DE102005060656A1 - Fuel injection valve for internal combustion engine has pressure cavity for outer needle control valve with pressure surfaces for valve-side endface - Google Patents

Abstract

The fuel injection valve has a valve body containing a co-axial valve needle unit (50) with an inner valve needle (51) and an outer valve needle (52). The outer valve needle pressure cavity (16) for opening the outer valve needle has pressure control surfaces (22, 221) for a further valve-side endface (81) of the outer valve needle.

Description

The The invention relates to a fuel injection valve with coaxial valve needle assembly for internal combustion engines according to the preamble of claim 1.

A fuel injection valve according to the preamble of claim 1 is already in the DE 10200401980036 A1 described. In this injection valve, a valve needle assembly is provided with an inner and an outer valve needle, wherein a single control chamber is provided for both valve needles. The opening of the inner valve needle controlling pressure surface is arranged on a valve seat side end face of the inner valve needle. The pressure surface which controls the opening of the outer valve needle is formed by a pressure shoulder, which is arranged at a distance from the valve seat-side end face on the outer valve needle. The pressure shoulder is exposed to a valve needle pressure chamber which is formed as an annular space on the outer circumference of the outer valve needle. Both valve needles are pressure balanced to initiate the closing process, since the closing acting surfaces are the same size as the opening acting surfaces and both surfaces experience the same pressure. Both valve pins close via spring forces.

task The present invention is a fuel injection valve to create a coaxial valve needle assembly, the compact is executed and more options for the Design of printing surfaces offers.

Advantages of the invention

The The object of the invention is with the characterizing features of Claim 1 solved. The fuel injection valve according to the invention has a compact design and offers more possibilities for the design the printing surfaces as in known fuel injection valves with a coaxial Valve needle assembly, because the Ventilnadeldrückräume for the openings of the inner and outer valve needle controlling pressure surfaces each formed on the valve seat side end surfaces of the valve needles are. When the valve needles are closed, both rows of spray holes are hydraulically sealed, which is why double seats for both Valve needles can be dispensed with. In particular, this is the case when the pressure in the control room for the outer valve needle is low or close to zero when the valve needle is closed. In the case of a simple double cone for the outer valve needle is the enclosed Dead volume low, which is why only minor HC emissions occur likely. About that In addition, in principle, a larger diameter for the valve needle seats possible than in previous designs. A larger seat diameter works positively affect the seat wear and the strength of the valve body. Furthermore the valve needle stroke can be reduced with constant needle throttling become.

advantageous Further developments of the invention are possible by the measures of the subclaims.

The Arrangement of the valve needle pressure chambers the respective valve seat side end surfaces of both valve pins is thereby possible because the valve needle pressure chambers through the two lower essentially hydraulic sealing guides on the outer valve needle are limited.

By the formation of the two axially offset guide holes and thereby trained essentially hydraulically sealed guides Beyond that two separate control rooms realized, wherein the first control chamber of the inner valve needle and the second control chamber of the outer valve needle is assigned and wherein the second control chamber for the outer valve needle within of the valve body between the valve seat remote guide bore and the valve seat near guide bore is trained. The inner valve needle is the first control chamber with a closing direction control surface and the outer valve needle is the second control chamber with a further acting in the closing direction further control surface exposed. Due to the two separate control rooms is an active closing the inner valve needle possible, because the closing acting pressure surfaces are bigger as the opening one acting surfaces.

To the Driving the inner and outer valve needle is the first control room for the inner valve needle to an inlet bore and a drain hole and the second control room for the outer valve needle to another inlet bore and to another drain hole connected, with the inlet bores with a high pressure system and the drain holes are connected to a low pressure return system. The control rooms be by means of a first control valve and by means of a second Control valve pressure loaded and depressurized.

The needed to control, closing acting pressure surfaces are directly associated with the valve needles, which is why the more compact Construction with a smaller number of components and thus a lower Number of sealing points is necessary.

A particularly compact embodiment of the fuel injection valve is achieved by a control sleeve of the inner valve needle is assigned and the control sleeve hydraulically separates the closing chamber substantially from the control room. The control sleeve has at least one sealing surface, which with a cooperates on a throttle body formed another sealing surface. Characterized in that the control sleeve is guided within the inner valve needle in a guide bore, that the closing space is formed in the guide bore and the closing surface has the diameter of the guide bore, a particularly compact fuel injection valve is made possible. It is also expedient if the control sleeve has a central bore which communicates with the one end with a first inlet bore and with the other end with the closing space in combination.

One Shut down the outer valve needle over the closing the inner valve needle is enabled in that the inner valve needle has a stop surface which, when closing the inner valve needle as a mechanical driver on the outer valve needle in the closing direction acts. The stop surface At the same time forms a stroke limitation when opening for the outer valve needle.

embodiments

embodiments The invention are illustrated in the drawing and in the following description explained in more detail.

It demonstrate:

1 a longitudinal section through a fuel injection valve according to the invention,

2a an enlarged section X of the valve seat side portion of the valve needle assembly according to a first embodiment,

2 B an enlarged section X of the valve seat side portion of the valve needle assembly according to a second embodiment,

3 an enlarged section X of a valve seat side portion of the valve needle assembly of a second embodiment of the fuel injection valve and

4 a further embodiment of the fuel injection valve.

In the 1 and 4 shown fuel injectors and the zu 3 belonging fuel injection valve each have a housing with a valve body 2 and a throttle body 3 on. The two parts of the housing are pressed against each other by a device not shown and hydraulically held tightly together. In the valve body 2 is a stepped bore 10 formed, in which a coaxial valve needle assembly 50 with an inner valve needle 51 and an outer valve needle 52 is guided axially displaceable. In the stepped bore 10 is with an upper portion a first, valve seat remote guide bore 11 and with a lower portion, a second, near the valve seat guide bore 13 formed.

The inner valve needle 51 has a first, valve seat remote guide portion 18 and a second, valve seat near guide portion 19 , The valve seat remote guide section 18 is in the valve seat remote guide bore 11 guided. At the valve seat near guide section 19 is the outer valve needle 52 with an inner pilot hole 55 guided axially displaceable. The outer valve needle 52 also has an outer guide circumference 56 on, with which the outer valve needle 52 additionally in the valve seat near guide bore 13 the stepped bore 10 in the valve body 2 is guided. All three guides are essentially hydraulically sealed. The inner valve needle 51 is on its entire length of a fuel channel 6 traversed along the longitudinal axis 7 of the valve needle assembly 50 runs and in a first, inner valve needle pressure chamber 16 empties.

The inner valve needle 51 has a guide bore at the end remote from the valve seat 25 on, in which a control sleeve 20 is guided longitudinally displaceable. This guide is essentially hydraulically sealed. The inner valve needle 51 also has an end face with which the inner valve needle 51 the pressure in a first control room 30 is exposed and thereby a control surface 26 for the inner valve needle 51 forms. The control area 26 is designed as an annular surface and thus has the valve seat remote guide section 18 present diameter d2 of the guide bore 11 and the diameter d3 of the guide bore 25 ,

At the valve seat near guide section 19 is on the inner valve needle 51 a stop surface 59 formed when closing the inner valve needle 51 as a mechanical driver on the outer valve needle 52 acting in the closing direction, if the inner valve needle 51 in front of the outer valve needle 52 is closed. In addition, the stop surface forms 59 a stroke limit when opening for the outer valve needle 52 out.

The inner valve needle 51 has at the top a valve seat side end face 8th put in the first, inner needle valve pressure chamber 16 has. The outer valve needle 52 is at the top ebenfells with another valve seat side end face 81 running, the a second, external needle valve pressure chamber 161 is exposed.

Between the guide sections 18 and 19 or between the guide holes 11 and 13 forms the stepped bore 10 around the inner valve needle 51 an annulus 23 out, who has a second control room 60 for the outer valve needle 52 forms. The second control room 60 is the outer valve needle 52 with a printing surface 61 exposed. At the printing surface 61 grips a closing spring 63 at, located at a valve seat remote guide section 11 trained ring surface 64 supported. To adjust the closing force is on the ring surface 64 the closing spring 63 a dial 65 pads. The annulus 23 is in the direction of the valve seat remote guide bore 11 an extended annulus 231 upstream, in the valve body 2 introduced an inlet hole 21 and a drain hole 24 lead. In the extended annulus 231 there is one on the inner valve needle 51 acting in the axial direction pressure surface, the one in the second control chamber 60 pointing pressure shoulder 66 for the inner valve needle 51 forms.

In the throttle body 3 are a first, centrally located inlet hole 31 , a second inlet hole 32 with a first inlet throttle 33 , a third inlet hole 38 with a second inlet throttle 39 , a first drain hole 34 with a first outlet throttle 35 and a second drain hole 36 with a second outlet throttle 37 educated. The third inlet hole 38 is with the inlet channel 21 and the second drain hole 36 with the drainage channel 24 connected. The first inlet hole 31 , the second inlet hole 32 and the third inlet hole 38 are connected to a high pressure system, such as a common rail system. The first drain hole 34 and the second drain hole 36 lead into a pressurized return system. The second inlet hole 32 is a first control valve 71 and the third inlet hole 38 a second control valve 72 assigned. The first control valve 71 and the second control valve 72 can alternatively also according to a representation shown with dashed lines with 711 denotes the first drain hole 34 and / or with 721 denotes the second drain hole 36 be assigned. But it is also conceivable, the central inlet bore 31 to assign another control valve.

The control sleeve 20 is with a central hole 43 provided with the central inlet bore 31 is hydraulically coupled, so that the first inlet hole 31 connected high-pressure connection continues via the central bore 43 , the guide hole 25 and the fuel channel 6 into the valve needle pressure chamber 16 to be led. The control sleeve 20 is further by means of a compression spring 44 in the guide hole 25 biased. The compression spring 44 is a shim 45 underlaid, with the closing force for the valve needle 51 can be adjusted.

In the control room 30 opens the second inlet hole 32 and the first drain hole 34 , A sealing surface 41 the control sleeve 20 against a face 42 of the throttle body 3 directed, separates the control room 30 from the central inlet bore connected to the high pressure port 31 ,

Below the control sleeve 20 forms the guide hole 25 a closing room 27 , which is the diameter d3 of the guide bore 25 owns and the around the fuel channel 6 around inside the inner valve needle 51 forms an annular surface, which serves as a closing surface 28 with the diameter d3 in the closing direction on the inner valve needle 51 acts. The closing room 27 is over the central hole 43 and the first inlet hole 31 connected to the high pressure system.

The stepped bore 10 is at one end of the valve body 2 from one on the valve body 2 trained valve body seat 15 limited, which is formed substantially conical. From the valve body seat 15 go the inner valve needle 51 associated inner injection openings 17 and the outer valve needle 52 associated outer injection port 711 from, which open in installation position of the fuel injection valve in a combustion chamber of an internal combustion engine.

Formations of the sealing seat side faces 8th and 81 of the valve needle assembly 50 go out 2a and 2 B out. According to 2a is on the valve seat side end face 8th one in the opening direction of the valve needle 51 pointing first printing surface 21 formed, which the inner valve needle pressure chamber 16 is exposed. The in the valve needle pressure chamber 16 in the closed state of the inner valve needle 51 acting first printing surface 21 is limited in size by a diameter d4, by the support of a valve needle seat 510 on the valve body seat 15 is determined. In the present embodiment, the diameter d4 is identical to the diameter of the valve seat near the guide section 19 the inner valve needle 51 because of the inner valve needle 51 trained valve needle seat 510 holding the valve needle pressure chamber 16 to the injection opening 17 seals, on the outer circumference of the inner valve needle 51 is executed. The outer valve needle 52 has in the embodiment according to 2a a so-called double sealing seat with a first valve needle seat 521 and a second valve needle seat 522 , Between the seats 521 and 522 is the further injection opening 171 arranged. The outer valve needle 52 also has on the valve seat side end face 81 one in the opening direction of the valve needle 51 pointing further printing surface 22 facing the outer valve needle pressure chamber 161 is exposed. The further printing surface 22 is determined in the closed state by the diameter d5. In the open state forms on the outer valve needle 52 another, additionally opening printing area 221 from the diameter d1 is determined. The outer valve needle pressure chamber 161 is in the closed state of the valve needle assembly 50 from the valve needle seat 510 the inner valve needle 51 and from the inner valve needle seat 521 the outer valve needle 52 limited.

In the embodiment in 2 B are the inner valve needle 51 and the outer valve needle 52 each with a double cone as valve needle seats on the valve seat side end faces 8th and 81 educated. This is the first pressure surface 21 the inner valve needle 51 from the valve pin seat 510 limited to the diameter d4. When lifting the inner valve needle 51 from the valve body seat 15 takes place on the valve seat side end face 8th a pressure infiltration and the opening pressure surface 21 is placed on a second, additionally opening printing surface 211 which then increases from the outer diameter of the inner valve needle 51 is limited. After opening the inner valve needle 51 the opening pressure is in the second valve needle pressure chamber 161 on, there on the opening acting pressure surface 22 the outer valve needle 52 acts, reducing the outer valve needle 52 from the valve body seat 15 is lifted. As a result, the valve seat side end face 81 the outer valve needle 52 infiltrated by the opening pressure and the opening acting pressure surface 22 is placed on a second, additionally opening printing surface 221 then enlarged by the outer diameter d1 of the outer valve needle 52 is limited.

A second embodiment of a fuel injection valve with a coaxial valve needle assembly 50 shows the enlarged section X of the sealing seat side valve needle assembly 50 in 3 , Here, the components, not shown, are identical to the components of the embodiment in 1 , The difference to 1 is that at the sealing seat near guide section 19 the outer valve needle 52 a hydraulic connection channel 70 is arranged, that of the fuel channel 6 in the other valve needle pressure chamber 161 leads. In addition, in this embodiment, the inner valve needle 51 also a double sealing seat with a first valve needle seat 511 and a second valve needle seat 5L2 executed. The first opening print area 21 the inner valve needle 51 is limited by the diameter d4. With the lifting of the inner valve needle 51 from the valve body seat 15 takes place on the valve seat side end face 8th a pressure infiltration, so that the opening pressure surface 21 on the additional opening pressure surface 211 is increased, which is limited by the diameter d6, in turn, the diameter of the valve seat near the guide section 19 equivalent. Between the two valve needle seats 511 and 512 are the inner injection openings 17 arranged. This embodiment allows the two injection ports 17 and 171 in their order can be opened optionally. So it is possible by controlling the outer valve needle 52 first the outer injection openings 171 to open and only then the inner injection openings 17 switch on or before the outer valve needle 52 close. In addition, both in the embodiments according to 2a and 2 B as well as in the embodiment according to 3 Embodiments of the valve body seats 15 with training of double cones, Trikegeln etc. possible. Such embodiments of the sealing seat are known per se.

Another embodiment of the fuel injection valve shows 4 , Here is the support for the closing spring 63 spaced from the annular surface 64 on the valve body 2 trained by putting in the annulus 23 a stop collar 651 is trained. The stop collar 651 can with traction and / or positive engagement, for example as a snap ring in the annulus 23 of the valve body 2 be attached.

The fuel injector with d2> d1, d4 and d6> d3 works as follows:
In a first control principle, the control valves 71 . 72 at the inlet bores 32 and 38 arranged. The pressure in the control rooms 30 and 60 is with open control valves 71 . 72 lower than the system pressure because of the inlet and outlet throttles 33 . 35 . 37 . 39 partially the pressure is lowered. The switching sequence is such that first the inner valve needle 51 is activated. Alternatively, then the outer valve needle 52 be activated, this only after the arrival of the inner valve needle 51 in the valve body seat 15 happens.

In the embodiments according to 1 . 2a . 2 B and 4 (except 3 ) it is advantageous that both valve pins 51 . 52 only by activation of the inner valve needle 51 closed, with first the inner valve needle 51 closes. For this it suffices that the control valve 71 is opened and thus system high pressure in the inlet bore 32 is applied. The pressure in the control room 30 rises thereby to a pressure level according to the vote of the inlet and outlet throttle 33 . 35 at. The inner valve needle 51 pushes the outer valve needle 52 by means of the stroke stop or the mechanical driver on the surfaces 59 . 61 in front of him. This happens when the sum of the closing pressure forces, which are composed of the pressure force on the control surface 26 added with the pressure force on the closing surface 28 and the spring force of the compression spring 44 , are greater than the sum of the opening pressure forces acting on the pressure surfaces 2l . 211 and 22 . 221 both valve pins 51 . 52 , According to the embodiment 4 In addition, the spring force of the compression spring acts 63 closing on the outer valve needle 52 , According to the embodiment 1 becomes when taking the outer valve needle 52 through the inner valve needle 51 the spring force of the Druckfe of the 63 lifted as they simultaneously closing on the outer valve needle 52 and opening on the inner valve needle 51 acts. Only with the sole closing of the inner valve needle 51 acts in the initial stage, the compression spring 63 at 1 on the inner valve needle 51 opening.

Because d2> d1, both valve needles become 51 . 52 in the direction of the valve body seat 15 pushed, even if because of the pressure reduction in the control room 30 via the inlet and outlet throttles 33 . 35 the pressure in the control room 30 not reached the full height of the system pressure. If the inner valve needle 51 in the valve body seat 15 is set, the pressure builds up in the second valve needle pressure chamber 161 rapidly over the spray holes 171 because the connection with the high pressure through the inner valve pin seat 510 . 511 . 512 is interrupted. The rest of the stroke is carried out by the outer valve needle 52 because the closing spring force of the compression spring 63 from a certain pressure level in the valve needle pressure chamber 161 is greater than the opening pressure acting on the end face 81 the outer valve needle 52 with the printing surfaces 22 . 221 , If the outer valve needle 52 a separate stroke stop on the valve body 2 would have, the operation would be similar. The outer valve needle 52 has in this case with the inner valve needle closed 51 to go through the full stroke until closing. The closing process is then correspondingly longer.

Alternatively, to speed up the closing process for the outer valve needle 52 in addition, the pressure in the inlet bore 38 be controlled. However, this measure is more likely for the embodiment in 3 meaningful.

According to the embodiment 3 the pressure builds up in the valve needle pressure chamber 161 not off because of the connection channel 70 the hydraulic connection to the system pressure with closed inner valve needle 51 maintains. The opening pressure on the printing surfaces 22 . 221 the outer valve needle 52 is thus greater than the closing force acting spring force of the compression spring 63 , The outer valve needle 52 is therefore only by opening the control valve 72 closed by himself in the control room 60 according to the design of the inlet and outlet throttles 39 . 37 sets a pressure, in turn, an additionally closing acting pressure force on the pressure surface 61 builds. The coordination of the inlet and outlet throttles must be selected so that the additional pressure force on the pressure surface 61 added with the pressure force of the compression spring 63 greater than the opening acting pressure forces on the end face of the outer valve needle 52 , If the connection channel 70 No throttling function is included, the pressure in the control room 60 correspondingly high. In addition, arises at the pressure shoulder 66 an opening force on the inner valve needle 51 , This is to be considered in the interpretation of the spring forces, the pressure level and the inlet and outlet throttles, so that the closing or closing of the inner valve needle 51 is secured.

In another driving principle, the outer valve needle 52 not in its closing operation by a driver function of the inner valve needle 51 supported. This is achieved by opening the control valve 72 in the control room 60 according to the design of the inlet and outlet throttles 39 . 37 a pressure, in turn, an additionally closing acting pressure force on the pressure surface 61 builds. The outer valve needle 52 closes when the closing forces are greater than the opening forces. For the closing process of the inner valve needle 51 It is largely irrelevant whether the outer valve needle 52 is still in the closing process or is already closed, so will not be discussed in the following on the already described relationships. To close the inner valve needle 51 becomes the control valve 71 open. Thus, it is preferably system high pressure in the inlet bore 32 at. The pressure in the control room 30 rises to a pressure level according to the vote of the inlet and outlet throttle 33 . 35 at. Correspondingly large is then the closing force acting on the control surface 26 , On all axially acting surfaces of the inner valve needle 51 pressure is on. The pressure in the control room 60 acts by activation of the outer valve needle 52 at the pressure shoulder 66 opening. The inner valve needle 51 begins the closing operation when the sum of the closing pressure acting on the control surface 26 added with the pressure force on the closing surface 28 and the spring force of the compression spring 44 is greater than the sum of the opening pressure acting on the pressure surface 21 . 211 the face 8th added with the pressure force at the pressure shoulder 66 and the spring force of the compression spring 63 , The spring force of the compression spring 63 must in the embodiment in 4 not taken into account, as they have no opening action on the inner valve needle 51 Has. In the embodiment in 1 For all types of actuators where d2> d1, d4 or d6> d3, d5> d4 applies, the spring force of the compression spring must be used 44 greater than the spring force of the compression spring 63 so that both valve needles 51 . 52 are closed at a pressure-free start operation. The greater the difference between the two spring forces in 1 is, the faster the inner valve needle closes 51 , The same applies to the pressure difference in the control rooms 30 . 60 , The greater the pressure difference between control room 30 and control room 60 is, the faster the inner valve needle closes 51 , If the inner valve needle 51 the outer valve needle 52 about the mechanical driver pushes, the same applies as already explained.

To initiate an opening movement of inner valve needle 51 becomes the control valve 71 closed. This causes the control room to run 30 over the first drain hole 34 empty, leaving the pressure in the control room 30 sinks. The at the first printing surface 21 acting pressure force in the opening direction exceeds that at the closing surface 28 acting closing force of the valve needle 5 because d4> d3. This will cause the valve needle 51 from the valve body seat 15 lifted and the injection openings 17 be released. At the valve seat side end face 8th the valve needle 5 increases due to the pressure infiltration the first pressure surface 21 with the diameter d4 on the second pressure surface also acting in the opening direction 211 with the larger diameter d6 ( 3 ). To open the outer valve needle 52 becomes the control valve 72 closed. As a result, the second control room runs 60 over the second drain hole 26 empty, leaving the pressure in the second control room 60 sinks. The at the printing surface 22 acting pressure force in the opening direction exceeds that on the outer valve needle 52 acting closing forces. This will cause the outer valve needle 52 from the valve body seat 15 lifted and the injection openings 171 be released. At the valve seat side end face 81 the valve needle 52 increases due to the pressure infiltration the first pressure surface 22 with the diameter d5 on the likewise acting in the opening direction extended pressure surface 221 with the larger diameter d1.

In a second control principle, as shown in dashed lines, the first control valve 711 the first drain hole 34 and the second control valve 721 the second drain hole 36 assigned. A closing of the inner valve needle 51 and the outer valve needle 52 is in each case by closing the control valves 711 and 721 scored, leaving the control rooms 30 and 60 over the open inlet bores 32 and 38 are supplied with system pressure. To open the valve pins 51 and or 52 becomes the control valve 711 and / or the second control valve 721 open, leaving the control rooms 30 and 60 over the return bores 34 and 36 relieved of pressure. After activating the control valves 71 . 72 corresponds to the pressure in the control rooms 30 . 60 essentially the system pressure, so that the fuel injection valve is substantially pressure balanced and is applied to all axially acting pressure surfaces with the opening of the control valves 71 . 72 the same pressure. The valve pins 51 . 52 close only over the compression springs.

For variations of the control principles, it is particularly advantageous if the first explanatory control principle is used. The inner valve needle closes 51 the outer valve needle 52 with and the remainder of the stroke of the outer valve needle 52 becomes during pressure drop in the valve needle pressure chamber 161 over the compression spring 63 realized. To open, first the inner valve needle 51 activated or the control room 30 relieved. After opening the inner valve needle 51 system pressure is in valve needle pressure chamber 161 at. The opening pressure surface 22 is with the outer valve needle closed 52 much smaller than the printing area 61 , which is why a much lower pressure in the control room 60 sufficient to the outer valve needle 52 to keep closed. Only after closing the control valve 72 opens the outer valve needle 52 , The outer valve needle is closed 52 again over the inner valve needle 51 , Thus, the pressure resistance of the valve body 2 significantly improved. In addition, in the phase in which no injection takes place, the control valve 72 closed. Thus, the control room 60 depressurized, which in turn waiver of a double seat on the outer valve needle 52 allows. In addition, no system pressure is throttled over the throttles in this phase. The driving principle for the inner valve needle 51 is freely selectable.

It is clear from the explanations so far that when d2> d1, d6> d3 and d3> d4 the condition is present that in the opened state of the inner valve needle 51 and unpressurized control room 30 an opening force on the inner valve needle 51 acts while closed inner valve needle 51 and also unpressurized control room 30 and closed control valve 72 a closing force on the inner valve needle 51 acts. This can be used eg for a special control principle, namely by opening the inner valve needle 51 over the second control room 60 he follows. It is during the closing process both valve pins 51 . 52 the control room 30 the inner valve needle 51 pressurized by the control valve 71 is open, and he control room 60 is depressurized by the control valve 72 closed is. After closing both valve pins 51 . 52 becomes the control room 30 depressurized, the control valve 71 is closed. To open now the control room 60 for the outer valve needle 52 pressurized by the control valve 72 is opened. The one in the control room 60 prevailing pressure attacks the pressure shoulder 66 the inner valve needle 51 on and the inner valve needle 51 opens while the outer valve needle 52 remains closed. To open the outer valve needle 52 becomes the control room 60 depressurized by the control valve 72 is closed. By combinations (number and order) of pressurizations in the respective control rooms 30 . 60 There are corresponding possibilities for pre-injections and main injections. All possibilities are common, that the two control rooms 30 . 60 be depressurized during the phases where no injection takes place. In addition, d2> d1, d6> d3 and d3> d4 offers the option of one for both control rooms 30 . 60 to use shared 3/3-way valve and thus use only one control valve.

Claims (11)

Fuel injection valve for internal combustion engines with a valve body ( 2 ), in which a coaxial valve needle assembly ( 50 ) with an inner valve needle ( 51 ) and an outer valve needle ( 52 ) is axially displaceably guided, with a within the inner valve needle ( 51 ) formed fuel channel ( 6 ), via which fuel channel ( 6 ) an inner valve needle pressure chamber ( 16 ) Fuel is supplied to which inner valve needle pressure chamber ( 16 ) the inner valve needle ( 51 ) with a valve seat side end face ( 8th ) is assigned, at the one in the opening direction of the valve needle ( 5 ) acting first printing surface ( 21 ) and at least one first inner valve needle seat ( 510 ) is formed, with a further, outer valve needle pressure chamber ( 161 ), which one on the outer valve needle ( 52 ) in the opening direction acting further pressure surface ( 22 ) is exposed, and with a on the outer valve needle ( 52 ) formed further valve seat side end face ( 81 ), at the at least one outer valve needle seat ( 511 . 512 ), wherein the inner valve pin seat ( 510 ) and the outer valve pin seat ( 521 . 522 ) with at least one valve body seat ( 15 ) and thereby form a sealing seat, which the valve needle pressure chambers ( 16 . 161 ) of at least one injection opening ( 17 . 171 ), characterized in that the outer valve pin pressure space ( 161 ) for which the opening of the outer valve needle ( 52 ) controlling printing surfaces ( 22 . 221 ) of the further valve seat-side end face ( 81 ) of the outer valve needle ( 5 ) assigned. Fuel injection valve according to claim 1, characterized in that the outer valve needle ( 52 ) in a valve seat near guide bore ( 13 ) of the valve body ( 2 ) and on a valve seat near guide section ( 19 ) of the inner valve needle ( 51 ) is guided. Fuel injection valve according to claim 1, characterized in that when the inner valve needle ( 51 ) the valve seat near guide section ( 19 ) of the inner valve needle ( 51 ) and the valve needle seat ( 521 ) of the outer valve needle ( 52 ) substantially a hydraulic limit for the inner valve needle pressure chamber ( 16 ) and that when the outer valve needle ( 52 ) the valve seat near guide bore ( 13 ) and the valve seat near guide section ( 19 ) substantially another hydraulic boundary for the inner and outer valve pin pressure space ( 16 . 161 ) train. Fuel injection valve according to claim 1, characterized in that a first control chamber ( 30 ) and a second control room ( 60 ) are provided, that the inner valve needle ( 51 ) the first control room ( 30 ) with a control surface acting in the closing direction ( 26 ) and the outer control room ( 60 ) with an opening pressure shoulder ( 66 ), and that the outer valve needle ( 52 ) the second control room ( 60 ) with a further pressure surface acting in the closing direction ( 61 ) is exposed. Fuel injection valve according to claim 4, characterized in that the second control chamber ( 60 ) within the valve body ( 2 ) between the substantially hydraulically sealing guides of the valve seat remote guide bore ( 11 ) and the valve seat near guide bore ( 13 ) and another guide bore ( 55 ) of the outer valve needle ( 52 ) for the valve seat near the guide section ( 19 ) of the inner valve needle ( 51 ) is trained. Fuel injection valve according to claim 4 or 5, characterized in that the first control chamber ( 30 ) to an inlet bore ( 32 ) and to a drain hole ( 34 ) and the further control room ( 60 ) to another inlet bore ( 38 ) and to another drain hole ( 36 ), wherein the feed bores ( 32 . 38 ) with a high-pressure system and the drainage holes ( 34 . 36 ) is connected to a low pressure return system. Fuel injection valve according to claim 4, 5 or 6, characterized in that the first control chamber ( 30 ) by means of a first control valve ( 71 . 711 ) and the further control room ( 60 ) by means of a second control valve ( 72 . 721 ) is pressure-resistant and pressure relieved. Fuel injection valve according to one of the preceding claims, characterized in that on the outer valve needle ( 52 ) acting in the closing direction closing spring ( 63 ), which within the further control room ( 60 ) is arranged. Fuel injection valve according to one of the preceding claims, characterized in that the inner valve needle ( 51 ) a control sleeve ( 20 ) is assigned to the control sleeve ( 20 ) at least one sealing surface ( 41 ), that the control sleeve ( 20 ) with the sealing surface ( 41 ) the closing room ( 27 ) from the control room ( 30 ) substantially hydraulically separates the control sleeve ( 20 ) within the inner valve needle ( 51 ) in a guide bore ( 25 ) is that the closing room ( 27 ) in the guide bore ( 25 ) is formed, that the closing surface ( 28 ) the diameter d3 of the guide bore ( 25 ), and that the control sleeve ( 20 ) a central bore ( 43 ), which with one end with a first inlet bore ( 31 ) and at the other end with the closing room ( 25 ). Fuel injection valve according to one of the preceding claims, characterized in that that the inner valve needle ( 51 ) a stop surface ( 59 ), which when closing the inner valve needle ( 51 ) as a mechanical driver on the outer valve needle ( 52 ) acts in the closing direction and forms a stroke limitation when opening for the outer valve needle. Fuel injection valve according to one of the preceding claims, characterized in that the inner valve needle ( 51 ) additionally acts in the closing direction closing surface ( 28 ) having a closing space ( 27 ) is exposed and acts on the closing force acting a compressive force.