EP1558843A1

EP1558843A1 - Fuel injection system for internal combustion engines

Info

Publication number: EP1558843A1
Application number: EP03809690A
Authority: EP
Inventors: Hans-Christoph Magel
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2002-10-25
Filing date: 2003-06-30
Publication date: 2005-08-03
Anticipated expiration: 2023-06-30
Also published as: JP2006504040A; DE10249840A1; US7461795B2; ES2320540T3; US20060049284A1; DE50311251D1; EP1558843B1; WO2004040117A1

Abstract

The invention relates to a fuel injection system for internal combustion engines comprising a fuel injection nozzle (2), which can be supplied with fuel by a fuel high-pressure source (1). Said fuel injection nozzle comprises: a moving nozzle plunger (3) for opening and closing injection openings; an injection nozzle high-pressure space (21), and; an injection nozzle control space (20). A pressure intensifying device (7) is connected between the fuel injection nozzle (2) and the fuel high-pressure source (1). Said pressure intensifying device has a moving pressure intensifier plunger (8), a pressure intensifier working space (11), a pressure intensifier control space (12), and a pressure intensifier high-pressure space (9). A filling connection (10), which is open when the fuel injection nozzle (2) is closed and which serves to fill the pressure intensifier high-pressure space (9), is closed by the nozzle plunger (3) when the fuel injection nozzle (2) is open.

Description

Fuel injection device for internal combustion engines

Technical field

The common rail injection system is used to inject fuel into direct-injection internal combustion engines. In this accumulator injection system, pressure generation and injection are decoupled from one another in time and place. A separate high-pressure pump generates the injection pressure in a central high-pressure fuel reservoir. The start of injection and the injection quantity are determined by the triggering time and duration of, for example, electrically operated injectors, which are connected to the high-pressure fuel reservoir via fuel lines. It is advantageous in the common rail injection system that the injection pressure is adapted to the load and speed. The fuel injection is carried out with the greatest possible injection pressure. A high injection pressure has e.g. B. the advantages of reduced pollutant emissions, reduced fuel consumption and high specific performance. The maximum injection pressures in common rail systems are limited to approx. 1800 bar by the high pressure resistance of pressure accumulators (rails) and high pressure pumps. A pressure booster in the injector can be used to further increase the injection pressure. The pressure intensifier converts a primary pressure made available by the pressure accumulator into the desired high injection pressure by means of a hydraulic transmission.

State of the art

From DE 4311627 AI a fuel injection device for pulp engines is known, in which the injection valves have a pressure booster to increase the injection pressure up to 2000 bar. As a result of the stroke movement of an booster piston, the fuel pressure in an injection pressure chamber increases to a multiple of the high pressure applied. After the injection of fuel from the injection pressure chamber into a combustion chamber, the pressure in the injection pressure chamber drops due to the resetting of the Intensifier piston. This opens a check valve so that fuel can flow into the injection pressure chamber with the high pressure applied (refill). However, the integration of such a check valve in a fuel injection device means a considerable manufacturing outlay. It is difficult to accommodate the check valve in the existing installation space.

Presentation of the invention

The fuel injection device according to the invention avoids the disadvantages occurring in the prior art and makes it possible to ensure that the pressure booster is refilled with a reduced manufacturing outlay. It is advantageously no longer necessary to accommodate a check valve for this purpose in the fuel injection device according to the invention.

These advantages are achieved according to the invention by a fuel injection device for internal combustion engines with a fuel injection nozzle which can be supplied with fuel by a high-pressure fuel source and which has a movable nozzle piston for opening and closing injection openings, an injection nozzle high-pressure chamber and an injection nozzle control chamber, with between the fuel injection nozzle and the Ki-aftstoff high-pressure source is connected to a pressure booster device which has a movable pressure booster piston, a pressure booster work chamber and a high pressure booster chamber, one open when the fuel injector is closed to fill the pressure booster high pressure chamber Filling connection is closed when the fuel injector is open.

The closing of the filling connection which is open when infested is coupled to the movement of the nozzle piston in the opening direction in order to release the injection openings.

In a preferred embodiment of the present invention, the filler connection is closed by the nozzle piston when the fuel injection nozzle is open.

Because, for example, the nozzle piston closes the filler connection when the fuel injection nozzle is open during fuel injection and releases it again after the fuel injection when the fuel injection nozzle is closed, there is no non-return valve for filling the pressure intensifier space when the pressure intensifier piston is reset needed. In the fuel injection device according to the invention, a pressure change in a pressure booster control chamber contained in the pressure booster device and / or in the pressure booster work chamber preferably causes a pressure change in the pressure booster high-pressure chamber. During its fuel injection, the pressure intensifier Koiben compresses the fuel in the pressure intensifier high-pressure chamber to an injection high pressure which is higher than the high-pressure fuel in the high-pressure fuel source. When the fuel injection nozzle is open, fuel is injected under high injection pressure through the injection openings into the combustion chamber of the internal combustion engine.

In a preferred embodiment of the present invention, the opening and closing of the injection openings can be controlled via a control valve. It is preferably a 3/2 valve. The control valve can e.g. B. in a pressure-controlled fuel injector, the opening and closing of the injection openings by activating the pressure booster device.

drawing

The invention is explained in more detail below with the aid of the drawing.

It shows:

FIG. 1 shows a hydraulic circuit diagram of a fuel injection device according to the invention in the idle state or when resetting,

FIG. 2 shows a hydraulic circuit diagram of a fuel injection device according to the invention during injection,

Figure 3 shows a fuel injection device according to the invention in a coaxial design and

Figure 4 shows another embodiment of a fuel injection device according to the invention in the idle state or when infected.

variants

Figure 1 shows a hydraulic circuit diagram of a fuel injection device according to the invention, which is in the idle state or when resetting. The system comprises a high-pressure fuel source 1, for example a pressure accumulator (common rail), which stores fuel compressed to up to 1600 bar by a high-pressure pump. From the high-pressure fuel source 1, the fuel is conducted via a high-pressure line 27 to the injectors, each of which contains a control valve 14, a pressure booster device 7 and a fuel injection nozzle 2.

The control valve 14 is a 3/2 valve in this preferred embodiment of the present invention. In FIG. 1, the control valve 14 is in a first switch position 15, in which the high-pressure line 27 to a pressure intensifier control chamber 12 of the pressure intensification device 7 is open and a low-pressure line 17 leading to a low-pressure system, not shown, is closed. In the second switching position 16 (not shown in FIG. 1), the control valve 14 closes the connection between the high pressure line 27 and the pressure booster control chamber 12 and establishes a connection between the pressure booster control chamber 12 and the low pressure line 17. The control valve 14 may e.g. B. Piezo or a solenoid valve. By using a fast-switching piezo valve as a control valve, small injection quantities can be injected into the combustion chamber 25 of the internal combustion engine in a defined manner and with small quantity tolerances even at high nozzle opening pressure. Furthermore, there is little leakage loss due to the fast switching process. Furthermore, the control valve 14 can be designed as a directly controlled valve or as a servo valve.

The pressure booster device 7 contains a pressure booster piston 8 which is resiliently mounted by means of a return spring 13. The pressure intensifier piston 8 separates a pressure intensifier high pressure chamber 9 from a pressure intensifier work chamber 11, which is connected to the fuel high pressure source via the high pressure line 27. The return spring 13 used to mount the pressure intensifier piston 8 is arranged in the pressure intensifier control chamber 12. The pressure booster piston 8 can be divided into two areas, a first (larger diameter) pressure booster piston section 18 and a second (smaller diameter) pressure booster piston section 19. The two pressure booster piston sections 18, 19 are separate components, but can also be firmly connected to one another or be designed as a single component. The housing 28 of the pressure booster device 7 has a step-shaped taper. The first pressure booster piston section 18 of the pressure booster piston 8, which is displaceably arranged in the housing 28, divides the interior of the pressure booster device 7 into two areas which are separated from one another in a liquid-tight manner except for leakage losses. One area is the pressure intensifier work space 11 connected to the high-pressure fuel source 1 via the high-pressure line 27, the second The area has the above-mentioned step-shaped taper into which the second pressure booster piston section 19 protrudes. As a result, the tapered region is delimited in a liquid-tight manner from the rest of the second region, so that a pressure intensifier control chamber 12 and a pressure intensifier high-pressure chamber 9 are formed. The pressure intensifier work chamber 11 is connected to the high-pressure fuel source 1 via the high-pressure line 27. The pressure intensifier control chamber 12 can be connected via the control valve 14 either to the high-pressure fuel source 1 (first switching position 15) or to the low-pressure line 17 (second switching position 16). The pressure intensifier high-pressure chamber 9 is connected via an injection high-pressure line 29 to an injector high-pressure chamber 21 of the fuel injector 2 and can be connected to an injector control chamber 20 contained in the fuel injector 2 via a filler connection 10. In this preferred embodiment of the present invention, the filling connection 10 is arranged between the pressure intensifier high pressure chamber 9 and the injection nozzle control chamber 20. The filling connection 10 preferably contains a throttle 23.

The fuel injection nozzle 2 comprises a nozzle piston 3 and projects with its injection openings 6 into the combustion chamber 25 of a cylinder of an internal combustion engine. The nozzle piston 3 can be divided into two areas, the upper (larger diameter) nozzle piston section 4 and the (smaller diameter) nozzle needle 5, the upper nozzle piston section 4 passing into the nozzle needle 5 via a pressure shoulder 30. In the area of the pressure shoulder 30, the nozzle piston 3 is surrounded by the injection nozzle high-pressure chamber 21.

In the idle state (FIG. 1), the control valve 14 is not activated (first switching position 15) and there is no injection. In this preferred embodiment of the present invention, when the fuel injector 2 is closed, the high pressure booster chamber 9 is connected to the high pressure fuel source 1 via the control valve 14 (in a first switching position 15), the pressure booster control chamber 12, the injector chamber 20 and the filler connection 10 , The high pressure of the high-pressure fuel source 1 is then present at the following locations:

In the flap pressure line 27,

In the pressure intensifier work space 11,

• via the high-pressure connection line 31 on the control valve 14, • via the first connection line 32 in the pressure intensifier control chamber 12,

Via the second connecting line 33 in the injector control chamber 20,

• Via the filler connection 10 in the DCL high pressure chamber 9 and

• via the high-pressure injection line 29 in the high-pressure injector space 21. Thus, in the idle state, all pressure chambers (11, 12, 9) of the pressure intensifier 7 are pressurized with high pressure and the pressure intensifier piston 8 is pressure-balanced. The pressure translation device 7 is deactivated and there is no pressure boosting. The pressure intensifier piston 8 is held in its initial position via the return spring 13. The high pressure in the injector control chamber 20 applies a hydraulic closing force to the nozzle piston 3, which keeps the fuel injector 2 closed together with the closing force of the closing spring 24. These two forces together are greater than the hydraulic force acting in the opening direction on the nozzle piston 3 in the injector high-pressure chamber 21, so that the injection openings 6 remain closed by the nozzle needle 50 despite the high pressure constantly present in the injector high-pressure chamber 1. There is consequently no injection.

FIG. 2 shows a hydraulic circuit diagram of a fuel injection device according to the invention during the injection.

The structure of the fuel injection device shown in FIG. 2 corresponds to that in FIG. 1. The injection of fuel into the combustion chamber 25 is initiated by activating the 3/2-way control valve 14. It is switched from the first switching position 15 (connection Pressure intensifier control chamber 12 is switched to the second switching position 16 via the first connecting line 32, high-pressure connecting line 31 and high-pressure line 27 with the high-pressure fuel source 1). In the second switching position 16, the pressure intensifier control chamber 12 is connected to the low pressure line 17. The pressure intensifier control chamber 12 is thus relieved of pressure, whereby the pressure intensifier device 7 is activated. At the same time, the injector control chamber 20 is relieved of pressure.

In the preferred embodiment of the present invention shown in FIG. 2, the high-pressure fuel source 1 (also during the injection) is connected via a high-pressure line 27 to the pressure intensifier work space contained in the pressure-translation device 7. In the pressure intensifier work chamber 11, the high pressure from the fuel high pressure source 1 acts in the compression direction 36 on the large piston surface 35 of the first pressure intensifier piston partial region 18. Contrary to the compression direction 36, only the low pressure in the pressure intensifier control chamber 12, the force of the return spring 13 and that acts High pressure in the pressure intensifier high-pressure chamber 9, which, however, only acts on the small piston surface 37. The force in the compression direction 36 predominates. The pressure booster piston 8 therefore moves in the compression direction 36 in the housing 28 of the pressure booster device 7 and compresses the fuel in the Pressure intensifier high-pressure chamber 9 and thus also increases the pressure in the injector high-pressure chamber 21. Due to the pressure difference between the injector high-pressure chamber 21 and the injector control chamber 20, the nozzle piston 3 moves in the opening direction against the closing force of the closing spring 24 and gives the injection openings 6 free. Fuel 34 is now injected into the combustion chamber 25 at a pressure which is higher than the pressure in the high-pressure fuel source 1 by the pressure-translation device 7.

When the fuel injector 2 is open, the filler connection 10 between the injector control chamber 20 and the high pressure chamber 9 is closed by the nozzle piston 3. One end of the nozzle piston 3 interacts with the sealing seat 26. Consequently, no loss can escape from the pressure intensifier high-pressure chamber 9 via the throttle 23 contained in the filling connection 10 during the injection.

As long as the pressure intensifier control chamber 12 is relieved of pressure, the pressure intensifier device 7 remains activated and the pressure intensifier piston 8 compresses the fuel in the pressure intensifier high-pressure chamber 9. The compressed fuel is passed on to the nozzle needle 5 and injected into the combustion chamber 25.

To end the injection, the control valve is switched back to the first switch position 15 (FIG. 1), so that the pressure intensifier control chamber 9 and the injector chamber 20 can be separated from the low-pressure line 17 and connected to the high-pressure fuel source 1. As a result, the high pressure builds up again in the pressure intensifier control chamber 9. In the pressure intensifier high-pressure chamber 9, the pressure drops to the high pressure generated by the high-pressure fuel source 1. The pressure booster piston 8 is now hydraulically balanced.

The fuel high-pressure source high pressure also builds up in the injector control chamber 20 and in the injector high-pressure chamber 21, so that the nozzle piston 3 of the fuel injector 2 is also hydraulically balanced. The nozzle piston 3 is then moved in the closing direction by the force of the closing spring 24 until the injection openings 6 are closed by the nozzle needle 5. The injection has ended and the filling connection 10 is released again by the movement of the nozzle piston 3 in the closing direction.

After the pressure equalization of the system, the pressure booster piston 8 is moved in the return direction 38 by the force of the return spring 13 until it returns to its starting position. is deferred. The pressure intensifier high pressure chamber 9 is refilled from the injection nozzle control chamber 20 via the throttle 23 contained in the filling connection 10. The filling takes place automatically without the need for an additional check valve.

To stabilize the switching sequences, additional measures can be taken to dampen vibrations between the high-pressure fuel source 1 and the injector. This can e.g. B. done by an optimized design of a throttle 22 in the high pressure line 27. Alternatively, a throttle check valve (not shown) can be used at any point on the feed line (27, 31, 32).

FIG. 3 shows a fuel injection device according to the invention in a coaxial design.

The pressure booster device and the fuel injection nozzle are arranged coaxially to one another in a common injector housing 39. In the injector housing 39, two parts which are movable relative to one another are spring-mounted: a pressure booster piston 8 and a nozzle piston 3. The pressure booster piston 8 has a first (larger diameter) pressure booster piston section 18 and a second (smaller diameter) pressure booster piston section 19. The injector housing 39 also has a step-shaped taper 41. The (larger diameter) first pressure booster piston section 19 is guided axially and largely liquid-tight from the larger diameter part of the injector housing 39. The (smaller diameter) second pressure booster piston section 19 is located partly in the larger diameter part of the injector housing 39 and is partially immersed in the smaller diameter part of the injector housing, where it is axially displaceable and largely liquid-tight. The larger-diameter first pressure booster piston section 18 part in the interior of the injector housing 39 from the pressure booster work chamber 11 and the pressure booster control chamber 12. The return spring 13 surrounding the smaller-diameter second pressure booster piston section 19 is arranged in the pressure booster control chamber 12. The return spring 13 is supported on the one hand in the area of the step-shaped taper 41 of the injector housing 39 and on the other hand on the first pressure booster piston section 18 having a larger diameter. In the idle state, it presses the pressure booster piston 8 against a limiting element 42 arranged in the injector housing 39 into its idle position. The pressure intensifier piston 8 is designed as a hollow piston: it contains a central, continuous bore 43. The nozzle piston 3 is guided in a liquid-tight manner in a guide region 44 in this bore 43. A pressure piece 45, which projects into the bore 43 in the form of a cylinder, is fastened to the injector housing 39 in the region of the pressure intensifier working space 11. On the side facing the nozzle piston 3, the pressure piece 45 has a taper, on which a closing spring 24 is fitted. The closing spring 24 is supported on the one hand against the pressure piece 45 and, on the other hand, presses against the end of the nozzle piston 3 projecting into the bore 42. Between the nozzle piston 3 and the pressure piece 45 there is sufficient space to lift the nozzle needle 5 from the injection openings 6 opposed to the force of the closing spring 24 during an injection process.

The closing spring 24 is surrounded in the bore 43 by the injection nozzle control chamber 20. In the preferred embodiment of the present invention shown in FIG. 3, the injector control chamber 20 is thus arranged in the pressure booster piston 8 designed as a hollow piston. The pressure booster piston 3 contains at least one opening 46, through which the injector control chamber 20 is constantly connected to the pressure booster control room 12, so that the pressure in the two rooms 12, 20 is always equalized.

Alternatively, the injector control chamber 20 could be e.g. instead of the pressure booster control chamber 12 e.g. be connected to the pressure intensifier work space 11. Then the injector control chamber 20 is not relieved together with the pressure intensifier control chamber 12, but remains constantly at the pressure level of the work space 11. This would also be possible since a higher pressure is built up in the injector high pressure chamber 21 by the pressure intensifier 7 the fuel injector 2 thus opens. For connecting the injector control chamber 20 to the pressure booster work chamber 11, e.g. the pressure piece 45 are reduced in diameter, so that it would no longer be guided in the pressure intensifier piston 8 in a high-pressure-tight manner, but rather a connection would exist between the two spaces 20, 11 along the pressure piece 45.

In the arrangement according to FIG. 3, the pressure intensifier high-pressure chamber 9 and the injection nozzle high-pressure chamber 21 according to FIGS. 1 and 2 coincide and are formed by the high-pressure chamber 47. In this preferred embodiment of the present invention, the filler connection 10 containing a throttle 23 between the injection nozzle control chamber 20 and the high pressure chamber 47 runs in the nozzle piston 3.

The fuel is metered into the combustion chamber 25 again by activating the 3/2-way control valve 14. As a result, the pressure booster control chamber 12 is connected to the low-pressure line 17 via the connecting line 32 and is thus relieved of pressure. This activates the pressure booster device and the fuel is compressed in the high pressure chamber 47 by the pressure booster piston 3. The compressed fuel is passed along the nozzle needle 5. The nozzle piston 3 finally opens the injection openings 6 as a result of the increasing opening pressure force in the high pressure chamber 47 and the fuel is injected into the combustion chamber 25. When the fuel injection nozzle is open, the nozzle piston 3 lies with the sealing seat 26 on the pressure piece 45 and thus closes the filling connection 10 in a liquid-tight manner. In this way, no compressed fuel can flow back from the high-pressure chamber 47 into the injector control chamber 20.

To end the injection, the pressure intensifier control chamber 12 is again connected to the high-pressure fuel source 1 by the control valve 14. As a result, the high-pressure fuel generated by the high-pressure fuel source builds up in the pressure intensifier control chamber 12 and via the opening 46 in the injector control chamber 20. The pressure in the high-pressure chamber 47 drops to the high-pressure fuel high-pressure source, whereupon the pressure booster piston 8 is hydraulically balanced, as is the nozzle piston 3. The force of the springs 13, 24 moves both pistons 3, 8 in their rest position. The nozzle needle closes the injection openings 6 and the nozzle piston 3 lifts the sealing seat 26 off the pressure piece 45. The filling connection 10 is thus opened, so that the high-pressure chamber 47 is connected to the high-pressure fuel source 1 via the filling connection 10 and further spaces 20, 12 and connections 46, 32, 31, 27. Thus, the high pressure chamber 47 is filled via the filling connection 10 when the pressure intensifier piston 8 is reset.

By combining the pressure intensifier high-pressure chamber and the injection nozzle high-pressure chamber, the pressure intensifier piston designed as a hollow piston and the filling connection contained in the nozzle piston, a particularly compact construction of the fuel injection device can advantageously be achieved in this preferred embodiment of the present invention.

FIG. 4 shows a further preferred embodiment of a fuel injection device according to the invention in the idle state or when infected.

In the idle state (no injection), the control valve 14 is in a first switching position 15, in which it connects the pressure intensifier work chamber 11 to the low pressure line 17. The injector control chamber 20 and the pressure intensifier high pressure chamber 9 connected to it in the idle state via the filler connection 10 and the injector high pressure chamber 21 are connected via a second low pressure line 48 to a low pressure region (not shown), as is the pressure intensifier Control chamber 12 via a third low-pressure line 49. In this preferred embodiment of the present invention, when the fuel injector 2 is closed, the pressure intensifier high-pressure chamber 9 is via the filler connection 10 and via the injector control chamber 20, the pressure intensifier control chamber 12 and the pressure intensifier work space 11 connected to at least one low pressure line 17, 48, 49. Thus, both the pressure booster piston 8 and the nozzle piston 3 are hydraulically balanced in the idle state and both pistons 8, 3 are held in their rest position by the associated spring 13, 24. The injection openings 6 are closed towards the combustion chamber 25 by the nozzle needle 5.

For injection, the control valve 14 is switched from the first switch position 15 to the second switch position 16. In the second switching position 16, the pressure intensifier work chamber 11 is connected to the high-pressure fuel source 1. The pressure generated by the high-pressure fuel source 1 builds up in the pressure intensifier work chamber 11. The pressure booster piston 8 thereby moves in the compression direction and compresses the fuel in the pressure booster high-pressure chamber 9 to the translated pressure. This is passed on to the injection nozzle high-pressure chamber 21. The nozzle piston 3 moves in the opening direction through the pressure craft generated in this way and releases the injection openings 6. At the same time, the filling connection 10 from the pressure intensifier high-pressure chamber 9 to the injector control chamber 20 is closed by the nozzle piston 3. So there is no loss during the injection.

To end the injection process, the control valve 14 is switched back to the first switching position 15. The pressure intensifier work space 11 is then connected again to the low pressure line 17. The low pressure also arises in the pressure intensifier chamber 9 and consequently also in the injector high pressure chamber 21. The nozzle needle 5 therefore closes and the nozzle piston 3 releases the filling connection 10. The pressure intensifier high-pressure chamber 9 is filled when the pressure intensifier piston 8 is reset 38 via the filling connection 10 from the low pressure system. The filler connection 10 can contain a throttle 23 if required.

List of reference symbols

High-pressure fuel source Fuel injection nozzle Nozzle piston upper nozzle piston section Nozzle needle Injection orifices Pressure intensifier device Pressure intensifier piston Pressure intensifier high pressure chamber Filling connection Pressure intensifier work chamber Pressure intensifier control chamber Return spring control valve first switching position second switching position Low pressure line first pressure intensifier piston part area second pressure intensifier chamber injector nozzle part first throttle second throttle closing spring combustion chamber sealing seat high pressure line housing of the pressure booster device injection high pressure line pressure shoulder high pressure connecting line first connecting line second connecting line injected fuel large piston area compression direction small piston area reset direction injector housing

step-shaped taper limiting element bore guide area pressure piece opening high pressure chamber second low pressure line third low pressure line

Claims

claims

1.Fuel injection device for Brennlcraft machines with a fuel injection nozzle (2) which can be supplied with fuel by a high-pressure fuel source (1) and which have a movable nozzle nozzle (3) for opening and closing injection openings (6), an injection nozzle high-pressure chamber ( 21) and an injection nozzle control chamber (20), wherein between the fuel injection nozzle (2) and the fuel high pressure source (1) a pressure transmission device (7) is connected, which has a movable pressure transmission piston (8), one Pressure intensifier work chamber (11) and a pressure intensifier high pressure chamber (9), characterized in that when the fuel injector (2) is closed, to fill the pressure intensifier high pressure chamber (9), an open filler connection (10) when the fuel injector ( 2) is closed.

2. Fuel injection device according to claim 1, characterized in that the filling connection (10) is closed by the nozzle piston (3) when the fuel injection nozzle (2) is open.

3. Fuel injection device according to claim 1, characterized in that a pressure change in a pressure intensifier control chamber (12) contained in the pressure intensifier device (7) and / or in the pressure intensifier work chamber (11) a pressure change in the pressure intensifier high pressure chamber ( 9) causes.

4. Fuel injection device according to claim 1, characterized in that the opening and closing of the injection openings (6) can be controlled via a control valve (14).

5. Fuel injection device according to claim 1, characterized in that the filling connection (10) between the pressure intensifier high-pressure chamber (9) and the injection nozzle control chamber (20) is arranged.

6. Fuel injection device according to claim 1, characterized in that the filling connection (10) has a throttle (23).

7. Fuel injection device according to claim 1, characterized in that the fuel high-pressure source (1) is connected during the injection via a high-pressure line (27) with the pressure intensifier work chamber (11) contained in the pressure intensifier device (7).

8. Fuel injection device according to claim 1, characterized in that the filling connection (10) can be closed by the interaction of the nozzle piston (3) with a sealing seat (26).

9. Fuel injection device according to claim 1, characterized in that a sealing seat (26) is formed on the nozzle piston (3), which cooperates with a pressure piece (45) to close the filler connection (10).

10. Fuel injection device according to claim 1, characterized in that the filling connection (10) is formed in the nozzle piston (3).

11. The fuel injection device according to claim 1, characterized in that the injection nozzle control chamber (20) is arranged in the pressure booster piston (8) designed as a hollow piston.

12. Fuel injection device according to claim 3, characterized in that the pressure intensifier high-pressure chamber (9) when the fuel injector (2) is closed via a control valve (14) (in a first switching position (15)), the pressure intensifier control chamber (12 ), the injector control chamber (20) and the filling connection (10) with the high-pressure fuel source (1) is connected.

13. Fuel injection device according to claim 3, characterized in that when the fuel injector (2) opens and opens, the pressure intensifier control chamber (12) and the injector control chamber (20) have a low pressure conduit

(17) are connected.

14. A fuel injection device according to claim 3, characterized in that when the fuel injector (2) is closed, the pressure intensifier high-pressure chamber (9) via the filler connection (10) and via the injector control chamber (20)

Pressure intensifier control chamber (12) and the pressure intensifier work space (11) are connected to at least one low pressure line (17, 48, 49).