EP1395744A1

EP1395744A1 - Fuel injection device for combustion motors, especially common rail injector, fuel system and internal combustion engine

Info

Publication number: EP1395744A1
Application number: EP02742681A
Authority: EP
Inventors: Friedrich Boecking
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2001-05-08
Filing date: 2002-04-18
Publication date: 2004-03-10
Anticipated expiration: 2022-04-18
Also published as: US20040025842A1; US6928985B2; JP2004519599A; EP1395744B1; WO2002090756A1; JP4130777B2; DE10122256A1; DE50206317D1

Abstract

The invention relates to a fuel injection device (10) used in internal combustion engines (94). Said device comprises a body (12) having an injection end (18). A recess (20) is formed in the body (12). An axially mobile valve element (24) which is located in the recess (20) co-operates with a valve seat and has, opposite the injection end (18), a pressure surface (36) which axially delimits a control chamber (38) which is itself radially delimited by a sleeve member (40). A device (55) prestresses the sleeve element (40) in a direction of a first body part (16) as well as the valve member (24) towards the injection end (18). The aim of the invention is to improve the operating precision of this fuel injecting device (10). For that purpose, the device (55) comprises separate prestress devices (46, 50) among which one pretress device (50) impinges upon the valve member (24) and another prestress device (46) impinges upon the sleeve member (40).

Description

Fuel injection device for internal combustion engines, in particular common rail injector, and fuel system and internal combustion engine

State of the art

The invention relates to a fuel injection device for internal combustion engines, in particular a common rail injector, with a housing with an injection end, with a recess running in the housing, with at least one axially movable valve element which is arranged in the recess, with a Valve seat cooperates and has a pressure surface facing away from the injection end, which axially delimits a control chamber, with a sleeve part, which delimits the control chamber radially, and with at least one device, which the sleeve part against a first housing section and the valve element in the direction of the injection End charged.

Such a fuel injection device is known from the market. It is a common rail injector. The control chamber is limited by an axial end face of a valve needle. The control chamber is radially delimited by a sleeve part, in the wall of which there is an inlet throttle. On the side opposite the valve needle, the control chamber is delimited by a housing part in which an outlet throttle is present. The inlet throttle is connected to a high pressure inlet, whereas the outlet throttle is connected to a low pressure area via a control valve. The throttling effect of the inlet throttle is stronger than that of the outlet throttle.

A compression spring is clamped between the sleeve part and an annular shoulder of the valve needle. Through this, on the one hand, the valve needle is urged against a valve seat in the region of the injection end, and on the other hand, the sleeve part is urged against the housing part. In order to lift the valve needle from its valve seat in the area of the injection end, the pressure in the control room is reduced. The normal high pressure is still present on a pressure surface of the valve needle. If the pressure difference is sufficient, the closing force of the compression spring is overcome so that the valve needle moves.

The object of the present invention is to develop a fuel injection device of the type mentioned at the outset in such a way that the fuel can be injected even more precisely with it.

This object is achieved in a fuel injection device of the type mentioned at the outset in that the device which prestresses the sleeve part against a first housing section and the valve element in the direction of the injection end comprises separate prestressing devices, one prestressing device in each case the valve element and another biasing device acts on the sleeve part.

Advantages of the invention

According to the invention, it was recognized that leaks between the sleeve part and the first housing section are equivalent to an enlarged cross section of the inlet throttle. If there is a leak between the sleeve part and the first housing section, the fuel can therefore flow into the control chamber faster than desired when the pressure drops in the control chamber, so that the pressure in the control chamber rises again too quickly. This leads to premature closing of the valve element. Such a leak between the sleeve part and the first housing section is avoided in the fuel injection device according to the invention.

This takes place in that the force with which the sleeve part is acted against the first housing section can be selected to be sufficiently high so that there is an optimal seal between the sleeve part and the first housing section. However, such a high contact pressure is only possible if separate pre-tensioning devices are provided for the sleeve part and for the valve element.

In order to be able to provide the pressing force necessary for the necessary sealing between the sleeve part and the first housing section, a very stiff spring is required. On the other hand, in order to be able to bring about an opening movement of the valve element even with a small pressure drop in the control chamber,

Biasing device, which acts on the valve element, be relatively soft. Such individual configurations of the corresponding pretensioning devices are possible in the fuel injection device according to the invention.

The fuel injection device according to the invention thus allows an optimal seal between the sleeve part and the first housing section in an extremely inexpensive and simple manner, which enables a precise and reproducible pressure curve in the control chamber. This in turn enables precise opening and closing the fuel injector.

Advantageous developments of the invention are specified in the subclaims.

In a first development it is mentioned that the pretensioning device, which acts on the sleeve part, is supported on a second and stationary housing section. With such a support, the forces necessary for a good seal between the sleeve part and the first housing section can be absorbed well.

The seal can also be improved in that the sleeve part has a circumferential sharp edge with which it rests on the first housing section.

Advantageously, there is an opening in the wall of the sleeve part, which forms an inlet flow restrictor for the control chamber. Such an inlet flow restrictor can be introduced into the sleeve part in a simple manner and with the highest precision.

Furthermore, it is possible for the pretensioning device, which acts on the sleeve part, to be supported on a shoulder of the recess in the housing. Since the recess in the housing in which the valve element is arranged is generally designed as a stepped bore anyway, such a shoulder can be provided without much additional effort.

An advantageous possibility for designing the prestressing device for the sleeve part is that the prestressing device comprises a disc spring with an opening through which the valve element extends. Such disc springs, which can optionally also be arranged as a spring assembly, have a very high rigidity. They can thus be used to achieve high contact forces between the sleeve part and the first housing section, which is advantageous for the desired sealing. In addition, such disc springs are very compact.

In a further development, at least one recess is present in the disc spring in the region of the radially outer edge. In this case, the space in which the disc spring is arranged can also be used for the flow guidance of the fuel. In this case, the fuel can flow through the recess.

Alternatively, the pretensioning device, which acts on the sleeve part, can comprise a spring sleeve. Such a spring sleeve generally has the shape of a cylinder and enables support in a location axially distant from the sleeve part.

It is preferred if there is at least one opening in the wall of the spring sleeve. In this case, the space in which the spring sleeve is arranged can also be used as a flow channel for the fuel. It is particularly preferred if there is an inlet flow restrictor in the wall of the spring sleeve. Such an opening with a specific cross section can be easily and inexpensively introduced into the spring sleeve without adversely affecting its rigidity or service life.

It is also possible that the pretensioning device, which acts on the sleeve part, comprises a spring element with a support section and at least two axially extending spring sections. Even with such a spring element, the support can be axially from the sleeve part done away. Since the spring element comprises individual spring sections, between which there are spaces, the flow through the space in which the spring element is arranged is not or only slightly impaired.

The invention also relates to a fuel system with a fuel injection device that injects the fuel directly into the combustion chamber of an internal combustion engine, with at least one high-pressure fuel pump, and with a fuel manifold to which the fuel injection device is connected.

In order to improve the precision of the injections carried out in such a fuel system, it is proposed that the fuel injection device be designed in the manner mentioned above.

The invention further relates to an internal combustion engine with at least one combustion chamber into which the fuel is injected directly.

In order to optimize the operation of this internal combustion engine with regard to fuel consumption and emissions, it is proposed that the internal combustion engine have a fuel system of the type mentioned above. Since this fuel system measures the fuel very precisely into the combustion chamber, emissions can be kept low and fuel consumption kept low.

drawing

Exemplary embodiments of the invention are explained in detail below with reference to the accompanying drawing. The drawing shows: 1: a partial longitudinal section through a first embodiment of a fuel injection device for internal combustion engines, with a pretensioning device for a sleeve part;

FIG. 2: a top view of the pretensioning device of FIG. 1;

3 shows a partial longitudinal section through a region of a second exemplary embodiment of a fuel injection device for internal combustion engines, with a prestressing device for a sleeve part;

Fig. 4 is a perspective view of the biasing device of Fig. 3;

5 shows a modification of the pretensioning device from FIG. 4;

6: a view similar to FIG. 1 of a third exemplary embodiment of a fuel injection device for internal combustion engines, with a prestressing device for a sleeve part;

FIG. 7 shows a perspective illustration of the pretensioning device from FIG. 6; FIG. and

8: a schematic representation of an internal combustion engine with a fuel system and a plurality of fuel injection devices corresponding to FIG. 1.

Description of the embodiments

In Fig. 1 carries a fuel injection device overall reference numeral 10. It is a common rail injector, which is used for the direct injection of highly compressed fuel into the combustion chamber of an internal combustion engine. The injector 10 comprises a multi-part housing 12. The housing 12 comprises a nozzle body 14 and an intermediate disk 16. The nozzle body 14 and the intermediate disk 16 are clamped against one another via a nozzle clamping nut (not shown in the drawing).

The lower end of the nozzle body 14 in FIG. 1 is designed as an injection end 18. A recess 20 runs in the longitudinal direction of the nozzle body 14. The recess has the shape of a stepped bore and ends in the injection end 18. At the injection end 18 there are several fuel outlet openings 22 arranged distributed over the circumference of the injection end 18. A valve element 24 is arranged in the recess 20 in the nozzle body 14. It is a valve needle which runs coaxially with the recess 20 and is axially movable. The valve needle 24 works together with a valve seat (without reference numerals) in the area of the injection end 18.

The valve needle 24 has several sections with different diameters: an oblique pressure surface 30 is present between a section 26 with a smaller diameter and a section 28 with a larger diameter. Above section 28 there is a section 32 which has a smaller diameter than section 28. Above section 32 in turn, valve needle 24 has an end section 34, the diameter of which is somewhat larger than that of section 32. End section 34 axially follows bounded above by a printing surface 36.

The pressure surface 36 in turn axially delimits a control chamber 38. Radially, the control chamber 38 is delimited by a sleeve part 40 which extends downward to approximately the level of the transition between the end section 34 and the section 32 of the valve needle 24. The end section 34 is tightly guided in the sleeve part 40. The upper edge of the sleeve part 40 has a conical bevel, so that a cutting-like biting edge 44 is formed, with which the sleeve part 40 rests on the intermediate disk 16. The intermediate disk 16 delimits the control chamber 38 upwards.

An intermediate disk 42 is arranged below the sleeve part 40, through the opening of which the section 32 of the valve needle 24 passes with some play. The washer is urged upwards by an annular disc spring 46. With its radially outer edge, the disc spring 46 is supported on a shoulder 48 of the recess 20. The section 32 of the valve needle 24 passes through a central opening 47 of the disc spring 46.

A helical compression spring 50 is in turn supported on the disk spring 46. The helical compression spring 50 is arranged coaxially with the valve needle 24. At the bottom, the helical compression spring 50 is supported on an annular collar 52 of a guide sleeve 54. The disc spring 46 and the helical compression spring 50 are part of one

Actuation device 55. The inner diameter of the guide sleeve 54 is slightly smaller than the outer diameter of the section 28 of the valve needle 24. The guide sleeve 54 is therefore supported on the shoulder formed between the section 28 and the section 32 of the valve needle 24.

Between the sleeve part 40, the intermediate disk 42 and the guide sleeve 54 on the one hand and the wall of the recess 20 in the nozzle body 14 on the other hand there is an annular space 56 available. This is connected to a high-pressure manifold 60 via a flow channel 58. In the wall of the sleeve part 40, a bore is made in the upper region thereof, which forms an inlet throttle 62.

In the intermediate disk 16 there is a through hole 64 in the radial center thereof, which has a section with a small diameter, which forms an outlet throttle 66. The diameter of the inlet throttle 62 is smaller than that of the outlet throttle 66. The control chamber 38 is connected to a switching valve 68 via the through bore 64 with the outlet throttle 66. On the outlet side, this is in turn connected to a low-pressure area (without reference numerals).

The annular space 56 is connected by axial channels in the nozzle body 14, which are introduced into the wall of the recess 20, with an annular pressure space 70, which is present in the recess 20 at the level of the pressure surface 30. A further annular space 72 leads from the pressure space 70, with the valve needle 24 open, to the fuel outlet openings 22. A number of semicircular recesses 74 are made in the outer edge of the disc spring 46, distributed over the circumference. This connects the area of the annular space 56 above the disk spring 46 to the area below the disk spring 46. For the formation of the recesses 74 in the disc spring 46, reference is made to FIG. 2.

The injector 10 shown in FIG. 1 operates as follows:

When the injector 10 is closed, the switching valve 68 is closed. In this case, the full system pressure prevails in the control chamber 38, which also exists in the high-pressure manifold 60, in the flow channel 58, in the inlet Throttle 62 and in the annular space 56 prevail. This pressure acts on the pressure surface 36 at the upper end of the valve needle 24. As a result and through the action of the helical compression spring 50, the valve needle 24 is pressed against the injection end 18 of the nozzle body 14. The fuel outlet openings 22 are thus separated from the annular space 72, so that no fuel can escape.

In order to carry out an injection with the injector 10, the switching valve 68 is opened. Since the diameter of the outlet throttle 66 is larger than that of the inlet throttle 62, more fuel flows out of the control chamber 38 to the low-pressure region than flows back through the inlet throttle 62. The pressure in the control chamber 38 thus falls. At the same time, the full system pressure is present in the pressure chamber 70 and acts on the pressure surface 30 on the valve needle 24. When the corresponding resultant force on the pressure surface 30, the closing force by the helical compression spring 50 and by the pressure surface 36 exceeds the outgoing force, the valve needle 14 lifts off the valve seat in the region of the injection end 18 and releases the fuel outlet openings 22.

In order to end an injection, the switching valve 68 is closed again. Fuel continues to flow into the control chamber 38 through the inlet throttle 62 until the same pressure prevails in the control chamber 38 as in the annular chamber 56 and at all other points within the injector 10. Due to the pressure on the pressure surface 36 of the valve needle 24 and due to the Force, which is exerted by the compression coil spring 50 on the valve needle 24, the valve needle 24 is again moved in the direction of the injection end 18 and the connection between the fuel outlet openings 22 and the annular space 72 is interrupted.

So that the closing time of the valve needle 24 is as possible corresponds exactly to the desired value, the pressure curve in the control chamber 38 also corresponds as exactly as possible to the desired curve. The desired course is in turn influenced by exact dimensioning of the inlet throttle 62 on the one hand and the outlet throttle 66 on the other hand.

In order to prevent fuel from the annular space 56 from entering the control space 38 through a gap between the sleeve part 40 and the intermediate disk 16 (this would correspond to a larger diameter of the inlet throttle 62), the disc spring 46 is designed to be very rigid. As a result, the biting edge 44 is pressed against the wall of the intermediate disk 16 with a very high contact force, which creates an optimal seal. At the same time, however, the helical compression spring 50 is so soft that the opening process of the valve needle 24 is not impaired.

3 shows a second exemplary embodiment of an injector 10. Parts which are functionally equivalent to parts which have already been described in connection with FIGS. 1 and 2 have the same reference numerals. It will not be discussed in detail again.

The main differences relate to the design of the pretensioning device, which acts on the sleeve part 40 against the intermediate disk 16. Instead of a disc spring, a spring sleeve 46 is provided in the injector shown in FIG. 3. This essentially consists of a hollow cylinder (cf. FIG. 4), in the wall of which elongated openings 74 are present in the azimuthal direction.

The upper edge of the spring sleeve 46 is supported on the Washer 42 from. The lower edge of the spring sleeve 46 is supported on a shoulder 76, which is formed between a region 78 of the recess 20 with a larger diameter and a region 80 of the recess 20 with a smaller diameter. Krafttoff can pass through the recesses 74 in the spring sleeve 46.

A variant of such a spring sleeve is shown in Fig. 5. This spring sleeve 46 has only a single opening in its wall, which forms an inlet throttle 62. Furthermore, in this spring sleeve 46 there are two relatively rigid sections 82 and 84, between which a spring section 86 designed in the form of an accordion is arranged.

6 shows a further exemplary embodiment of an injector 10. It also applies here that parts which have equivalent functions to parts which have been described in connection with FIGS. 1-5 have the same reference numerals and are not explained again in detail here.

In contrast to the injector 10 shown in FIG. 1, a spring element 46 is provided in the injector 10 shown in FIG. 6 instead of a disc spring. This has an annular support section 88, on which two axially extending spring sections 90 are formed. A semi-circular bulge 92 is bent into the spring sections 90 in the region of their lower end in FIG. 6, but somewhat spaced therefrom (cf. also FIG. 7), each forming a spiral spring.

An internal combustion engine 94 is shown schematically in FIG. 8. It comprises a fuel system 96. This in turn has a fuel tank 98, from which an electric low-pressure fuel pump 100 den Feeds fuel to a motor-driven high pressure pump 102. From there, the fuel reaches a fuel collecting line 104, which is also commonly referred to as a "rail". A plurality of injectors 10, which are designed in accordance with FIG. 1, FIG. 3 or FIG. 6, are connected to the fuel collecting line 104. The injectors 10 each inject the fuel (diesel or gasoline) directly into combustion chambers 106.

It should also be pointed out that the terms “above” and “below” in the above description refer exclusively to the figures. In principle, the device 10 can also be arranged in a different position than that shown in the figures.

Claims

Expectations

1. fuel injection device (10) for internal combustion engines (94), in particular common rail injector, with a housing (12) with an injection end (18), with a recess (20) running in the housing (12), with at least one axially movable valve element (24), which is arranged in the recess (20), with a

Valve seat cooperates and has a pressure surface (36) facing away from the injection end (18), which axially delimits a control chamber (38), with a sleeve part (40), which delimits the control chamber radially, and with at least one device (55), which the sleeve part (40) against a first housing section (16) and the valve element (24) in the direction of the injection end (18), characterized in that the device (55) comprises separate biasing devices (46, 50), each a biasing device (50) acts on the valve element (24) and another biasing device (46) on the sleeve part (40).

2. Fuel injection device (10) according to claim 1, characterized in that the biasing device

(46), which acts on the sleeve part (40), is supported on a second and stationary housing section (14).

3. Fuel injection device (10) according to one of the preceding claims, characterized in that the biasing device (46) which the sleeve part (40) acts on a shoulder (48) of the recess (20) in the housing (12).

4. Fuel injection device (10) according to one of claims 1 or 2, characterized in that the sleeve part (40) has a circumferential sharp edge (44) with which it rests on the first housing section (16).

5. Fuel injection device (10) according to one of the preceding claims, characterized in that in the wall of the sleeve part (40) there is an opening which has an inlet flow restrictor (62) for the control chamber

(38) forms.

6. Fuel injection device (10) according to one of the preceding claims, characterized in that the biasing device, which acts on the sleeve part (40), comprises a disc spring (46) with an opening through which the valve element (24) extends.

7. Fuel injection device (10) according to claim 6, characterized in that in the disc spring (46) in the region of the radially outer edge at least one recess (74) is present.

8. Fuel injection device (10) according to one of claims 1 to 5, characterized in that the biasing device which acts on the sleeve part (40) comprises a spring sleeve (46).

9. Fuel injection device (10) according to claim 8, characterized in that in the wall of the spring sleeve

(46) at least one opening (74) is present.

10. Fuel injection device (10) according to claim 8, characterized in that an inlet flow restrictor (62) is present in the wall of the spring sleeve (46).

11. Fuel injection device (10) according to one of claims 1 to 5, characterized in that the biasing device, which acts on the sleeve part (40), a spring element (46) with a support section (88) and at least two axially extending spring sections ( 90).

12. Fuel system (96) with a fuel tank (98), with at least one fuel injection device (10) which injects the fuel directly into the combustion chamber (106) of an internal combustion engine (94), with at least one high-pressure fuel pump (102), and with one

Fuel manifold (104) to which the fuel injection device (10) is connected, characterized in that the fuel injection device (10) is designed according to one of claims 1 to 11.

13. Internal combustion engine (94) with at least one combustion chamber (106) into which the fuel is injected directly, characterized in that it has a fuel system (96) according to claim 12.