WO2007017335A1 - Divided double seat injection valve member - Google Patents

Abstract

The invention relates to a fuel injector (10) having a complex injection valve member (14) for injecting fuel into a combustion chamber (54) of an internal combustion engine. The complex injection valve member (14) comprises an outer part (18), impinged upon with pressure by a first pressure compartment (20), and at least one inner part (16; 16.1, 16.2), impinged upon with pressure by a second pressure compartment (34). The at least one inner part (16; 16.1, 16.2) comprises at least one pressure stage (36, 38) and a seat (40) having an outer part (18). A seat (42) of the outer part (18) is configured inside the nozzle body (12). Once the seat (40) of the at least one inner part (16; 16.1 and 16.2) in the outer part is opened, the opening force of the outer part (18) is reduced depending on the product of a pressure difference Δp between the system pressure pD and a pressure pS in front of the injection openings (46) having a difference in area between the seat surface of the seat (42) of the outer part (18) minus a bore surface of a bore (52) for the seat (40) of the at least one inner part (16; 16.1, 16.2).

Description

Split injection valve member with double seat

The invention relates to a split injection valve member with double seat for injecting fuel into the combustion chamber of an internal combustion engine according to the O-berbegriffes of claim 1.

State of the art

DE 31 13 475 A1 relates to a fuel injection nozzle. The fuel injector for use on internal combustion engines comprises a valve needle and a valve needle and this and their pressure chamber in an axial bore with a partially dense radial guide receiving hollow needle. The valve needle and the hollow needle are actuated by the supplied fuel, contrary to the flow direction of the fuel, in the opening direction and loaded by at least one closing spring. The pressure chamber of the valve needle is always connected to an arranged between the valve body and hollow needle pressure chamber of the hollow needle. The hollow needle and the valve needle each control an injection point with at least one injection opening each, wherein the injection points can be opened one after the other and depending on the pressure of the supplied fuel. Both needles are loaded by only one closing spring, which acts at least indirectly on the valve needle and this presses on a seat in the hollow needle and thus provides the hollow needle to a seat in the nozzle body. From a first low fuel pressure first lifts the hollow needle to a stop from its seat, the first injection point is turned on. In this case, the internally guided valve needle is taken, which is moved from a second higher fuel pressure alone against the closing spring and thus aufsteuert the second injection point.

US 5,458,292 shows a fuel injector with a multipart injection valve member. An internal part of the multi-part injection valve member is guided in an outer injection valve member part. A pressure chamber of the outer injection valve member is acted upon by high-pressure fuel. From this pressure chamber of the outer injection valve member part, the fuel flows to a pressure chamber acting on the inner injection valve member. With the injection valve member arranged on the inside, there are first fuel injection openings, and with the outside Ventilated injector member part are aufsteuerbar external Kraftstoffeinspritzöffiiungen.

In today used fuel injectors, in which the preferably needle-shaped injection valve member directly from the actuator, such. a piezoelectric actuator, is controlled by this actuator to overcome the needle opening force. The needle opening force results from the product of pressure and the area formed by the needle seat. To reduce this force required to open the injection valve member, the seat diameter must be reduced at the same system pressure. The reduction in the seat diameter of fuel injectors used today on the nozzle body is only limited possible manufacturing and functional considerations.

Presentation of the invention

The present invention is therefore based on the object to reduce fuel injectors with dirketer needle control, the force required to actuate the injection valve member.

Following the present invention, the opening of a multi-part injection valve member takes place in two steps. The multi-part injection valve member preferably comprises an inner part, which is axially guided in an outer part of the multi-part injection valve member. A pressure chamber, which is acted upon by fuel under system pressure, is always in fluid communication with a further pressure chamber which is assigned to the inner part of the multipart injection valve member. The system pressure prevailing in the pressure chamber thus always acts on the pressure chamber, which is assigned to the inner part of the multipart injection valve member.

Inner part and outer part of the multi-part injection valve member are designed so that the inner part of the multi-part injection valve member at the brennraumsei- term end has a seat whose seat diameter is smaller than the seat diameter of the seat of the outer part of the multi-part injection valve member at the combustion chamber end.

Due to the selected seat diameter opens when opening the multi-part injection valve member first, the inner part, so that very small injection quantities can be realized in the combustion chamber of the internal combustion engine. In the injection, which takes place by opening the inner part of the multipart injection valve member, a pressure builds up in the opening direction below the seat of the outer part of the multipart injection valve member. This pressure acts on the inner part of the multi-part injection valve member and causes its movement in the opening direction until the inner part of the multi-part injection valve member has undergone a stroke. After passage of the stroke is opened by, for example, a mechanical driver, the outer part of the multi-part injection valve member. To open the outer part of a reduced power requirement is necessary, which must be applied by the actuator of the fuel injector, wherein the reduced power requirement from the differential pressure between the pressure p _D in the nozzle body and the pressure below the injection holes p _s and the remaining surface of the seat diameter of the outer part d ₂ minus the bore diameter for the seat d] of the inner part of the multi-part injection valve member is formed.

The pressure building up after opening the inner part of the multipart injection valve member below the injection opening pressure is thus used to open the outer part of the multipart injection valve member and allows the reduction of the opening force, which is applied by the actuator of the fuel injector. It is possible to couple the inner part and the outer part of the multi-part injection valve member by means of a mechanical driver, or to bring about the coupling between the inner part and outer part of the multi-part injection valve member by hydraulic means.

drawing

With reference to the drawing, the invention will be described below in more detail.

It shows:

FIG. 1 shows a first embodiment variant of the fuel injector proposed according to the invention,

2 shows a cross section through the nozzle body with inner part and outer part of the multi-part injection valve member, which are coupled together via a mechanical driver,

FIG. 3 is an enlarged view of the combustion chamber end of the fuel injector as shown in FIG. 1;

FIG. 4 shows a further embodiment of the fuel injector proposed according to the invention, -A-

5 shows a cross section through the fuel injector according to FIG. 4, showing the nozzle body, the inner part and the outer part of a multipart injection valve member, which are hydraulically coupled to one another,

6 is an enlarged view of the combustion chamber end of the fuel injector according to the representation in Figure 4,

FIGS. 6.1, 6.2 and 6.3 variants of embodiment of needle-shaped injection valve members,

FIG. 7 shows a seat geometry with a continuous pointed cone,

8 shows a stepped executed pointed cone of an inner part of an injection valve member and

9 shows a pointed cone on the inner part with also continuous cone angle.

embodiments

The illustration according to FIG. 1 shows a first exemplary embodiment of the fuel injector proposed according to the invention.

A fuel injector 10, which is acted upon by a high-pressure source (not shown in detail in FIG. 1), such as a high-pressure reservoir or a high-pressure pump, surrounds this body 12. In the nozzle body 12, a multipart injection valve member 14 is housed, which has an inner part 16 and a Outer part 18 includes. According to this embodiment, the outer part 18 of the multipart injection valve member 14 is guided on the inner part 16. In the nozzle body, a first pressure chamber 20 is formed, in which system pressure p _D prevails. At the inner part 16 of the multipart injection valve member 14 is a spring element 22. At the periphery of the inner part 16 of the multi-part injection valve member 14 is at least one longitudinal groove 24; the axis of symmetry of the multipart injection valve member 14 is indicated by reference numeral 26.

In the exemplary embodiment according to FIG. 1, the inner part 16 and the outer part 18 of the multi-part injection valve 14 are mechanically coupled by means of a driver 28. The driver 28 is attached to an inner peripheral surface of the outer part 18 and surrounds a pin 44 of the inner part 16 of the multi-part injection valve member 14th At the combustion chamber end of the nozzle body 12 of the fuel injector 10 according to the Ausiührungsbeispiels in Figure 1, there are a number of injection ports 46, via which the fuel under system pressure can be injected into a not shown in Figure 1 combustion chamber of an internal combustion engine.

The illustration according to FIG. 2 shows a cross section through the combustion chamber side area of the fuel injector according to the exemplary embodiment in FIG. 1 according to section line II-II.

Within the nozzle body 12, the first pressure chamber 20 is shown in a circular shape in FIG. The first pressure chamber 20 encloses the outer part 18 of the multi-part injection valve member 14. The pin 44 is enclosed by the driver 28, which is fixedly connected to the inner peripheral surface of the outer part 18 of the multi-part injection valve member, such. cohesively joined. In the illustration according to Figure 2, the driver 28 is formed sickle-shaped. Instead of the geometry of the driver 28 shown in FIG. 2, this could also have a semicircular or another contour familiar to the person skilled in the art, e.g. the driver 28 may be made of two half-shells. To ensure the mechanical coupling via the driver 28, this is firmly connected to the outer part 18 of the multipart injection valve member 14.

FIG. 3 is an enlarged view of the combustion chamber end of the fuel injector as shown in FIG.

As can be seen in FIG. 3, the multipart injection valve member 14, which is surrounded by the first pressure chamber 20, comprises the inner part 16 with the pin 44, on which the outer part 18 is guided in a guide section 48. The stroke, which must be covered by the inner part 16 of the multi-part injection valve member 14 in the opening direction in order to open the outer part 18, is indicated by reference numeral 30. The mechanical carrier 28, which can be formed in a crescent-shaped cross-section as shown in FIG. 2, is e.g. cohesively connected to the peripheral surface of the outer part 18.

The mode of operation of the fuel injector proposed according to the invention is as follows:

From the first pressure chamber 20 in the nozzle body 12 flows through at least one inlet bore 32 under system pressure fuel to a second pressure chamber 34 to. The second pressure chamber 34 is defined by the outer contour of the inner part 16 and the inner contour of the outer Part 18 defines. In the illustration according to FIG. 3, for example, two inlet bores 32 and their symmetry axis 50 are shown. The number of inlet bores 32 in the outer part 18 can be chosen arbitrarily, taking into account strength reasons.

The inner part 16 includes a first pressure stage 36 and a second pressure stage 38. At the combustion chamber end of the inner part 16 is a seat 40 of the inner part 16 in the outer part 18 of the multi-part injection valve member 14. The seat diameter of the seat 40 of the inner part 16 is denoted by d] , The seat 40 of the inner part 16 is located on a bore 52 which is formed at the combustion chamber end of the outer part 18. The bore diameter of the bore 52 is designated by d _B. The outer part 18 has a seat 42 whose diameter is denoted by d ₂ . In the illustration according to FIG. 3, the inner part 16 is placed in its seat 40 in the outer part 18 and the outer part 18 of the multipart injection valve member 14 is placed in its seat 42 in the nozzle body 12. The opening into the combustion chamber 54 of the internal combustion engine Einspritzöff- openings 46 are therefore closed.

The opening of the multi-part injection valve member 14 with the inner part 16 and the outer part 18 proceeds as follows:

First opens the inner part 16, by a pressure reduction in a control chamber 13 of the fuel injector 10. The force acting on the inner part 16 opening force is generated by the formed on the inner part 16 first pressure stage 36 and formed on the inner part 16 second pressure stage 38. By way of the seat 40 released after the opening of the inner part 16, very small injection quantities are injected into the combustion chamber 54 via the injection bores 46. Before the injection openings 46 below the seat 42 of the outer part 18, the pressure p _s builds up. Upon further opening of the inner part 16, this passes through the stroke 30 and pulls the outer needle member 18 at stop on the driver 28. This is to open the outer part 18, a reduced power requirement needed, which is applied by the actuator. The reduced power requirement results from the differential pressure between the pressure in the nozzle body p _D and the pressure in front of the injection openings 46 p _s multiplied by the residual area of the diameter d _{2 of} the seat 42 of the outer part 18 minus the diameter of the bore 52 for the seat 40 of the inner part 16. Accordingly, after opening the inner part 16 in the combustion chamber end of the nozzle body 12 below the outer part 18 building pressure for opening the outer part 18 of the multi-part injection valve member 14 is used. This allows a smaller dimming of the actuator, since the opening force required for opening the multi-part injection valve member 14 is significantly reduced by the solution proposed by the invention. Of the Differential pressure Δp depends on the residual area, which is calculated according to the following relationship: - (d ₂ ² - d] ² ) with Δp = p _d - p _s with p _d nozzle pressure and p _s system pressure. 4

The illustration according to FIG. 4 shows a further exemplary embodiment of the fuel injector proposed according to the invention with a multipart injection valve member.

The multipart injection valve member 14 according to Figure 4, also includes an inner part 16 and an outer part 18, which, however, in contrast to the exemplary embodiment of Figure 1 are not mechanically but hydraulically coupled together. According to the exemplary embodiment illustrated in FIG. 4, the inner part is designed to be divided and comprises a first part 16.1 and a second part 16.2. The first part 16.1 is traversed by a connecting channel 70 which opens above an end face 72 (FIG. 6) of the second part 16.2 of the inner part.

In the nozzle body 12 of the fuel injector 10 according to Figure 4, the first pressure chamber 20 is executed, with reference numeral 46 are formed at the combustion chamber end of the nozzle body 12 injection openings.

FIG. 5 shows a cross-section according to the sectional profile V-V shown in FIG.

From the illustration according to FIG. 5, it can be seen that the first part 16. 1 is completely enclosed by the outer part 18 of the multipart injection valve member. Reference numeral 70 designates the connecting channel passing through the first part 16.1. The outer part 18 of the multipart injection valve member is enclosed by the first pressure chamber 20 which is bounded by the nozzle body 12.

FIG. 6 shows the combustion-chamber-side end of the exemplary embodiment according to FIG. 4 in an enlarged representation.

According to this embodiment, the inner part 16 of the multi-part injection valve member 14 comprises a first part 16.1 with a connecting bore 70 and a separate second part 16.2 thereof. Both the first part 16.1 and the second part 16.2 of the split-shaped inner part 16 are enclosed by the outer part 18. The connecting channel 70 of the first part 16.1. opens above an end face 72 of the second part 16.2. The prevailing in the first pressure chamber 20 system pressure p _D acts via inlet openings 32 in a second pressure chamber 34. The second pressure chamber 34 is defined by the contour of the second part 16.2 and the inner contour of the outer part 18. The first pressure chamber 20 and the second pressure chamber 34 are always in fluid communication with each other, so that in both pressure chambers 20, 34 system pressure p _D is always present. Analogous to the exemplary embodiment according to FIG. 1, the seat 40 of the second part 16. 2 of the inner part 16 is formed in the outer part 18. The seat of the second part 16.2 in the outer part 18 has the diameter d]. The bore 52, on which the seat 40 of the second part 16.2 of the inner part 16 is formed, is embodied in a diameter d _B. Below the end of the outer part 18 a plurality of injection openings 46 are shown, which are distributed approximately in a star shape and allow a uniform injection of fuel into the combustion chamber 54 of the internal combustion engine. The seat 42 of the outer part 18 in the nozzle body 12 has a diameter d ₂ .

In the illustration according to FIG. 6, both the seat 40 of the second part 16.2 of the inner part 16 and the seat 42 of the outer part 18 of the multipart injection valve member 14 are closed.

The applied in the second pressure chamber 34 pressure p _D acts on the first pressure stage 36 and the second pressure stage 38 of the second part 16.2 of the inner part 16. The end face 72 of the second part 16.2 of the inner part 16 is controlled by prevailing in the control _chamber 16 of the fuel injector 10 pressure p r acted upon. If the second part 16.2 of the inner part 16 opens in the opening direction, the seat 40 of the second part 16.2 is opened, so that a small injection quantity can be injected into the combustion chamber 54 via the injection openings 46. Before the injection openings 46, a pressure p _s builds up below the still closed seat 42 of the outer part 18 of the multipart injection valve member. The second part 16.2 continues to open until its end face 72 has passed through the stroke 30. In the connecting _channel 70 prevails in the control _chamber 13 respectively applied pressure p _Steue r

After opening the second part 16.2 of the inner part 16 and below the still closed seat 72 of the outer part 18 is under the seat 42 of the outer part 18 of the pressure p _{s in} front of the injection openings 46 at. To open the outer part 18 from the seat 42 a reduced power requirement is necessary, resulting from the pressure difference Δp = p _D - p _s and the remaining surface of the seat diameter d _{2 of} the outer part 18 minus the bore diameter d _{B of} the bore 52 for the seat 40 of second part 16.2 of the inner part 16 of the multi-part injection valve member results. The residual surface of the seat diameter d _{2 of} the outer part minus the bore diameter d _b for the inner part results according to the

Relationship (d ₂ ² - d] ² ). Depending on the design, d] can also be equal to d _B.

4 Both exemplary embodiments according to FIG. 1 and FIG. 4 have in common that a reduced power requirement is required to actuate the outer part 18 of the multi-part injection valve member 14, which has to be applied by an actuator, such as a piezoactuator. The smaller this opening force, the smaller the actuator can be designed. It is irrelevant whether the inner part 16 - be it in one piece, be it in two parts, the first part 16.1 and the second part 16.2 comprising - and the outer part 18 hydraulically coupled according to Figure 4, or by means of a mechanically acting driver 28, as shown in the embodiment of Figure 1.

FIG. 6.1 shows a multipart injection valve member 14, the inner part 16 of which is designed in several parts and comprises the first part 16.1 and the second part 16.2. According to this embodiment, a press fit is performed between the first part 16.1 and the outer part 18 of the multi-part injection valve member 14, so that only the second part 16.2 of the inner part 16 is movable relative to the outer part 18 of the multi-part injection valve member 14. Analogously to the exemplary embodiment illustrated in FIG. 6, the first pressure chamber 20 and the second pressure chamber 34 communicate via the at least two inlet bores 32, which are mounted on an outer axis 18 on an axis of symmetry 50. On the second part 16.2 of the inner part 16, a first pressure stage 36 and a second pressure stage 38 are executed.

In the lower region of the multipart injection valve member 14, the seat 40 for the second part 16.2 of the inner part 16 is shown in the closed position; the seat 42 of the outer member 18 in the nozzle body 12 of the fuel injector 10 is also closed. In the seat 42 of the outer part 18, the seat 42 on the seat diameter d ₂ ; the seat diameter of the seat 40 of the inner part 16 and of the second part 16.2 of the inner part has a diameter d]. On the outer part 18 of the multipart injection valve member 14 is a bore 52 which is formed in the bore diameter d _B. Below the seat 42 of the outer part 18 are formed in the nozzle body 12 injection openings 46 which may be arranged in a star shape with respect to the axis of symmetry 26 and via which the fuel is injected into the combustion chamber 54 of the internal combustion engine.

The illustration according to FIG. 6.2 shows a further embodiment variant of an injection valve member. According to this embodiment, the inner part 16 of the multi-part injection valve member 14 is integrally formed. The passage 70 shown in the embodiment of Figure 6 and an end face which can be pressurized by the control chamber, are omitted. Analogous to the above-described exemplary embodiment according to the illustration in FIG. 6.1, the one-piece injection valve member 14 has an inner part 16, but in one piece, and an outer part 18. A second pressure chamber 34 within the outer part 18 of the multipart injection valve member 14 is in contact with the first via the inlet bores 32 Pressure chamber 20 in conjunction. The inlet bores 32 are located on the axis of symmetry 50 with respect to the outer part 18. In the first pressure chamber 20, the pressure level b _d prevails while the pressure before the Einspritzöffhungen is indicated with p _s . The bore 52 at the combustion chamber-side end of the outer part 18 is designed in diameter d _B and, in the illustration according to FIG. 6.2, is closed by the seat 40 of the inner part 16 at the diameter d1. Similarly, the seat 42 of the outer part 18 in the nozzle body 12 (see diameter d ₂ ) is also closed. The seat 42 separates the area in the nozzle pressure prevails p _D of the area in which the pressure level p _s prevails. Analogous to the representation in accordance with FIG. 6.1, the injection openings 46 extend as fine channels at the end of the nozzle body 12 at the combustion chamber end and are arranged, for example, in a star shape with respect to the symmetry axis 26 in the nozzle body 12.

The illustration according to Figure 6.3 shows a further embodiment of a multi-part injection valve member whose inner part is formed in several parts and has a first part 16.1 and a second part 16.2. The end face 72 of the second part 16.2 of the multi-part inner part 16 is acted upon via the connecting channel 70 with the pressure prevailing in the control chamber 13. The inner part 16.2 is movably arranged with respect to the outer part 18 of the multi-part injection valve member 14. Via a hydraulic coupling according to this embodiment is given by the connecting channel 70, with which the pressure prevailing in the control chamber 13 pressure level is transmitted to the end face 72 of the second part 16.2 of the multi-part inner part 16.

In the illustration according to Figure 6.3, both the seat 40 (see seat diameter d]) and the seat 42 of the outer part 18 (see seat diameter d ₂ ) are closed. In contrast to the holes 52 shown in Figure 6.1 and 6.2 at the combustion chamber end of the outer part 18 of the multi-part injection valve member 14, the bore 52 extends at the combustion chamber end of the outer part 18 in the embodiment of FIG 6.3 funnel-shaped and has a continuously - with respect to the combustion chamber end of the outer part 18 - narrowing diameter.

The illustrations according to FIGS. 7, 8 and 9 show different seat geometries of a multipart injection valve member 14. Thus, for example, the inner part 16 of a multi-part injection valve member 14 shown in FIG. 7, be it a one-piece inner part 16 or a second part 16. 2 of a multi-part inner part, has a pointed cone which, at its seat diameter d 1, rests against its seat 40 on the inside of the outer part 18 is applied. The seat 42 of the outer part 18 in turn has the seat diameter d ₂ and is closed in the illustration according to FIG. 7, so that the injection openings extending at the combustion chamber end of the nozzle body 12 are all separated from the region in which the nozzle pressure p _D prevails.

In comparison to the inner part of the injection valve member shown in FIG. 7, a stepped conical region is formed at the combustion chamber end of the inner part 16 or a second part 16. 2 of a split inner part 16, at which the seat diameter d] prevails at the separation of the conical regions Seat 40 of the inner part 16 and the second part 16.2 of the inner part in the outer part 18 defined. The bore 52 at the combustion chamber end of the outer part 18 of the multi-part injection valve member 14 extends in a constant diameter d _B ; the seat diameter of the seat 40 is indicated d], the seat diameter of the seat 42 of the outer part 18 in the nozzle body 12 is designated by the diameter d ₂ . The seat 42, which is in the closed state, separates the area in which the nozzle pressure p _D prevails from the area in which the system pressure p _s prevails. With respect to the axis of symmetry 26 of the nozzle body 12, the injection openings 26 may extend approximately star-shaped at the combustion chamber end of the nozzle body 12.

Finally, FIG. 9 shows a further embodiment variant of a nozzle seat geometry in which an integrally formed inner part 16 or the second part 16.2 of a multipart interior part 16 are placed in the seat 40 of the outer part 18 of the multipart injection valve member 14. In the outer part 18 of the multi-part injection valve member 14 is the bore 52, which is formed in the embodiment shown in Figure 9 in constant diameter d _B. Below the closed seat 42 of the outer part 18 in the nozzle body 12, system pressure p _s prevails, which is separated by the closed seat 42 from the region in which the nozzle pressure p _D prevails.

Compared to the inner part 16 and the second part 16.2 of a multi-part inner part 16 shown in FIG. 8, the seat geometry according to FIG. 9 has a uniform course at the tip of the one-piece inner part 16 and the second part 16.2 of the multi-part inner part 16. The tip cone is placed in its seat 40, which adjusts itself at the inlet into the bore 52 in the outer part 18 of the multipart injection valve member 14. Due to the closed seat 42 of the outer part 18, the region in which the nozzle pressure p _D prevails and the region in the system pressure p _s prevails, so that no fuel flows beyond the fuel injector in the nozzle body relative to the axis of symmetry 26 of the fuel injector star-shaped injection openings 46 is injected into the combustion chamber 54. Bezueszeichenliste

10 Fuel injector PD Pressure in the nozzle body (System¬

12 nozzle body pressure)

13 control chamber Ps pressure in front of injection openings 46

14 multi-part injection valve member

16 Inner part (one-piece, multi-part) 70 Connecting channel

16.1 first part 72 end face second part 16.2 of

16.2 second part multi-part inner part 16

18 outdoor unit

20 first pressure chamber

22 spring element

24 longitudinal groove

26 symmetry axis

28 drivers

30 stroke

32 inlet bore

34 second pressure chamber

36 first pressure level

38 second pressure level

40 seat inner part 16 or second part

16.2

42 seat outer part

44 cones

46 injection port

48 guide inner part

50 symmetry axis inlet bore

52 bore outer part 18

54 combustion chamber

d] seat diameter seat 40 d ₂ seat diameter seat 42 d _B bore diameter bore 52

Claims

claims

1. Fuel injector (10) with a multipart injection valve member (14) for injecting fuel into a combustion chamber (54) of an internal combustion engine, with an outer part (18) which is pressurized by a first pressure chamber (20) and with at least one inner part (16 16.1, 16.2), which is pressurized by a second pressure chamber (34), wherein the at least one inner part (16; 16.1, 16.2) has at least one pressure stage (36, 38) and a seat (40) in an outer part (18) while a seat (42) of the outer part (18) is ausgebiledet in the nozzle body (12), characterized in that after opening the seat (40) of the at least one inner part (16; 16.1, 16.2) in the outer part (18) the opening force of the outer part (18) depending on the product of a pressure difference Δp between system pressure p _D and a pressure ps before the injection openings (46) and a surface difference between the seat surface of the seat (42) of the outer part (18) minus one Drilling surface of a bore (52) for the seat (40) of the at least one inner part (16; 16.1, 16.2) is reduced.

2. Fuel injector according to claim 1, characterized in that the injection openings (46) are arranged in a star shape at the combustion chamber end of the nozzle body (12) and an injection of fuel via this, both at least an inner part (16; 16.1, 16.2) , as well as when the outer part (18) is open.

3. Fuel injector according to claim 1, characterized in that the first pressure chamber and the second pressure chamber (34) are always acted upon by system pressure p _D.

4. Fuel injector according to claim 1, characterized in that in the outer part (18) below the seat (40) a pressure build-up below the seat (42) of the outer part (18) enabling bore (52) is executed.

5. Fuel injector according to claim 1, characterized in that the at least one inner part (16; 16.1, 16.2) and the outer part (18) are hydraulically or mechanically coupled to one another.

6. Fuel injector according to claim 5, characterized in that the outer part (18) has an inner part (16) at least partially enclosing driver (28).

7. Fuel injector according to claim 5, characterized in that the second part (16.2) of the inner part (16) has an end face (72), which lies opposite a connecting channel (70) in the first part (16.1) of the inner part (16).

8. Fuel injector according to claims 6 or 7, characterized in that the outer part (18) after passing through a stroke (30) through the at least one inner part (16; 16.1 and 16.2) is opened with a reduced opening force.

9. Fuel injector according to claim 4, characterized in that the outer part (18) on the inner part (16) of the multi-part injection valve member (14) is guided on a guide portion (48).