pump housing (2).

Description

description

Title:

HIGH PRESSURE PUMP WITH A FLUID DAMPER

The invention relates to a high-pressure pump, comprising a pump housing, on which a pump cylinder head having a pump cylinder head is arranged, wherein in a pump cylinder guide of the pump cylinder a

Pump plunger is arranged, which is provided with a fluidbefüllbaren pump working space and arranged in the pump housing fluidbefüllbaren

Engine room cooperates, and wherein the pump work chamber via an electromagnetically actuated suction valve with the engine room

is fluid-connectable and the fluid guide of the high-pressure pump has a fluid damper.

State of the art

Such a high pressure pump is known from DE 10 2013 207 393 AI. This high pressure pump is part of a fuel injection system of

Internal combustion engine. This high-pressure pump has a pump housing, on which a pump cylinder head having a pump cylinder head is arranged, wherein in a pump cylinder guide of the pump cylinder a

Pump plunger is arranged to promote the fuel. For this purpose, a pump working space is arranged adjacent to the pump cylinder guide to which an electromagnetically actuated suction valve from an engine room of the high-pressure pump fuel is supplied. Furthermore, the high-pressure pump to a fluid damper outside of the high-pressure pump to the

Pump housing is arranged in the region of a feed for fuel. The fluid damper is installed in a housing shell, the outside of the

Pump housing is attached. The invention has for its object to provide a high-pressure pump, which is improved in terms of damping of pressure fluctuations or pressure pulsations of the fluid to be delivered.

Disclosure of the invention

This object is achieved in that the fluid damper in a in the

Pump housing recessed damper chamber is inserted. This

Design is based initially on the knowledge that

Pressure fluctuations or pressure pulsations in the region of the high pressure pump can lead to cavitation and / or a lubricant film break between components of the high pressure pump. In addition, oscillations may occur in the area of a periphery interacting with the high-pressure pump, in particular fluid lines with components installed thereon, which cause noise. In the worst case, the lines or components installed therein, such as filters, can be damaged or destroyed. The previously known and practiced cultivation of a fluid damper in a supply line to the high-pressure pump or outside of the high-pressure pump is a high construction cost, which can also be prone to failure. In addition, for example, by an external attachment of the fluid damper on the

High-pressure pump increases their space requirements. These disadvantages described above are provided by the inventively provided installation of the

Fluid damper in a damper chamber, which is integrated into the pump housing, avoided.

In a further development of the invention, the fluid damper is a membrane. This membrane is annular or cylindrical in shape and has two opposite annular end faces, which has an inner

Include diaphragm chamber and are movable against each other. Such a membrane is basically known and can be made for example of a metallic material. The diaphragm chamber is thus formed between the two opposite end faces and filled for example with a gas. In development of the invention, the membrane is acted upon on both sides by the pressure prevailing in the damper chamber fluid pressure. As a result, an ideal working of the membrane is made possible by the pressure curves are synchronous on both sides of the membrane. In other words, the pressure profiles of the medium on both sides of the membrane or their membrane surfaces are the same and pi (t) = P2 (t). Due to the inventive installation of the membrane and the supply of the fluid fuel through an inlet channel below the membrane, the end faces in the longitudinal direction

or pressurized parallel to the end faces. This positively influences the function and durability of the membrane.

In a further embodiment of the invention, a feed connection opens directly or via a feed channel into the engine room and the damper chamber directly connected thereto. By this configuration, the mounting position of the fluid damper or the membrane at the origin of the

Pressure fluctuations or pressure pulsations as close as possible assigned.

In a further embodiment of the invention, at least two membranes are arranged in the damper chamber. This configuration can be easily realized by the damper chamber embedded in the pump housing, wherein the arrangement with respect to the inlet connection - as stated - is oriented so that the membrane is arranged longitudinally to the Pulsationsausbreitungsrichtung and not transverse to it as before. This reduces the load on the membrane. Consequently, the life of the diaphragm thus installed is increased, whereby the life of the high-pressure pump or a maintenance interval of the high pressure pump is increased or extended.

In a further embodiment of the invention, the damper chamber between the engine room and a plunger space connection or the

Plunger space arranged below the pump cylinder head. As a result, attenuation takes place directly at the two main pulsation sources, which are triggered by the high-pressure pump. Furthermore, the damper chamber is arranged directly next to an inlet connection and a return connection. This has a positive effect on the inlet and return of the fluid in terms of attenuation of these registered pulsations.

In a further embodiment of the invention, the at least one membrane can be inserted into a membrane holder, which can be installed in the damper chamber. This is a preferred embodiment which allows easy mounting of the at least one diaphragm in the damper chamber. It is also possible to install for different applications differently shaped membranes in an always same design damper chamber to a high-pressure pump.

In a further embodiment of the invention, the damper chamber on a coverable from a chamber cover mounting opening. This mounting hole is arranged on the high-pressure pump, that this is accessible even with a fully equipped with attachments high-pressure pump. As a result, without disassembly of the high pressure pump, the damper chamber can be achieved. The chamber lid can be screwed to the pump housing with the insertion of a sealing ring, for example.

In an advantageous further embodiment of the invention is the

Engine room connected to the damper chamber and both are connected via connecting channels with a plunger space below the pump cylinder head. This embodiment is structurally and manufacturing technology low feasible and also offers the advantage that by the direct

Aneinanderbindung the components advantages in terms of damping pressure fluctuations or pressure pulsations of the fluid to be delivered can be achieved.

In a further embodiment of the invention, designed as a high-pressure fuel pump high-pressure pump is part of a fuel injection system

Internal combustion engine, wherein the fuel injection system is designed for example as a common-rail fuel injection system and for injecting fuel, for example, diesel fuel or gasoline is formed in a combustion chamber of the internal combustion engine. Further advantageous embodiments of the invention are the

Drawing description can be found in which an illustrated in the figures embodiment of the invention is described in detail.

Show it:

Figure 1 is an overall perspective view of an inventive

trained high pressure pump,

FIG. 2 shows a cross section through a high-pressure pump according to FIG. 1,

3 shows a longitudinal section through an inventively designed

High-pressure pump according to Figure 1,

FIG. 4 shows a perspective view of a high-pressure pump similar to FIG. 1 with an exploded view of the components of a fluid damping device,

Figure 5 is a sectional view of a pump housing a

High-pressure pump according to Figure 1,

Figure 6a is a representation of a hitherto practiced pressurization of a membrane and

Figure 6b realized by the inventive design

Pressurization of a membrane.

Figure 1 shows a perspective view of a high-pressure pump, which is designed as a high-pressure fuel pump 1 of a fuel injection system. The fuel injection system is installed on an internal combustion engine and the high-pressure fuel pump delivers fuel supplied from a low-pressure fuel system with a delivery pressure of, for example, up to 3,000 bar into a high-pressure accumulator connected to the high-pressure fuel pump 1 via a high-pressure line, from which the fuel stored there is allocated by fuel injectors for controlled injection Combustion chambers of Internal combustion engine is removed. The fuel is for example

Diesel fuel and the internal combustion engine a self-igniting

Internal combustion engine. The high-pressure fuel pump has a pump housing 2, on which a pump cylinder head 4 having a pump cylinder 3 (see also FIG. 2) is mounted. The pump cylinder head 4 has a high pressure port 5 for connection to the high pressure line. Furthermore, in the

Pump cylinder head 4 built an electrically operated suction valve 6, which will be discussed below with reference to Figure 2. The

Suction valve 6 has a connector 7 for electrical connection to an electronic control device.

In the pump housing 2 an apparent from Figure 2 engine compartment 8 is recessed in which a double cam 9 having camshaft 10 is rotatably mounted. For installation of the camshaft 10 in the pump housing 2, the engine compartment 8 is closed by a pump housing cover 11 to the surroundings, through which a drive cone 12 of the camshaft 10 protrudes. On the drive cone 12, for example, a drive gear is rotatably mounted, which is offset by a drive shaft, for example, the internal combustion engine when operating the same in a rotary motion. The

Pump housing 2 further has an inlet port 13 and a

Return port 14 on. The inlet connection 13 is connected, for example via a pressure-resistant inlet hose with the fuel low-pressure system, while the return port 14 is connected via a return hose, for example, with a fuel tank. Side especially in addition to the

Inlet port 13 and also the return port 14 is a chamber lid 15 with the insertion of a sealing ring 16 (Figure 2) screwed for example by means of three screws 17. The chamber lid 15 closes a mounting opening 18, also explained below, of a damper chamber 19.

FIG. 2 shows a longitudinal section through the high-pressure fuel pump 1 according to FIG. 1, it being apparent from this illustration that the pump cylinder 3 of the pump cylinder head 4 projects into a plunger space 20 in the pump housing 2. In the cylindrically shaped plunger space 20 is a Roller tappet 21 used with a roller 22 on the in the

Engine room 8 arranged double cam 9 of the camshaft 10 rolls during a rotational movement of the camshaft 10 and thus the roller tappet 21 in the plunger space 20 translationally moves up and down. So that the roller tappet 21 with the roller 22 is in permanent contact with the double cam 9 of the camshaft 10, a tappet spring 23 is arranged in the tappet space 20, which is clamped between the pump cylinder head 4 and a retaining disk 24 which is arranged within the roller tappet 21 , The holding disc 24 rests on an inner ring contact surface 25 of the roller tappet 21 and at the same time holds a pump tappet 26, which is translationally movable in a pump cylinder guide 27 embedded in the pump cylinder 3, with a

Pump plunger foot 28 against a roller holder 29 of the roller tappet 21st

The inlet connection 13 (see also FIG. 3) is connected to the engine compartment 8 via an inlet channel 30 (see also FIG. 5). The engine room 8 is in turn connected to the damper chamber 19 and both are over

Connecting channels 31 a, 31 b with the plunger space 20 below the

Pump cylinder head 4 connected. The connecting channel 31a has an extension 32 (FIG. 2), which opens into a contact surface 33 of the pump housing 2 for fitting the pump cylinder head 4. The extension 32 continues in a feed channel 34, which is embedded in the pump cylinder head 4 and communicates with the solenoid-operated suction valve 6. The solenoid-operated suction valve 6 has an actuated by this inlet valve 35 which connects the feed channel 34 in the open state with a pump chamber 36, which is arranged in extension of the pump cylinder guide 27 above the pump plunger 26 in the pump cylinder head 4. Consequently, when the inlet valve 35 is open at a

Downward movement of the pump plunger 26 introduced via the inlet port 13 fuel supplied into the pump chamber 36 and pushed back in a subsequent upward movement of the pump plunger 26 in the same way with the inlet valve open 35 back into the low-pressure fuel system. Then, when the inlet valve 35 is closed by a switching operation of the solenoid-operated suction valve 6, a pressure builds up in the pump working space 36 and the fuel in the pump working chamber 36 is supplied via a check valve 37 in the High pressure connection 5 promoted. In Figure 5, a return passage 43 is further shown, which is connected to the return port 14 and, for example, arranged in the pump housing 2 and the pump housing cover 11 bearings for supporting the camshaft 10 for cooling and

Lubrication passed back fuel into the fuel

Low pressure system or the tank leads back.

By the previously described intended function of

High-pressure fuel pump 1 and also caused by the

Low-pressure fuel system arise in the high-pressure fuel pump 1 pressure pulsations, which are to be damped. For this purpose, a fluid damping device is installed in the damper chamber 19, which will be explained with reference to Figures 2, 3 and 4 below. The fluid damping device has in the illustrated embodiment, two membranes 38a, 38b, which are inserted with insertion of a diaphragm spring 39, which is made for example of spring steel, in a preferably designed as a stamped bent part membrane holder 40. The pre-assembled membrane holder 40 is shown in Figure 4 via the mounting hole 18 inserted into the damper chamber 19 and then the chamber lid 15 is bolted by means of screws 17 with the pump housing 2 with the insertion of the sealing ring 16. The

Membranes 38a, 38b are annular or cylindrical in shape and have an inner membrane chamber 41 which is filled with medium, for example, with a compressible gas filled. Acts on the two opposite annular end faces 42 of the two membranes 38 a, 38 b each have a force, the two end faces 42 are deformed inwardly into the diaphragm chamber 41. This effect is used for damping the prevailing in the high-pressure fuel pump 1 pressure fluctuations or pressure pulsations. By the above-described installation of the membranes 38a, 38b and the supply of fuel through the inlet channel 30 below the membranes 38a, 38b these are pressurized as shown in Figure 6b in the longitudinal direction (parallel to the end faces 42) and not as in a conventional membrane in Transverse direction (frontally on an end face 42), as shown in Figure 6a.

Claims

claims

1. High-pressure pump, comprising a pump housing (2) on which a pump cylinder (3) exhibiting pump cylinder head (4) is arranged, wherein in a pump cylinder guide (27) of the pump cylinder (3) a pump plunger (26) is arranged, with a Pump working space (36) and one in the pump housing (2) arranged engine compartment (8) cooperates, and wherein the pump working chamber (36) via an electromagnetically actuated suction valve (6) with the engine compartment (8) is fluid-connectable and the high pressure pump has a fluid damper, characterized characterized in that the fluid damper in one in the

Pump housing (2) recessed damper chamber (19) is inserted.

2. High-pressure pump according to claim 1,

characterized in that the fluid damper is at least one diaphragm (38a, 38b).

3. High-pressure pump according to claim 2,

characterized in that the membrane (38a, 38b) comprises an inner medium-filled membrane chamber (41).

4. High-pressure pump according to claim 2 or 3,

characterized in that the membrane (38a, 38b) is pressurized on both sides of in the damper chamber (19) prevailing fluid pressure.

5. High-pressure pump according to claim 4,

characterized in that the membrane (38a, 38b) is pressurized parallel to its opposite end faces 42). High-pressure pump according to one of claims 2 to 5,

characterized in that an inflow port (13) for supplying, one of the high pressure pump to be conveyed medium in the

Engine room (8) and merges into it damper chamber (19) opens.

High-pressure pump according to one of claims 2 to 6,

characterized in that at least two membranes (38a, 38b) are inserted parallel to each other in the damper chamber (19).

High-pressure pump according to one of claims 2 to 7,

characterized in that the membrane (38a, 38b) in a

Membrane holder (40) is inserted, which is insertable into the damper chamber (19).

High-pressure pump according to one of the preceding claims,

characterized in that the damper chamber (19) has a

Chamber cover (15) coverable mounting opening (18).

10. High-pressure pump according to one of the preceding claims,

characterized in that the engine room (8) with the

Damper chamber (19) connected and both via connection channels (31a, 31b) with a plunger space (20) below the pump cylinder head (4) are connected.

11. Fuel injection system with a high-pressure fuel pump (1)

formed high-pressure pump according to one of the preceding claims.