WO2007014733A1

WO2007014733A1 - Fuel injection system for an internal combustion engine

Info

Publication number: WO2007014733A1
Application number: PCT/EP2006/007559
Authority: WO
Inventors: Andreas Moch; Wolfgang Scheibe
Original assignee: L'orange Gmbh
Priority date: 2005-08-02
Filing date: 2006-07-31
Publication date: 2007-02-08
Also published as: JP5122455B2; DE502006005872D1; KR20080043803A; WO2007014734A1; JP2009503349A; JP4869346B2; KR101358851B1; KR20080045689A; DE102005036780A1; EP1920156B1; ATE513987T1; KR101231701B1; EP1920155B1; EP1920155A1; JP2009503348A; ATE454550T1; EP1920156A1

Abstract

The invention provides a fuel injection system which, with a mechanically simple design and low control expenditure, has a high degree of operational reliability in that a quantity-limiting arrangement, having a quantity-limiting valve and a bypass valve, is arranged upstream of a respective injector, the blocking element of which bypass valve is acted on in the closing direction with a closing force corresponding to the given pressure difference across the quantity-limiting valve, and is to be adjusted in the opening direction by means of an adjustment device whose adjustment force is lower than the closing force which corresponds to the pressure difference generated across the quantity-limiting valve if the injection valve is defective, that is to say in the event of the fuel supply to the respective cylinder combustion space exceeding the maximum control injection quantity.

Description

Fuel injection system for an internal combustion engine

The invention relates to a fuel injection system for an internal combustion engine according to the preamble of claim 1.

Fuel injection systems of the aforementioned type are known from JP 61-138873 Al, in which in a line connection between a high pressure source and an injection injector, a flow limiting valve is provided to the bridging a controlled bypass valve is arranged. The quantity limiting valve comprises a valve piston which is guided tightly in a receiving bore and is displaceable between an inlet-side starting position and an outlet-side blocking position, which is resiliently supported on the inlet-side starting position and which, against the resilient support, moves into its outlet-side blocking position, assumes a stop position. wherein the displacement volume displaced in accordance with the displacement path is supplied to the injection injector and injected into the respective combustion chamber via the injection injector in a measured amount in a predetermined time. Apart from leaks, the volume supplied to the injection injector corresponds to the volume displaced above the valve piston, which volume must be replenished in preparation for a next injection process. For this purpose, the bypass valve is assigned to the Mengenbegrenzungs-, via which the inlet side and the outlet side of the flow control valve is connected after completion of the injection, so that due to the resilient support of the valve piston in the direction of its inlet-side starting position, the displaced stroke volume replenished and the valve piston in his Starting position can be pushed back, so that the valve piston again its starting position for the next injection process ^¬ takes.

In such a design of the fuel injection system is indeed ensured via the flow control valve that only the amount of fuel is available for injection via the fuel injection injector, which is displaced over the valve piston until it reaches its respective outlet end position, possibly its blocking position Has. However, the barrier function achieved in this way is only guaranteed if the fuel supply to the injector remains interrupted via the bypass valve and a corresponding activation, which necessitates corresponding control of the bypass valve, thus requiring further control effort, which must also be appropriately monitored and safeguarded Uncontrolled inflow of fuel to the combustion chamber of a cylinder can lead to the destruction of the internal combustion engine.

Corresponding conditions are also present in a fuel injection system according to DE 102 13 659 A1, despite the fact that in this solution a pressure booster is used, which additionally performs the function of a quantity-limiting valve.

To limit the amount in case of malfunction of the injection injector due to sticking his for the injection process from its closed position to be lifted nozzle needle in an open position, the use of a quantity limiting valve is known from DE 1 601 408, which works with a resiliently supported against the inlet side valve piston, which at inadmissibly high injection volume So, for example, when the nozzle needle snagging differential pressure dependent in a drain-side blocking position is moved and whose the undisturbed injection operation corresponding displacement volume between successive injections via a throttled bypass connection is replenished in each case. In the blocking position, which results when the displacement volume can not be filled up due to eg continuous injection or leakages on the part of the injector, the bypass connection via the valve piston is deactivated.

Furthermore, it is also known from this document to provide an accumulation volume for limiting the quantity in the line connection leading to the injection injector, which maintains a predetermined pressure level during normal operation of the injection injector due to appropriate dimensioning of the inlet and outlet cross sections, but drops below this pressure level, for example during continuous injection , so that by detecting the pressure level via a volumetric flask, a car signal can be triggered. Both solutions work independently of the injection injector control.

Mengenbegrenzungsventile, the Differenzdruckdruckig also work as a check valves, are further known from DE 196 40 085 Cl, with dimensioning of the pressurized total area of its valve piston such that when you start the engine opening the valve piston - release the fuel passage - then takes place, if a pressure applied to a partial surface, which allows a displacement of the valve piston in case of damage to the injection-side closed position against the spring force.

Furthermore, DE 195 48 610 A1 discloses a third-party-controlled valve which limits the volume flow supplied to the downstream injection injector and, in addition, acts as a differential pressure relief valve as well as a check valve via a variable electromagnetic field determined ^¬ return force can be acted upon, so that the operation of the valve can be controlled in dependence on operating parameters of the internal combustion engine. For this purpose, the valve piston used as an anchor is structurally enclosed on the housing side by a magnet coil, wherein the housing consists of amagnetic materials at least in the ^{overlap region} to the magnet coil.

The invention has for its object to design a fuel injection system of the type mentioned in that the bypass valve is active, preferably driven in terms of cycle time, possibly also in terms of flow rate per unit time - ie the flow, the active control but no additional Control effort is blocked in their effects, if the operation of the injection injector is disturbed and fuel to the combustion chamber of the internal combustion engine based on the trouble-free operation of the injection injector in excess, and thus not controlled in a predetermined manner via the injection injector, the combustion chamber is supplied.

According to the invention this is achieved with the features of claim 1, according to which the locking member of the bypass valve in the direction of its blocking position, in particular in its blocking position with a pressure difference between the inlet side and outlet side of the flow limiting valve corresponding closing force is fuel-loaded and the bypass valve is associated with an actuating device, over which the locking member in the opposite direction, ie in the direction of its inlet-side open position, is adjustable. The size of the actuating force to be applied via the actuating device is in this case limited to the closing force caused by the pressure difference during the trouble-free operation of the injection injector. is tuned force that the locking member remains in disturbed Be ^{¬ operation of} the injection injector, and thereby higher pressure differential, in its blocking position, regardless of an attempted adjustment on the adjusting device. The decisive factor for this is that the actuating force to be applied via the adjusting device is smaller than the closing force given in this operating state, which is preferably dependent on flow and throttling by spring force and in the open position of the blocking element and which is smaller than the opening force during normal operation. which can be applied via the adjusting device.

Thus, the blocking position of the locking member is ensured independently of each control for the bypass valve, as soon as the fuel injector to the combustion chamber of the respective cylinder supplied fuel quantity results in the part of the flow limiting valve a pressure difference result, which is above the pressure difference in the regular operation of the internal combustion engine and at a given, trouble-free operation of the injection injector results. Throttling at overcurrents of the locking member remains due to the intended opening of the bypass valve outside the temporal injection range of the supplied via the flow restrictor injection injector without negative impact on the injection pressure, since during the injection phase - due to the time offset - no pressure loss occurs.

With regard to the bypass valve, it is therefore necessary, since the locking position results Differenzentdruckabhängig, based on the conversion to the blocking position no control, but only with respect to the conversion to the open position, with errors in the relevant control can not be relevant to safety, as resulting overpowering ßige injection quantities lead to increased pressure differences, which in turn have independent of any control, a conversion of the locking member of the bypass valve into the blocking position result, and thus a blockage of the fuel supply to the combustion chamber of the respective cylinder.

The amount of pressure difference in trouble-free operation of the injection injector is in the order of the product of the valve piston of the flow limiting valve acting on its initial position spring force and the valve piston surface, so that the response of the bypass valve and thus the flow control valve can be set by design specifications in a simple manner.

The embodiment of the invention also offers the advantage in multi-cylinder internal combustion engines, to dispense with a separate control for the control of the actuator of the bypass valve, if, according to the set firing order of the cylinder, the control for the mass limiting valve of a cylinder associated by-pass valve from the control is derived for the injection injector of another cylinder, is injected into the conditionally caused by the ignition offset of this cylinder in a period in which no injection takes place on the combustion chamber of the cylinder in the line connection to the high pressure source to be addressed in parallel bypass valve.

With regard to the control of the bypass valve proves to be suitable as a setting device for this one magnetic actuator, so that a respective injection injector and driven in response to this by-pass valve with minimal effort in a predetermined dependence, can be controlled and energized, with respect to a magnetic actuator in particular the determination of a limit force alone by the interpretation, and thus without additional effort is possible.

Preferably, within the scope of the invention, a bypass valve is used whose blocking member is overflowed in the direction of adjustment. However, the solution according to the invention is also to be realized with bypass valves, in which the locking member is adjustable transversely to the overflow direction and thus for the adjustment to overcome in the order of magnitude of each given pressure difference corresponding frictional force.

Further details and features of the invention will become apparent from the claims. Furthermore, the invention will be explained below with reference to an embodiment. Show it:

1 is a schematic representation of an internal combustion engine with its fuel injection system,

2 is a schematic sectional view of the lying in the line connection of a high-pressure source to an injection injector quantity limiting valve with associated bypass valve as a quantity limiting arrangement,

3 in turn very schematically in section, an embodiment of the bypass valve,

4 with respect to a quantity limiting valve, which lies in the line connection of the high-pressure source to an injection injector, the valve piston of which the stroke over time during trouble-free operation of the associated injection injector, Position Fig. 5 a of Fig. 2 corresponding schematic Dar ^¬, wherein the drain-side line section opens wetting valve to the receiving bore of the Mengenbegren- and is connected via the flow regulator to the line connection to the Einspritzinjektor, and

Fig. 6 shows a further embodiment of a bypass valve, this works as a slide valve with transversely to the flow direction lying and across its displacement direction Differenzenzdruckabhängig acted upon locking member.

FIG. 1 shows a fuel injection system 2 for an internal combustion engine 1 operating as a diesel engine. The injection takes place, as shown in the figure for a cylinder of the multi-cylinder internal combustion engine, in each case on a combustion chamber 3 via the injection nozzle 12 of a fuel injector 7, which is connected to a line connection 11 in which, starting from a fuel tank 10, a low-pressure Fuel pump 9 and, downstream as a high pressure source, a high-pressure fuel pump 5 are arranged with downstream high-pressure accumulator 6. From the high-pressure accumulator 6 is branched out the supply of the respective cylinders associated Kraftstoffinj sectors 7, wherein each of the injectors 7 is preceded by a respective quantity limiting arrangement 8. The control of the injectors 7 takes place, as indicated schematically, via a control and regulation unit 4.

The quantity limiting arrangement 8, which is indicated only schematically in FIG. 1, is shown in more detail in FIG. 2 and comprises a quantity limiting valve 13 located in the line connection 11 and a bypass arrangement assigned to it, illustrated by a bypass valve 14, which is connected to the Inlet side 17 and the drain side 18 is connected to the Mengenbegrenzungs- valve 13 via line sections 15 and 16. The separate representation of the quantity limiting valve 13 and the bypass valve 14 is a solution lying within the scope of the invention; Of course, the Mengenbegrenzungs- arrangement 8 can also be structurally combined, for example, in a common housing. The quantity limiting valve 13 has a conventional structure with a housing 19, in whose receiving bore 20, a valve piston 21 is guided tightly, which is supported by a spring 22 in the direction of the inlet side 17 and shown in Fig. 2 in its inlet-side stop position as a starting position is.

The illustrated position of the valve piston 21 corresponds to an operating situation in which the force acting on the valve piston 21 by the inlet side actuating force is smaller than the actuating force, which results from the outlet side pending pressure plus the force of the spring 22. If the actuating force acting on the valve piston 21 in the direction of its inlet-side starting position drops to a value which is smaller than the actuating force resulting from the inlet side, the valve piston 21 is displaced in the direction of the outlet side 18 and possibly reaches the stop position on the outlet side receiving housing 19 as a locked position.

The displacement, ie the stroke H of the valve piston 21 between its inlet-side starting position and its drain-side Sperrläge corresponds to a stroke volume which is at least equal to, preferably greater than the maximum injection volume of the injection injector. If the bypass valve 14 is closed, the valve piston 21 is displaced from its initial position according to FIG. 2 during the injection via the injection injector by an adjustment path which leads to a injection volume corresponding stroke volume correlated. If, for example, due to sticking of the nozzle needle of the nozzle 12 of the injection injector 7 in an open position, larger discharge amounts, the volume delimited via the valve piston 21 in its inlet-side starting position depletes the volume and the valve piston 21 displaces into its drainage line due to the pressure drop on the outlet side. tige blocking position, so that - apart from leaks - the further supply of fuel to and via the injection injector 7 is suppressed to the respective combustion chamber 3.

In a corresponding manner, even with trouble-free operation of the injection injector 7 at each injection a displacement of the valve piston 21 in the direction of its drain-side blocking position, with a corresponding pressure difference between inlet side 17 and drain side 18, and the provision of the valve piston 21 to its inlet-side starting position is after Completion of the injection process in that via the bypass valve 14, the outlet side 18 is connected to the inlet side 17, so that the delimited via the valve piston 21 stroke volume replenished and the valve piston 21 can be reset by the spring 22 back to its inlet-side starting position.

The bypass valve 14 must thus - in trouble-free operation - in the respective interval between successive injections of a respective Einspritzinjektors 7, bridging the flow restrictor 13, a connection between the inlet side 17 and the drain side 18 at least for a period unlock, but otherwise keep this connection closed or interrupt, both during the respective injection operations as well as in the cases in which an uncontrolled supply of fuel via the injection injector to the combustion chamber as a result of a Operational disturbance, for example, the sticking of the nozzle needle of the nozzle of the injection injector, takes place. For this purpose, in the context of the invention, the bypass valve 14 with a locking member 23, preferably in the form of a valve body 24, which is acted upon in the direction of its locking position with the pressure difference between inlet side 17 and discharge side 18 of the flow control valve 13 and the only for adjusting in his Open position via a controlled adjusting device 25 is adjustable, wherein the adjusting device 25 is designed with respect to the applied about it force, that although an adjustment of the valve body 24 in its open position at differential pressures is possible, as they occur with trouble-free operation of the injection injector with corresponding injection volumes, but not in overlying differential pressures, as they adjust, for example, in a snagging of the nozzle needle of the injector injector with appropriate continuous injection.

The resulting in such circumstances pressure differences have the consequence that the formed by the valve body 24 and flowed in the direction of locking member 23 due to the limited force of the actuator 25 can not be adjusted in an open position in the passage of fuel through the bypass valve 14 is possible, regardless of whether the actuator 25 is addressed in the sense of actuation of the locking member 23 or not.

Such a function can be realized in a particularly simple manner via an adjusting device 25 in the form of a magnetic actuator 26. A preferred construction for such a bypass valve 14 is shown in Fig. 3, in which the line sections 15 and 16 terminate in end pieces 27, 28, which are connected via a clamping connection 29 sealingly. In the embodiment of FIG. 3, the drain-side, the line 16 associated end piece 28 is formed as a receptacle for the valve body 24 and has a corresponding bore 30 which is widened in diameter to the cross section of the line section 16. The end piece 28 thus forms a bore receptacle, and in the bore 30 of the valve body 24 is guided, wherein the bore in the flow direction 31 terminates on a seat surface 32 for the valve cone 33 of the valve body 24. The valve cone 33 is in turn connected to a shaft part of the valve body 24, which forms the armature 34 of the magnetic actuator 26 formed as a hollow shaft. In the region of the magnet armature 34 embodied as a hollow shaft, the valve body 24 flows centrally, in the region of the valve cone 33 overflowing, so that in the open position of the valve body 34 there is a flow, preferably a slightly restricted flow, through which the valve body optionally in addition to the spring 46 is loaded in the direction of its locking position due to the throttling differential pressure dependent. The valve cone 33 and the end piece 28 in its receiving the bore 30 forming and overlapping the coil 35 of the magnetic actuator 26 lying region 45 are formed of non-magnetic material.

In the closed position of the valve body 24, the latter is arranged at a predetermined travel distance from the end face of the end piece 27 partially overlapping the bore 30, so that the end piece 27 forms with its end face a stop limit for the valve body 24 in the opening direction. The tensioning device 29 is realized for example by hat-like clamping sleeves 36, 37, the radial Paragraphs of the end pieces 27, 28 overlap, wherein in the shaft portion of the clamping sleeve 36, in a radial recess thereof, the coil 35 of the magnetic actuator 26 is housed, so that there is a very compact design.

Fig. 2 shows, only schematically indicated, the magnetic actuator 26 with its control line 38, wherein, according to the described function of the Kraftstoffein- injection system and the associated Mengenbegrenzungs- arrangement 8 energization of the magnetic actuator 26 is required only to open the bypass connection. The bypass connection may and must be opened between successive injection intervals of the injection injector. A corresponding activation can take place via the control and regulating device 4 assigned to the internal combustion engine 1. According to the invention, the ignition offset between the individual cylinders of the internal combustion engine used for multicylinder internal combustion engines is used to control the bypass valve 14 or its magnetic actuator 26 such that the bypass valve 14 located in the line connection to a cylinder depends on the current flow of the cylinder Injection injector of another cylinder is energized, to which the injection takes place in the interval between two injections of the cylinder, in the supply of the controlled bypass valve 26 is located. Schematically, this is indicated in FIG. 1 by the fact that a control line 40 is branched off from the control line 39 for a cylinder, not shown here, which is connected to the quantity limiting arrangement 8 for the injection injector 7 of the illustrated cylinder.

The operation in this regard is illustrated schematically in FIG. 4, in which the stroke of the valve piston 21 of a quantity-limiting valve 13 with respect to time is compared with reference to FIG. the following injections of a cylinder ^{zugeordne ¬} injection injector is shown. The respective stroke for the valve piston 21 of a quantity-limiting valve 13, which lies in the line connection to an injection injector 7 that injects into a cylinder of the internal combustion engine 1, is removed. The energization time of this injection injector, hereinafter referred to as the first injection injector, is denoted by Tl.

In conjunction with the amount of fuel flowing out during the injection and the resulting pressure difference, there is a displacement of the valve piston 21 in the direction of its outlet-side blocking position, but this is not achieved in the case of trouble-free operation of the injection injector. The corresponding trouble-free injection stroke is removed with 41. The stroke position of the valve piston 21 thus achieved is essentially maintained until the bypass valve 14 opens, so that as a result of the reduction in the pressure difference, the valve piston 21 returns to its supply-side starting position. The corresponding stroke is removed at 42. The curves 43 and 44 indicate that the valve piston 21 due to leakage during the injection (curve 43) as well as in the interval between two successive injections on the same cylinder (curve 44) moves slightly in its stroke position. The provision of the valve piston 21 to its inlet-side starting position according to the section 42 of the lift curve is due to the opening of the bypass valve 14th

For the bypass valve 14, the energization duration is indicated at T2 in FIG. 4, wherein the energization duration T2 of the bypass valve 14, as already explained, preferably the injection time of a second, to another cylinder of the combustion Engine injection injector injector corresponds, so that, undisturbed operation of the internal combustion engine assumes, essentially equal to Bestromungsinter- valle Tl and T2 result.

Overall, a fuel injection system is thus designed by the invention to the effect that with a simple mechanical design and low control effort high reliability is guaranteed.

2, the drain-side line section 16 of the bypass valve 14 is connected to the bore 30 of the flow control valve so that even in those cases in which the working as a 2/2 valve bypass valve 14 can not be switched and possibly remains stuck in its open position, a shut-off of the discharge side 18 is to be achieved against the fuel injector 7, if over the fuel injector an unregulated outflow of fuel should take place on the respective combustion chamber. The displacement of the valve piston 21 to its blocking position is to be achieved in such a case on the pressure difference, which results due to the throttle function when overflow of the bypass valve 14. The throttle function leads to the establishment of a pressure difference between the inlet-side side of the piston 21 and its expiration-side application.

In Fig. 6, another embodiment of a bypass valve, now designated 50, illustrated. This bypass valve 50 comprises a slide 51 which is overflowed transversely to the direction of adjustment, wherein the overflow direction is again illustrated by the arrow 31. In the illustration, the slide 51 assumes its blocking position, the adjusting device 52 is again used as a magnetic position. direction illustrated. The slider 51 is provided with an overflow opening 53, which is indicated by dashed lines.

The situation shown corresponds to a closed position of the bypass valve 50, and at a pressure difference between upstream side and downstream side of the slide 51 is subjected to force transversely to its direction of adjustment, resulting in the slide 51 to be intercepted shear forces corresponding frictional forces against the slide housing 54. The conditional by such pressure differences supporting forces between the slider 51 and the housing 54 are illustrated as transverse forces to the direction of adjustment of the slider by the arrows 55.

From pressure differences, for example in the case of excessive leaks, when the injector gets stuck in its spray position or the like, transverse loads on the slide 51 and the magnitude of the pressure differences result in corresponding support forces (arrows 55) from which an adjustment of the slide 51 results in counteracting frictional forces. To overcome these frictional forces, as to overcome the pressure differences, appropriate restoring forces are required.

Is a corresponding power supply, as provided by the invention, limited, so the pressure differences corresponding to such pressure differences for adjusting the slide 51 can not be covered, with the result that the slide 51, analogous to the valve body 24, remains in its blocking position, if in case of disturbances the available power supply is exceeded.

The adjusting device 52 is preferably also embodied here as a magnetic adjusting device, which in the present case is expediently designed as a linear adjusting device, which allows adjustment of the slider 51 to opposite sides.

Claims

claims

A fuel injection system for an internal combustion engine, comprising a high-pressure fuel source, an injection injector associated with a combustion chamber of a cylinder of the internal combustion engine, with a in a line connection of the high-pressure source to Einspritz injector quantitative limit arrangement, comprising a flow control valve and a bypass arrangement thereto, and with in a receiving bore the quantity limiting valve tightly guided valve piston which is displaceable between a feed side starting position and an outlet-side blocking position as a stop position, which is resiliently supported on the inlet-side starting position and whose adjustment between the starting position and the blocking position corresponds to a stroke volume which is equal to or greater than the maximum injection volume of the injector, which adjusts a pressure difference in operation between the inlet side and the outlet side of the flow control valve and wherein the bypass arrangement to the quantity limit ungsventil whose inlet side and the outlet side connects and in the bypass arrangement designed as a shut-off flow valve bypass valve, which has a locking member which is adjustable between a blocking position and a passage position via an adjusting device, characterized in that the bypass valve (14) outside the time range of Injection of the downstream fuel injection injector (7) via the actuating device (25) is open and that the locking member (23) of the Bypassventi- les (14) toward its locking position, in particular in its blocking position with the pressure difference between feed side (17) and discharge side (18) of the flow control valve (13) corresponding closing force fuel applied and in the opposite direction via the adjusting device (25) is adjustable and that the maximum actuating force of the actuating device (25) is smaller by a predetermined amount than the closing force, the results in a disturbed operation of the fuel injector (7) occurring pressure difference.

2. Fuel injection system according to claim 1, characterized in that the actuating force of the actuating device (25) by a safety threshold is greater than the closing force, which is located in trouble-free operation of the fuel injector (7) and in the closed position valve body (24) Bypass valves (14) on the valve body (24) acting pressure difference corresponds.

3. Fuel injection system according to claim 1 or 2, characterized in that the valve body (24) is spring-loaded in the direction of its closing position.

4. Fuel injection system according to claim 1, characterized in that the valve body (24) of the valve (14) is loaded in its open position with a flow-related force in the direction of its closed position.

5. Fuel injection system according to claim 3 or 4, characterized in that during trouble-free operation of the injection injector (7) on the valve piston (21) of the flow control valve (13) given pressure difference in the order of the valve piston (21) acts in the direction of its initial position acting spring force.

6. Fuel injection system according to claim 1, characterized in that the adjusting device (25) of the bypass valve (14) is designed as an electrically operated adjusting device.

7. Fuel injection system according to claim 6, characterized in that the adjusting device (25) of the bypass valve (14) is designed as a magnetic adjusting device.

8. Fuel injection system according to claim 7, characterized in that the bypass valve (14) as a blocking member (23) in the flow direction aufzubehand- on its locking position hit, sealingly guided in a bore (30) valve body (24), in the overlap area to an exciter coil (35) enclosing the bore receiving means forms a magnet armature (34), wherein the Bohrungsaufnähme at least in the region (45) between exciter coil (35) and magnet armature (34) consists of non-magnetic material.

9. Fuel injection system according to claim 8, characterized in that the bore (30) in the direction of flow to a seat surface (32) of the Bohrungsaufnähme expires and the armature (34) carries a seat (32) associated with the valve cone (33), the consists of non-magnetic material.

10. Fuel injection system according to claim 9, characterized in that the magnet armature (34) is designed as a hollow shaft.

11. Fuel injection system according to claim 9 or 10, characterized in that the anchor region of the valve body (24) centrally through ^¬ flows and the valve plug (33) is flowed over the outside.

12. Fuel injection system according to claim 1, characterized in that - in mehrzylindriger training of the internal combustion engine (1) and the combustion chambers (3) of the cylinder respectively according to the firing sequence with a time delay injecting, electrically controlled injection injector (7) - for the bypass valve (14 ) associated with a quantity limiting valve (13) in the line connection (11) to an injection injector (7) injecting the combustion chamber (3) of a first cylinder, and one for the combustion chamber (3) of a second one delayed in the firing order Cylinder injecting injection injector is provided a control in the same time range.

13. Fuel injection system according to claim 12, characterized in that with the energization of the injecting on the second cylinder injection injector (7) is energized the bypass valve (14) of the flow limiting valve (13) connected in the line connection (11) for injecting the first cylinder injection injector (7).

14. Fuel injection system according to claim 13, characterized in that a common energization of the injecting the second cylinder injection valve (17) and the bypass valve (14) is provided, which the mass limiting valve (13) of the assigned to the first cylinder injection injector (7).

15. Fuel injection system according to claim 1, characterized in that the valve body (24) of the bypass valve (14) is overflowed in its direction of adjustment.

16. Fuel injection system according to claim 1, characterized in that the valve body (slide 51) of the bypass valve (50) is overflowed transversely to its direction of adjustment.

17. The fuel injection injector according to claim 1, characterized in that the bypass valve (14) terminates at the outlet side on the receiving bore of the quantity limiting valve (13) in a region which, via the valve piston (21) against the AbIaufVerbindung to the fuel injector (7 ) can be shut off.