EP1726816A2 - Fuel injection system with ventilation device - Google Patents

Abstract

The fuel injection system has a fuel pump unit (1, 2) with a feed pump (1) and a high-pressure fuel pump (2). It also has a fuel filter (4) and a venting device (5) between the pump unit and the filter. The venting device is in the form of a path valve (5'). The path valve combines the venting function with measurement of the temperature of the fluid flow. For this purpose, the path valve includes a temperature sensor (6).

Description

The invention relates to a fuel injection system comprising a high-pressure fuel pump unit with a Kraftstoffvorförderpumpe and a high-pressure fuel pump, a fuel high-pressure pump unit upstream fuel filter, and a venting device, which is arranged between the high-pressure fuel pump unit and the fuel filter, wherein the venting device is designed as a directional control valve, and wherein in a first Position of the directional control valve, the output of the fuel filter is connected to the input of the high-pressure fuel pump unit and in which in a second position of the directional control valve, the output of the fuel filter is connected to a Endlüftungsaustritt the venting device.

A generic fuel injection system is already out of the DE 103 45 225.7 known. For venting the fuel system is arranged between a Kraftstoffvorförderpumpe and one, the Kraftstoffvorförderpumpe upstream, a fuel filter designed as a venting directional control valve. The directional control valve is designed such that in a first position, the output of the fuel filter is connected to the input of the fuel feed pump and in a second position, the output of the fuel filter is connected to a return line.

In modern common rail fuel injection systems, to determine the pressure control strategies, the feed temperature of the fuel must be detected near the pump inlet. For this purpose, usually a temperature sensor in the input area of Fuel feed pump used. For the arrangement of the temperature sensor to the fuel feed pump additional fasteners and holes on the pump housing or the supply line are required, which increase the structural design of the fuel injection system and thus the manufacturing cost.

Object of the present invention is therefore to provide a fuel injection system with a simple design, which can be safely and easily vented, and in which a simple measurement of the fluid temperature is feasible.

The object is solved by the independent claim 1.

Advantageous embodiments of the invention, which can be used individually or in combination with each other, are the subject of the dependent claims.

The invention is based on a generic fuel injection system comprising a high-pressure fuel pump unit with a Kraftstoffvorförderpumpe and a high-pressure fuel pump, a fuel high-pressure pump unit upstream fuel filter, and a venting device, which is arranged between the high-pressure fuel pump unit and the fuel filter, wherein the venting device is designed as a directional control valve, and wherein in a first position of the directional control valve, the output of the fuel filter is connected to the input of the high-pressure fuel pump unit and in which, in a second position of the directional control valve, the output of the fuel filter is connected to an end vent outlet of the venting device on that the directional control valve comprises a temperature sensor for detecting the fluid temperature. The ventilation function and the temperature measurement are thus combined in a single unit. Additional fixings or holes for mounting the temperature sensor are not required. As a result, the manufacturing costs are reduced and the installation of the system considerably simplified. In addition, the space requirement of the entire fuel injection system is reduced.

An advantageous embodiment of the invention provides that the directional control valve, which comprises a valve body and a valve tappet, wherein the valve stem rests in a closed valve position with a sealing surface against a valve seat formed on the sealing seat, is constructed such that the valve stem is formed as a sleeve and the temperature sensor is mounted in the sleeve. This arrangement results in a particularly space-optimized design of the directional control valve. At the same time, the temperature sensor assumes the function of the closing element of the directional control valve. The temperature sensor protrudes into the flow, resulting in a very accurate and rapidly responding to changing temperatures temperature measurement of the fluid.

A particularly advantageous embodiment of the invention provides that the temperature sensor is screwed into the sleeve. By screwing into the sleeve results in a particularly simple, inexpensive and quick installation of the temperature sensor. The temperature sensor is firmly connected to the sleeve and can not be solved during operation.

A further preferred embodiment of the invention provides that the sleeve essentially consists of a material that is thermally poorly conductive with respect to the temperature sensor. As a result, thermal repercussions of the directional valve are minimized to the temperature sensor, whereby a particularly accurate temperature measurement is possible.

A particularly preferred embodiment of the invention provides that the sleeve consists essentially of a plastic. The plastic is compared to the temperature sensor thermally poorly conductive and also inexpensive and easy to work. Here, a plastic is to be selected which is fuel-resistant and therefore suitable for use in fuel injection systems.

A further preferred embodiment of the invention provides that a control unit detects and evaluates the signals from the temperature sensor. The evaluated data may then be used to control or regulate the fuel injection system and to select a suitable pressure control strategy.

In summary, it can thus be stated that the fuel injection system according to the invention with a directional control valve, which includes a temperature sensor for detecting the fluid temperature, combines in a surprisingly simple manner the venting of the fuel injection system, as well as the detection of the fluid temperature in a structural unit. This results in a particularly space-optimized design.

Figur 1

eine Schnittdarstellung eines, in einem erfindungsgemäßen Kraftstoffeinspritzsystem verwendeten, Wegeventils;

Figur 2

einen Schaltplan eines Kraftstoffeinspritzsystem mit einem Wegeventil entsprechend Figur 1.

Exemplary embodiments and further advantages of the invention are explained below with reference to the drawings. It shows schematically:

FIG. 1

a sectional view of a directional valve used in a fuel injection system according to the invention;

FIG. 2

a circuit diagram of a fuel injection system with a directional control valve according to Figure 1.

Identical or functionally identical components are subsequently provided across the figures with the same reference numerals.

FIG. 1 shows a sectional view of a directional valve 5 'used in a fuel injection system according to the invention. The left side in Figure 1 shows the directional control valve 5 'in a first, hereinafter referred to as the closed position position. The right side in Figure 1 shows the directional control valve 5 'in a second, hereinafter referred to as the open position position.

The directional control valve 5 'comprises a valve body 51 with an inlet 54, a first outlet 55 and a second outlet, which is referred to below as the final ventilation outlet 56. The valve body 51 has a guide bore 511, in which a valve stem 52 is guided longitudinally movable. On the valve tappet 52, a valve plate 521 is formed with a sealing surface 522.

When the valve position is closed (see left side in FIG. 1), the fluid flows from the inlet 54 of the directional control valve 5 'to the first outlet 55. The end-vent outlet 56 is closed by the contact of the valve tappet 52 with the sealing surface 522 against a sealing seat 512 of the valve body 51. so that no fluid can escape through the Endlüftungsaustritt 56. The valve stem 52 is for this purpose, preferably by a valve spring 53, sealingly pressed against the valve body 51 formed on the sealing seat 512. This ensures that the Endlüftungsaustritt 56 is always closed in the rest position.

In the open valve position (see right side of Figure 1), the valve plate 521 is lifted with the sealing surface 522 from the sealing seat 512 of the valve body 51. As a result, the Endlüftungsaustritt 56 of the directional control valve 5 'is released and air and / or liquid can be removed from the fuel injection system. Depending on the design of the directional control valve 5 'while the first output 55 is completely or only partially closed.

The control of the directional control valve 5 'can be done manually or via an actuator, which is for example operated electromagnetically.

The directional control valve 5 'is preferably to be arranged spatially within the fuel system such that it sits above the fuel lines 9, 10 through which fluid flows. The air present in the fluid system, due to the lower density relative to the fuel, always flows at the top of the en and can be easily removed from the fluid system without large amounts of fuel flowing out of the fuel injection system via the Endlüftungsaustritt.

The valve stem 52 is formed as a sleeve 52 '. In the 52 ', a temperature sensor 6 is housed, which simultaneously assumes the function of the valve closure member. By accommodating the temperature sensor 6 in the valve stem 52 can easily two functions, namely the vent of the fuel injection system and the temperature measurement of the fluid are combined in one unit. This results in a very compact unit for temperature measurement and system ventilation.

For receiving the temperature sensor 6, the valve stem 52 designed as a sleeve 52 'preferably has an internal thread 523 and the temperature sensor 6 has a corresponding external thread 61. With appropriate selection of the internal thread 523 can be easily screw commercially available temperature sensors 6 in the sleeve 52 '. The valve plunger 52 designed as a sleeve 52 'essentially consists of a material which is thermally poorly conductive with respect to the temperature sensor 6. As a result, thermal repercussions between the temperature sensor 6 and the valve body 51 can be reduced to a minimum. As a material for the valve stem 52 in particular plastic is suitable. In addition to their poor thermal conductivity, plastics have the particular advantage that they are largely resistant to fuel, depending on the choice of plastic. They are also inexpensive and easy to work with.

The temperature sensor 6 is preferably connected to a control unit 7, which detects and evaluates the signals from the temperature sensor 6. The temperature values can then be used to define a pressure control strategy. Such a pressure control strategy is particularly common in fuel injection systems, especially in common rail injection systems.

FIG. 2 shows a circuit diagram of a fuel injection system with a directional control valve 5 'corresponding to FIG. The fuel injection system comprises a tank 8, in which an Intankpumpe 3 is arranged, which is preferably electrically controlled. The Intankpumpe 3 promotes the fuel located in the tank 8 via a first fuel line 9 to the input 41 of a fuel filter 4. The fuel filtered by the fuel filter 4 is further promoted via a second fuel line 10 to a Kraftstoffvorförderpumpe 1. Between the fuel feed pump 1 and the fuel filter 4 a correspondingly formed 1-way valve 5 'is arranged. The directional control valve 5 'is designed as a 3/2-way valve 5 "and serves for venting the fuel injection system. In its closed position, the 3/2-way valve 5" establishes a connection between the outlet 42 of the fuel filter 4 and the inlet 11 of the fuel feed pump 1 ago. In the open position, the 3/2-way valve 5 "blocks the fuel flow between the fuel filter 4 and the fuel feed pump 1 and establishes a connection between the outlet 42 of the fuel filter 4 and the exhaust vent 56. The final vent 56 carries the fuel / air mixture via a return line 18 back to the tank 8. Preferably, a viewing window 13 is mounted in or on the return line 18, with which you can visually determine whether there is still air in the return line 18.

In a cost-effective variant, the final vent outlet 56 projects freely into the engine compartment, so that after a few drops of fuel have emerged, the 3/2-way valve 5 "can be moved from the open to the closed position The exiting fuel droplets can be collected, for example, via a cup. The 3/2-way valve 5 '' can be operated manually or by an electric actuator.

The fuel feed pump 1 is connected via a further fuel line 17 with a high-pressure fuel pump 2 connected downstream thereof. Between the output 12 of the fuel feed pump 1 and the input 21 of the high-pressure fuel pump 2, a fuel metering device is provided, which preferably operates as a flow control valve 14 and serves to meter the fuel high-pressure pump 2 a defined amount of fuel. The high-pressure fuel pump 2 delivers fuel under high pressure via a fuel distributor 15 to the so-called common rail to the injectors 16, which are connected downstream of the fuel distributor 15, whereby fuel can be injected into an internal combustion engine.

On the fuel filter 4 is optionally a further venting device 43 with a vent line 44 vorsehbar, with the air in the fuel filter 4 and in the first fuel line 9 can be discharged. When fueling the tank 8, when changing the fuel filter 4 or other system components, air in the first fuel line 9 and in the second fuel line 10 can occur. The fuel feed pump 1 has only a limited ability to remove air from the fuel lines 9, 10 by promotion. As a result, in particular when starting the internal combustion engine, only delayed starting takes place or even starting of the internal combustion engine can be made impossible.

Bleeding the fuel system is easy. The basic principle for this purpose has already been explained in the description of FIG. The venting of the fuel injection system will therefore be explained below only briefly.
The pumps 1, 2, 3 are actuated, for example by actuating the starter of the internal combustion engine. The ventilation device 5 is actuated, ie brought into its open position, by pressing the button on the 3/2-way valve 5 "or by actuation via the actuator 13. Through the Intank pump 3, the fuel pushes the fuel filter 4 and the second fuel line via the first fuel line 9 10 air in front of it, which is excreted via the Endlüftungsaustritt 56 of the 3/2-way valve 5 "and the return line 18 in the direction of the tank 8. When the venting is completed, for example, by an empirical value, a predetermined time or visually through a viewing window 13 which is arranged in the return line 18 or at the final vent outlet 56 of the venting device 5, the 3/2-way valve 5 "is moved to its closed position ,
Due to the spatial proximity of the 3/2-way valve 5 '' for Kraftstoffvorförderpumpe 1 10 virtually no air is contained after the venting process in the second fuel line. A small amount of air can be contained between the 3/2-way valve 5 '' and the fuel feed pump 1, but since this volume is kept small, this small amount of air can be conveyed away quickly by the Kraftstoffvorförderpumpe 1. Preferably, the 3/2-way valve 5 "is arranged directly at the inlet 11 of the fuel feed pump 1. Alternatively, the 3/2-way valve 5 "is arranged closer to the inlet 11 of the fuel feed pump 1 than at the outlet 42 of the fuel filter 4. By pressing or pressing the 3/2-way valve 5 '' and simultaneously switching on the pumps 1, 2, 3 is thus advantageous, a simple and fast venting feasible.

Preferably, only the Intankpumpe 3 is operated simultaneously or in temporal correlation with the pressing or pressing the 3/2-way valve 5 ", ie without the Kraftstoffvorförderpumpe 1 or the high-pressure fuel pump 2 to operate. This has the advantage that the Intake pump 3, which is usually designed as an electric pump, can be switched on before starting the internal combustion engine, for example when the ignition is switched on or when the ignition key is turned on, in order to initiate the venting process. The high-pressure fuel pump 2 and the thus mechanically connected Kraftstoffvorförderpumpe 1 are often driven only by means of a rotation of the crankshaft, ie by means of a startup of the internal combustion engine. Thus, advantageously, a venting operation without starting process is possible. By trained as an actuator temperature sensor 6, the fluid temperature can be measured directly at the input 11 of the fuel feed pump 1. The temperature sensor 6 is preferably connected to a control unit 7 which detects and evaluates the fluid temperature. The values can then be used to select a pressure control strategy.

The fuel injection system according to the invention thus has in a particularly advantageous manner a directional control valve 5 ', which combines two functions, namely the venting of the fuel injection system and the temperature measurement of the fluid flow in a structural unit. This results in a structurally particularly simple, space-optimized, structure of the fuel injection system.

Claims (6)

Fuel injection system comprising: a high-pressure fuel pump unit (1, 2) with a fuel feed pump (1) and a high-pressure fuel pump (2), - One of the high-pressure fuel pump unit (1, 2) upstream of the fuel filter (4), and a venting device (5) arranged between the high-pressure fuel pump unit (1, 2) and the fuel filter (4), wherein the venting device (5) is designed as a directional control valve (5 '), and - In a first valve position of the directional control valve (5 '), the output (42) of the fuel filter (4) with the input (11) of the fuel feed pump (1) is connected, and - In a second valve position of the directional control valve (5 '), the output (42) of the fuel filter (4) is connected to a Endlüftungsaustritt (56), characterized in that
the directional control valve (5 ') comprises a temperature sensor (6) for detecting the fluid temperature. A fuel injection system according to claim 1, wherein the directional control valve (5 ') comprises a valve body (51) and a valve lifter (52), and wherein the valve lifter (52) seals in a closed valve position with a sealing surface (522) against a valve body (51). formed sealing seat (512),
characterized in that
the valve tappet (52) is designed as a sleeve (52 ') and the temperature sensor (6) is arranged in the sleeve (52'). Fuel injection system according to claim 1 or 2,
characterized in that
the temperature sensor (6) is screwed into the sleeve (52 '). Fuel injection system according to claim 2 or 3,
characterized in that
the sleeve (52 ') consists essentially of a relative to the temperature sensor (6) thermally poorly conductive material. Fuel injection system according to claim 4,
characterized in that
the sleeve (52 ') consists essentially of a plastic. Fuel injection system according to one of the preceding claims,
characterized in that
a control unit (7) detects and evaluates the signals from the temperature sensor (6).

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