DE102006013704A1 - Fuel injector, e.g. for a motor vehicle, has an injector body, a jet body and an actuator for operating a needle-shaped injection valve element - Google Patents

Abstract

A first buncher space (72) activates an injection valve element (92). An actuator (20) fits in an injector body (12) in a pressure chamber (18) affected by systems pressure. A fuel injector (10) has a pressure intensifier (26). So as to reverse the direction of force/effect, the actuator is assigned a primary (28)/secondary (30) piston system.

Description

was standing of the technique

EP 0 995 901 A1 refers to a fuel injector. The fuel injector includes a fuel inlet through which high pressure fuel flows to the fuel injector. Further, an outlet is provided on the fuel injector and a volume provided between the inlet and the outlet. Within this volume, a piezoelectric actuator is incorporated, which acts on a control piston, via the vertical movement of the fuel pressure is influenced within a control chamber. The out EP 0 995 901 A1 known fuel injector is relatively long-building, which is not least due to the formation of the actuator as a piezoelectric actuator in the form of a stack of a plurality of stacked piezocrystals.

DE 103 33 427 B3 refers to a fuel injector. The fuel injection device comprises an injection valve which has a valve needle for opening and closing injection openings. The fuel injector is supplied with high pressure fuel via a line during operation. In the fuel injector, an actuator is further provided as well as a hydraulic coupler having two cooperating with a coupler volume of the coupler, linearly arranged one behind the other piston. The coupler volume is filled via guide gaps of the pistons lying one behind the other, using fuel under high pressure. At the ends of the pistons facing away from the actuator, there is in each case a filling space, which is connected to the line carrying high-pressure fuel. Furthermore, one of the two pistons arranged one behind the other with a cross-sectional area is connected to the actuator via a rod, while the other of the two pistons guided behind one another has a cross-sectional area which is fixedly connected via a rod to a cross-sectional area of the valve needle which is smaller in cross-sectional area. The two other ends of the pistons engage in associated compartments, which communicate with each other via a channel.

presentation the invention

By the proposed solution according to the invention on a fuel injector having a maximum pressure booster on the one hand implemented a direct needle control and on the other hand when opening the Valve member ensures that one in comparison to the prevailing System pressure, which is applied in a high-pressure accumulator (common rail), a Injection with a significantly higher than the system pressure Maximum pressure level can be realized. As an actuator is following the solution according to the invention a piezoelectric actuator used that builds relatively short compared to the outlined solutions of fuel injectors known in the art are.

With one and the same control valve, optionally formed on the push rod-shaped extension may be a pressure relief of the preferably needle-shaped Injection valve member directly controlling the first control room as well a pressure relief of the highest pressure transmission realizing extreme pressure translator possible. With the proposed solution according to the invention can be over the Realization at a pressure stage on a primary piston / secondary piston unit a dynamic force balance with respect to that designed as a piezoelectric actuator Bring actuator, so that the pressure load of the actuator formed as a piezoelectric actuator within a fuel under system pressure Cavity remains limited.

In a first embodiment acts on an end face of the pressure-bar-shaped on the control valve body Approach a first control room on this side of a damper disc, the a damper hole for making a hydraulic connection between said first Control room and one beyond the damper disc trained second control room for direct control of the needle-shaped Injection valve member is used. In a further embodiment the direct control of the preferably needle-shaped Injection valve member from a first control chamber, which through the aforementioned Primärkolben- / secondary piston unit is charged. Dependent from a difference in diameter between the outer diameter of the primary piston and the outside diameter of the secondary piston and the hydraulically effective diameter of the preferably needle-shaped Injection valve member, can be over the Primary piston / secondary piston unit one pressure ratio realize that regardless of the over the highest pressure translator successful translation the system pressure to a much higher pressure level is achieved, with which the fuel injected into the combustion chamber becomes.

The inventively proposed fuel injector allows a direct needle control over which a translation is achieved depending on the diameter differences of the primary piston, secondary piston and injection valve member already in connection with the direct needle control; regardless of this achieved in the context of the direct needle control translation can by the highest pressure ratio, the pressure level, with which the injection is carried out to pressures beyond 2500 bar. However, this maximum pressure level exists only in the components of the fuel injector which are located downstream of a compression space of the high-pressure intensifier in the injector. The preferably designed as a piezoelectric actuator is not exposed to this pressure level, but is acted upon in the region facing away from the injection openings of the fuel injector only with system pressure.

drawing

Based the drawing is the inventively proposed fuel injector described in more detail below.

It shows:

1 A first embodiment variant of the inventively proposed fuel injector with primary piston / secondary piston unit and high pressure intensifier, which are actuated simultaneously via a control valve.

2 an embodiment of the in 1 illustrated fuel injector, in which a pressure stage is not executed on the control valve body, but this upstream of the primary piston / secondary piston unit,

3 a further embodiment variant of the inventively proposed fuel injector, in which a direct control of the injection valve member via a control chamber, which is acted upon by a Primärkolben- / secondary piston unit,

4 an embodiment of the inventively proposed fuel injector with a direct control of the needle-shaped injection valve member with a pressure stage on the control valve body and

5 an embodiment of the present invention proposed fuel injector with a system pressure applied to the primary piston / secondary piston unit.

variants

The representation according to 1 is a first embodiment of the present invention proposed fuel injector with primary piston / secondary piston unit and maximum pressure translator to remove, the needle-shaped injection valve member is directly controlled.

An in 1 sectioned fuel injector 10 includes an injector body 12 and a nozzle body 14 , In the injector body 12 of the fuel injector 10 opens a high-pressure inlet 16 , at which there is fuel under system pressure. The fuel is in an in 1 not shown high-pressure storage space (common rail) of a high-pressure accumulator injection system and generates a high-pressure inlet 16 on the injector body 12 connectable high pressure supply line fed to the fuel injector. From the high pressure inlet 16 the fuel under system pressure flows into a pressure chamber 18 inside the injector body 12 is trained. Within the pressure chamber, an actuator is arranged, which preferably as a piezoelectric actuator 20 is executed. The actor 20 comprises a number of piezocrystals, which are arranged one above the other in the form of a stack. They are connections 22 provided over which the actor 20 loaded and unloaded. The one in the pressure room 18 recorded actor 20 is about a spring 24 , which is preferably designed as a tube spring biased.

The fuel injector proposed in the embodiment of the invention 10 according to 1 illustrated actuator 20 is operated non-inversely. This means that the actor 20 over the connections 22 in the closed state of the preferred needle-shaped injection valve member 92 uncharged, ie is de-energized. Only to open the preferably needle-shaped injection valve member is formed as a piezoelectric actuator of the fuel injector 10 charged, ie energized.

Because the actor 20 is driven non-inverse, by means of a translation, the effect of the actuator 20 with respect to the needle-shaped injection valve member 92 vice versa.

Below the actuator preferably designed as a piezoelectric actuator 20 there is a pressure intensifier 26 , The pressure intensifier 26 includes a primary piston 28 and a guided in this secondary piston 30 , Between the primary piston 28 and the secondary piston 30 is a piston spring 32 arranged, which is the primary piston 28 against the secondary piston 30 biases. At the secondary piston 30 is a control valve body 36 a control valve 34 educated. The control valve body 36 juts into a hydraulic room 70 in the injector body 12 is trained, into it. At the periphery of the control valve body 36 is at least one flow channel 38 formed in the form of a bevel over which fuel in the hydraulic space 70 can flow in. Below one on the control valve body 36 trained seat 40 runs a leak oil line 42 , about which control quantities in the low-pressure region of the fuel injector 10 be derived.

Below the seat 40 at the control valve body 36 extends a pressure rod-shaped component 44 whose front side has a first control room 72 limited.

In the injector body 12 of the fuel injector 10 is also a high-pressure translator 46 arranged. The high-pressure translator 46 includes a piston 52 who has a first frontal 50 and a second end face 62 has and from a passageway 48 is traversed. The high-pressure translator 46 is via a high pressure translator control room 54 controlled, in which a piston spring 56 is included, which is the piston 52 applied. The filling of the high-pressure intensifier control chamber 54 via a piston 52 trained inlet throttle 58 wherein the high pressure translator control room 54 over a first channel 66 with one above the hydraulic space 70 lying space in the injector body 12 hydraulically communicating. The one in the piston 52 trained passageway 48 is via a filling valve 60 secured, which a flow connection between the first end face 50 and the second end face 62 of the piston 52 closes. About the filling valve 60 becomes one below the second end face 62 in the injector body 12 executed compression space 64 filled with fuel. When operating the high pressure intensifier 46 by a pressure relief of the high-pressure intensifier control chamber 54 closes the filling valve 60 the passageway 48 , so in the compression room 64 Maximum pressure can be built up.

From the compression room 64 below the second end face 62 of the piston 52 extends a second channel 68 to the nozzle room 108 in the nozzle body 14 is trained. The nozzle room 108 of the nozzle body 14 is through a damper disk 78 separated from the injector body. The nozzle body 14 and the injector body 12 are by means of a damper disc 78 enclosing nozzle retaining nut 90 fastened together. Above the damper disc 78 is located in the injector body 12 a cavity into which the second channel 68 , the compression room 64 branches off, flows. Within this cavity are a first control chamber sleeve 74 that the first control room 72 limited as well as a first control chamber sleeve 74 Preloading spring element 76 added. The control chamber sleeve 74 is at an upper plan side of the damper disc 78 hired, leaving the first control room 72 through the front of the push-rod-shaped approach 44 of the control valve body 36 , the first control chamber sleeve 74 and the top plan side of the damper disc 78 is limited. In the damper disc 78 is a damper hole 80 formed as well as at least one a fuel passage to the nozzle chamber 108 enabling drilling 82 , The first control room 72 stands over the damper bore 80 with a second control room 84 hydraulically connected. The second control room 84 is formed by a preferably needle-shaped injection valve member 92 trained end face and a second control chamber sleeve 86 that has another spring element 88 biased, limited. The second control chamber sleeve 86 as well as this acting on further spring element 88 are in the nozzle room 108 of the nozzle body 14 arranged, as well as the preferably needle-shaped injection valve member 92 , Below a covenant, on which the further spring element 88 for biasing the second control chamber sleeve 86 supported, is located on the circumference of the preferably needle-shaped injection valve member 92 at least one polished section 94 , which provides a flow connection between the nozzle space 108 and one the injection valve member 92 represents at the combustion chamber end enclosing annular gap. The injection valve member 92 includes a seat at its top 96 and closes when the injection valve member 92 in the seat 96 is set, at least one injection opening at the combustion chamber end of the nozzle body 14 ,

While the diameter of the control valve body 36 above the at least one flow channel 38 is denoted by d ₁ , the control valve body 36 below the at least one flow channel 38 , in the area in which it is enclosed by the hydraulic space, a reduced diameter d ₂ on. The diameter d _{2 also} represents the diameter in which a pressure stage 100 at the control valve body 36 above the seat 40 is executed. With regard to the high-pressure translator 46 It should be noted that the diameter of the piston above the high pressure intensifier control chamber 54 Denoted by d ₃ and the diameter of the piston 52 below the high pressure translator control room 54 in the area of the second end face 62 of the piston 52 is denoted by d ₄ . The direct control of the preferably needle-shaped injection valve member 92 realized therefore a translation, which is given by the diameter ratio d ₁ / d ₂ , while the high-pressure translator 46 realized a gear ratio, which is given by the diameter ratio d ₃ / d ₄ . The gear ratios d ₁ / d ₂ and d ₃ / d ₄ substantially correspond to each other.

The functioning of the in 1 illustrated fuel injector 10 Is as follows:
The non-inverse controlled actuator 20 is to open the injection valve member 92 , ie the initiation of the injection process via the connections 22 energized so that a longitudinal extension of the actuator 20 forming piezocrystal stack arises. Due to the linear expansion of the actuator 20 drives the primary piston 28 of the pressure intensifier 26 into a hydraulic room. In this one rises According to the pressure, so the pressure level 100 at the transition between the secondary piston 30 and the portion of the control valve body formed in the diameter d ₁ 36 a retraction of the secondary piston 30 against the action of the piston spring 32 in one of the primary pistons 28 enclosed space causes. This drives with the secondary piston 30 connected control valve body 36 of the control valve 34 from his seat 40 in the injector body. Due to the now open seat 40 in the injector body 12 stand the high pressure intensifier control room 54 over the first channel 66 , the at least one flow channel 38 and the hydraulic room 70 with the leak oil line 42 in conjunction with, at the same time the first control room 72 for direct control of the preferably needle-shaped injection valve member 92 relieved of pressure. Opening the seat 40 thus simultaneously causes a direct control of the preferably needle-shaped injection valve member 92 by pressure relief of the first control room 72 and a pressure increase in the compression chamber which is considerably higher than the system pressure 64 at pressure relief of the high-pressure intensifier control room 54 in the drain line 42 ie the low pressure area of the fuel injector 10 , This solution ensures that at the time when the injection valve member 92 opens, under high pressure fuel over the compression space 64 and the second channel 68 in the nozzle room 108 pending. The fuel flows over the at least one polished section 94 on the circumference of the preferably needle-shaped injection valve member 92 , the annular gap, by opening the seat 96 released injection openings 98 at the combustion chamber end of the nozzle body 14 to.

About the merged primary pistons and secondary pistons 30 becomes a direction of action reversal of the non-inverse controlled piezoelectric actuator 20 achieved, in which when energized while the primary piston 28 is moved downward, however, by this downward movement, a mounting of the secondary piston 30 causes its pressure level 100 lies in a room in which when retracting the primary piston 28 the pressure rises.

The closing of the needle-shaped injection valve member 92 takes place by a cancellation of the energization of the trained as a piezoelectric actuator 20 of the fuel injector 10 , When the current supply to the actuator is canceled 20 this assumes its original longitudinal extent, so that the primary piston 28 of the pressure intensifier 26 out of the room in which the piston 30 the pressure level 100 having. Due to the piston spring 32 becomes the secondary piston 30 including the control valve body formed thereon 36 in his seat 40 in the hydraulic room 70 posed. As a result, the pressure relief of the high-pressure intensifier control chamber 54 with the leak oil line 42 ie to the low pressure area of the fuel injector 10 lifted, leaving the piston 52 of the high pressure translator 46 through the piston spring 56 is placed in its rest position. Because in this process the piston 52 with its second front 62 from the compression room 64 The pressure also drops and drops back to the system pressure level. With the retraction of the control valve body 36 in the injector body 12 in the area of the hydraulic space 70 executed seat 40 also moves the front side of the pressure rod-shaped neck 44 in the first control room 72 and increases the pressure there. The pressure increase in the first control room 72 gets over in the damper disc 78 trained damper hole 80 in the second control room 84 transfer. The end face of the preferably needle-shaped injection valve member 92 moves in the closing direction of the injection valve member 92 and put this in his seat 96 so that the at least one on this body 14 at the combustion chamber end formed injection opening 98 is closed.

The pressure level 100 causes in the 1 illustrated embodiment of the present invention proposed fuel injector 10 that on the actuator 20 acting forces are dynamically balanced.

The representation according to 2 is a further embodiment of the inventively proposed fuel injector can be seen.

The structure of the high pressure intensifier 46 , the nozzle body 14 and the first control room 72 and the second control room 84 are analogous to the corresponding components as shown in FIG 1 obtain.

Unlike in 1 illustrated embodiment is the primary piston 28 of the pressure intensifier 26 from a transverse bore 102 traversed. From the transverse bore branches a connecting channel 106 off into one in the primary piston 28 formed cavity opens, in which the piston spring 32 is included. The piston spring 32 acts on the secondary piston 30 of the pressure intensifier 26 , Furthermore, in the embodiment according to 2 between a pressure space below the primary piston 28 and the hydraulic room 70 in the injector body 12 an overflow channel 104 which hydraulically connects the two said hydraulic spaces.

In contrast to the representation according to 1 is the pressure level 100 in the embodiment according to 2 on the actuator side, so that even in this embodiment of the actuator dynamically balanced force and only in the pressure chamber 18 over the high pressure inlet arising system pressure is exposed.

Also according to the in 2 illustrated embodiment, the actuator 20 non-inverse driven. When energizing the actuator 20 over the connections 22 the actor stretches 20 resulting in a downward movement of the primary piston 28 leads. The primary piston 28 moves with its front side into a hydraulic space, in which the secondary piston 30 of the pressure intensifier 26 is included. Due to the pressure increase in this hydraulic space when retracting the primary piston 28 the secondary piston moves 30 in the opening direction against the action of the piston spring 32 as well as in the cavity of the primary piston 28 over the channels 102 and 106 pending system pressure. When driving up the secondary piston 30 leaves the control valve body 36 his seat 40 so the first channel 66 with the leak oil line 42 to the low pressure area of the fuel injector 10 contact. Further, when opening the seat 40 also the overflow channel 104 into the hydraulic room 70 opens, with the drain line 42 connected.

Also according to the in 2 illustrated embodiment of the present invention proposed fuel injector 10 will when opening the seat 40 the pressure in the first control room 72 lowered, which is a direct control of the injection valve member 92 in the opening direction has the consequence because of the damper bore 80 at pressure reduction in the first control room 72 also the preferred needle-shaped injection valve member 92 acting second control room 84 undergoes a pressure relief, so that the injection valve member 92 from his seat 96 is moved and the combustion chamber end of the nozzle body 14 engineered injection ports 98 releases. At the same time, when you open the seat 40 a pressure relief of the high-pressure intensifier control chamber 54 brought about, so that the pressure in the compression space 64 of the high pressure translator 46 increases dramatically and this high pressure level above the second channel, which is significantly higher than the system pressure 68 also in the nozzle room 108 is transferred, so that when opening the injection ports 98 at a Auffahrbewegung of the needle-shaped injection valve member 92 this highest pressure level at the injection openings 98 is present and an injection process of fuel takes place.

Is the current to the actuator 20 over the connections 22 on the other hand, the actor picks up 20 its original length and the primary piston 28 moves upwards in a vertical direction. Due to the operation of the primary piston / secondary piston assembly 28 . 30 of the pressure intensifier 26 , the secondary piston closes 30 and the control valve body 36 moves into its seat. This is the pressure relief of the high-pressure intensifier control room 54 in the drain line 42 interrupted, so that the piston 52 through the piston spring 56 is returned to its rest position, resulting in a pressure drop in the compression chamber 64 leads. At the same time increases due to the retraction of the front side of the rod-shaped projection 44 at the control valve body 36 the pressure in the first control room 72 at. Pressure increase in the first control room 72 is via the damper hole 80 in the second control room 84 transferred so that the injection valve member 92 in his combustion chamber side seat 96 is placed and at the combustion chamber end of the nozzle body 14 trained injection ports 98 be closed again.

The representation according to 3 is a compact constructive embodiment of the present invention proposed fuel injector refer.

The in 3 illustrated fuel injector 10 includes the injector body 12 and the nozzle body 14 , Between the nozzle body 14 and the injector body 12 However, is not according to the embodiments in the 1 and 2 provided damper disc 78 intended. The actor 20 is operated non-inversely and is over the connections 22 supplied with current. About the high pressure inlet 16 Under system pressure, fuel flows into the pressure chamber 18 of the injector body 12 , This is preferred as a piezoelectric actuator 20 trained actuator acts directly on the primary piston 28 of the pressure intensifier 26 one, wherein in the cavity of the primary piston 28 the the secondary piston 30 acting piston spring 32 is included. The under system pressure fuel comes out of the pressure chamber 18 over the cross hole 102 and the overflow channel 104 in this cavity and acts on the secondary piston 30 in which in the embodiment according to 3 the preferred needle-shaped injection valve member 92 is trained. The primary piston 28 in turn, it forms the control valve body 36 of the control valve 34 , In the injector body 12 is the hydraulic room 70 formed, a closing seat 40 for the control valve body 36 forms. Above the closing seat 40 branches from the hydraulic room 70 the leak oil line 42 starting with the low pressure area of the fuel injector 10 as shown in 3 hydraulically connected.

The face of the primary piston 28 protrudes in the embodiment according to 3 in the first control room 72 that of one by means of the spring element 76 acted upon first control chamber sleeve 74 and the upper plan side of the nozzle body 14 is limited. In the nozzle body 14 is the nozzle space 108 formed over the second channel 68 with fuel from the compression chamber 64 is charged.

The preferably needle-shaped injection valve member 92 works with the one at the combustion chamber end of the nozzle body 14 executed seat 96 together, below which at least one injection opening 98 opens into the combustion chamber of the internal combustion engine.

Analogous to the embodiments according to the 1 and 2 is the high pressure translator 46 provided, the first end face 50 is subjected to system pressure level, which on the piston 52 acts. The high-pressure translator 46 is by a pressure relief of the high-pressure intensifier control room 54 in which the piston spring 56 is arranged, actuated. By the piston 52 the passageway extends 48 passing through the filling valve 60 is closed. The pressure relief of the high-pressure intensifier control chamber 54 done by opening the closing seat 40 , causing the hydraulic space 70 with the leak oil line 42 in the low pressure region of the fuel injector 10 is connected.

The functioning of in 3 illustrated embodiment of the fuel injector 10 is the following: Is the non-inverse controlled actuator 20 energized, drives the primary piston 28 due to the linear expansion of the actuator 20 in the first control room 72 one. Due to the pressure increase in the first control room 72 the secondary piston moves 30 with needle-shaped injection valve member formed thereon 93 in the opening direction, so that the tip of the injection valve member 92 from her seat 96 extends and the injection ports 98 at the combustion chamber end of the nozzle body 14 releases. Simultaneously with the achieved in this way direct control of the needle-shaped injection valve member 92 becomes the high pressure translator room 54 over the first channel 66 the opened lock seat 40 and the hydraulic room 70 with the leak oil line 42 connected so that acted upon by system pressure first end face 50 of the piston 52 a retraction movement of the second end face 62 in the compression room 64 performs. The in the compression room 64 prevailing pressure is thereby increased significantly above system pressure level, so that in this way increased pressure level in the nozzle chamber 108 in the nozzle body 14 pending. Because the injection openings 98 at the combustion chamber end of the nozzle body 14 stand open, under high pressure fuel is injected into the combustion chamber of the internal combustion engine.

The diameter of the primary piston below the closing seat 40 is denoted by d ₅ , while the diameter of the injection valve member 92 is denoted by d ₆ and the diameter of the associated with this secondary piston 30 is denoted by d ₇ .

That with the direct control of the injection valve member 92 achievable gear ratio is

For completeness, it should be mentioned that the piston 52 of the high pressure translator 46 with a passageway 48 is provided by means of the filling valve 60 is closed. The filling valve 60 prevents during the compression process of the control piston 52 an escape of fuel from the compression chamber 64 and thus makes it possible to increase the pressure level in the compression chamber 64 over the system pressure level.

If the injection process is terminated, then the energization of the actuator 20 lifted, so that this assumes its original length again. The primary piston 28 gets out of the first control room 72 withdrawn and the closing seat 40 through the control valve body 36 locked. Due to the pressure reduction in the first control room 72 and through the cavity of the primary piston 28 acting system pressure and the action of the piston spring 32 becomes the secondary piston 30 including needle-shaped injection valve member 92 in the seat 96 driven so that the at least one opening into the combustion chamber of the internal combustion engine injection port 98 is closed.

The representation according to 4 is a further embodiment of the inventively proposed Kraftstoffinjektors refer to, which is actuated by means of a non-inverse energized actuator.

4 shows the fuel injector as shown in FIG 1 , concerning the high pressure translator 46 , the first control room 72 , the second control room 84 analogous to the embodiment of the in 1 illustrated fuel injector 10 is constructed.

Also according to the in 4 illustrated embodiment of the fuel injector 10 located on the secondary piston 30 of the pressure intensifier 26 the control valve body 36 of the control valve 34 , Due to the direction of action reversal of the actuator 20 through the primary piston / secondary piston unit 28 . 30 of the pressure intensifier 26 is when the actuator is energized 20 during downward movement of the primary piston 28 due to the elongation of the actuator 20 the secondary piston 30 mounted and the control valve body 36 from his seat 40 in the injector body 12 emotional. The open seat 40 causes a pressure relief of the high pressure intensifier control chamber 54 of the high pressure translator 46 over the first channel 66 , the hydraulic room 70 with the leak oil line 42 and at the same time a pressure release tion of the first control room 72 for direct actuation of the injection needle member, which is also preferably needle-shaped here 92 , About that from his seat 96 moving injection valve member 92 becomes under increased, above the system pressure pressure level standing fuel from the compression chamber 64 over the second channel 68 and the hole 82 in the nozzle chamber 108 inflowing fuel over the at least one polished section 94 in the periphery of the needle-shaped injection valve member 92 via the now open, at least one injection opening 98 injected into the combustion chamber of the internal combustion engine.

mit d₅ Durchmesser des Primärkolbens 28, d₇ Durchmesser des Sekundärkolbens 30, d₁ Durchmesser des Steuerventilkörpers 36 oberhalb des Sitzes 40.The operated by way of direct control, preferably needle-shaped injection valve member 92 is operated with a translation resulting from the diameter ratio of d ₈ to d ₆ . d ₈ denotes the diameter of the rod-shaped projection 44 at the control valve body 36 , d ₆ the diameter of the preferably needle-shaped injection valve member 92 , At the pressure intensifier 26 The resulting translation results from the following relationship:

with d ₅ diameter of the primary piston 28 , d ₇ diameter of the secondary piston 30 , d ₁ diameter of the control valve body 36 above the seat 40 ,

5 shows an embodiment of the fuel injector, which essentially according to the embodiment of the fuel injector according to 2 equivalent.

Also according to this embodiment, the fuel injector comprises 10 two, via a damper hole 82 in a damper disc 78 hydraulically interconnected control rooms 72 respectively. 84 , Also, the fuel injector according to the embodiment in 5 includes a high pressure intensifier 46 , above which in the compression room 64 a considerably higher than that at the high-pressure inlet 16 system pressure is reached for the injection. Also in this embodiment, the actuator 20 on the one hand via the preferably designed as a tube spring spring 24 biased and is driven non-inverse. About the primary piston / secondary piston unit 28 . 30 occurs when the actuator is energized 20 and actuation of the primary piston 28 due to the linear expansion of the actuator 20 a mounting of the secondary piston 30 and thus a pressure relief in the first control room 72 , Simultaneously with the downward movement of the primary piston 28 becomes the control valve body formed on this 46 from the seat 40 driven, so the first channel 66 the hydraulic room 70 the leak in this opening 42 to the low pressure area of the fuel injector 10 and the high pressure translator control room 54 Hydraulically interconnects and print load. Due to the pressure relief of the high-pressure intensifier control chamber 54 will be in the compression room 64 contained fuel compressed and via the second channel 68 and at least one bore 82 in the damper disc 78 in the nozzle chamber 108 diverted. Because of the pressure relief of the first control room 72 and the corresponding pressure relief of the second control chamber 84 the injection valve member 92 from the seat 96 is moved, can under high pressure fuel over the now open, at least one injection port 98 be injected into the combustion chamber of the internal combustion engine.

Claims (13)

Fuel injector ( 10 ) with an injector body ( 12 ) and a nozzle body ( 14 ), with an actuator ( 20 ) for actuating a needle-shaped injection valve member ( 92 ) via at least one first control room ( 72 ), wherein the actuator ( 20 ) in a pressure chamber subjected to system pressure ( 18 ) in the injector body ( 12 ) and the fuel injector ( 10 ) at least one pressure booster ( 26 ), characterized in that the actuator ( 20 ) a primary piston / secondary piston assembly ( 28 . 30 ) is assigned to the force and action direction reversal, via which a control valve body ( 36 ) of a control valve ( 34 ) at the same time the pressure relief of the at least one first control room ( 72 ) and a high pressure translator ( 46 ). Fuel injector ( 10 ) according to claim 1, characterized in that the primary piston ( 28 ) of the pressure intensifier ( 26 ) upon pressurization of a hydraulic space, the secondary piston ( 30 ). Fuel injector ( 10 ) according to claim 1, characterized in that on the secondary piston ( 30 ) the control valve body ( 36 ) and a push-rod approach ( 44 ) or on the secondary piston ( 30 ) the injection valve member ( 32 ) is trained. Fuel injector ( 10 ) according to claim 1, characterized in that the control valve body ( 36 ) a seat ( 40 ) in a hydraulic room ( 70 ) opens or closes, into which a first channel ( 66 ) of a high pressure translator control room ( 54 ) and from which a leak oil line ( 52 ) to the low pressure area of the fuel injector ( 10 ) branches off. Fuel injector ( 10 ) according to claim 3, characterized in that the approach ( 44 ) with a End face the at least one first control room ( 72 ) limiting the injection valve member ( 92 ) directly controls. Fuel injector ( 10 ) according to claim 1, characterized in that at the primary piston / secondary piston arrangement ( 28 . 30 ) an actuator-side pressure stage ( 100 ) for dynamic force compensation of the actuator ( 20 ) is executed. Fuel injector ( 10 ) according to claim 1, characterized in that the primary piston / secondary piston arrangement ( 28 . 30 ) the injection valve member ( 92 ) with a transmission ratio d ₁ / d ₂ or

or with a gear ratio

actuated, with d ₁ first diameter control valve body ( 46 ), d ₂ second diameter control valve body ( 46 ), d ₅ diameter primary piston ( 28 ), d ₆ diameter injection valve member ( 92 ), d ₇ diameter secondary piston ( 30 ). Fuel injector ( 10 ) according to claim 1, characterized in that the high-pressure translator ( 46 ) a piston ( 52 ), whose first end face ( 50 ) is subjected to system pressure and whose second end face ( 62 ) a compression space ( 64 ) is pressurized, from which a second channel ( 68 ) to a nozzle space ( 108 ) in the nozzle body ( 14 ) runs. Fuel injector ( 10 ) according to claim 8, characterized in that the piston 52 an inlet throttle ( 58 ) for filling the high-pressure intensifier control chamber ( 54 ) having. Fuel injector ( 10 ) according to claim 8, characterized in that the piston ( 52 ) a passageway ( 48 ) for filling the compression space ( 64 ) and in the passageway ( 48 ) a filling valve ( 60 ) is recorded. Fuel injector ( 10 ) according to claim 1, characterized in that the piston ( 52 ) generates a transmission ratio d ₃ / d ₄ , with d ₃ first diameter piston ( 52 ), d ₄ second diameter pistons ( 52 ). Fuel injector ( 10 ) according to claim 6, characterized in that a connecting channel ( 104 ) of the hydraulic space in which the pressure stage ( 100 ) is effective to the hydraulic space ( 70 ) runs. Fuel injector ( 10 ) according to claim 1, characterized in that the primary piston ( 28 ) Channels ( 102 . 106 ), via which a cavity in the primary piston ( 28 ) for receiving a piston spring ( 32 ) flows under system pressure standing fuel.