DE19958704A1 - Actuator movement transference device for motor vehicle common rail fuel injection system - Google Patents

Abstract

A device for transmitting the movement of an actuator (8) onto a positioning element (3) has a transmission module (19-21, 23-28) which establishes an operating connection between the actuator (8) and the positioning element (3) and forms a hydraulic chamber (36) and a storage chamber (31), which are filled with a hydraulic medium and are interconnected via a throttling point (22). The transmission module has first, second and third piston element (21-24), in which the first piston element (24) makes contact with the actuator (8) and the third piston element (23) makes contact with the positioning element (3), and the second piston element (21) is arranged movably between the first and the third piston elements and is acted on by a pressurizing force, so that between the first and second piston elements, is formed the storage element (41) and between the second piston element (21) and the first (23) is formed the hydraulic chamber (36).

Description

The invention relates to a device for transmitting a Movement of an actuator on an actuator according to the Oberbe handle of claim 1 and in particular a fluid doo sier with such a device. Such a master device, hereinafter also referred to as the transmission module known from DE 197 08 304 A1.

Storage is becoming increasingly common in automotive engineering spray systems used in those with very high injection press is working. In such z. B. under the designation "Common Rail Systems" known injection systems Fuel under high pressure arranged in the cylinders Injectors created. The injection process in the Zy Relieved by opening and closing the injection valves triggered, the injectors being controlled by actuators be erected according to the electromagnetic and - um high To achieve switching speeds - even after the piezo electrical principle work. The actuators in injection valves Press len, if necessary with the interposition of a ser voventils, a valve needle in the injection valve.

A transmission module is known from DE 197 08 304 A1, that the deflection of the actuator on a drive stamp of the Servo valve or a guide shaft of the valve needle wearing. The transmission module is essentially cylindrical mig formed and has a hydraulic chamber, which by a flexible membrane is limited. On the flexible mem bran is the drive stamp of the servo valve or the Füh valve stem. Leading from the hydraulic chamber a connecting hole with throttling effect to a memory chamber, which is provided inside the transmission module and is completed by a preloaded spring plate.  

The hydraulic chamber and the storage chamber are with a hy draulic medium filled. Over the spring plate in the Spei cherkammer is a rigid cover plate arranged on Injector actuator is present.

In the idle state, the in the Storage chamber prevailing pressure of the hydraulic medium transferred to the hydraulic chamber so that the flexible mem bran always on the drive stamp of the servo valve or on the guide valve stem is in contact, even if due to thermal effects or aging processes shifts in the arrangement of the individual components in the injection valve surrender. When the actuator is actuated, the deflection this actuator via the transmission module essentially un changed to the drive stamp of the servo valve or the Transfer the guide shaft of the valve needle. The connection bore between the hydraulic chamber and the storage chamber is designed for this so that due to the range of Actuation times in milliseconds are essentially none hydraulic medium from the hydraulic chamber into the accumulator chamber can drain.

The transmission module known from DE 197 08 304 A1 has however, a complicated structure and requires beyond from a high assembly effort when inserting into the on spray valve. Furthermore, it is with the well-known transfer difficult to compensate for the temperature entire working range of the injection valve from -40 ° C to Ensure + 150 ° C. The highly dynamic switching processes of the injection valve as well as the high, on the hydraulic Medium acting in the transmission module pressures up to 300 bar also place great demands on printing and printing wear resistance of the transmission module. This applies in particular for injection valves, in which piezo elements act as actuators ren are used. These piezo actuators make it possible fast switching speeds, but have only one ge wrestle stroke, so stroke losses in the transmission of Ak  door movement can lead to the valve needle in the on spray valve no longer opens reliably. In the state of the Technology z. B. from US 4 101 076, are already mecha African lever translator known to the stroke of the piezo actuator to reinforce. However, here is next to the transmission mo an additional lever element for temperature compensation required, whereby the manufacturing and assembly wall enlarged considerably.

The object of the present invention is a device for transmitting a movement of an actuator to an actuator and a fluid metering device with such a device to deliver, which is also due to its great reliability high continuous loads and extreme operating conditions draw and also easy to set up and manufacture can be.

This object is achieved by a device according to claim 1 and a fluid dispenser according to claim 10 solved.

According to the invention, the transmission module has three piston elements arranged one on the other, being between a first col. in contact with an actuator benelement and a second central piston element Storage chamber and between the second middle piston element ment and a third are in contact with an actuator located piston element formed a hydraulic chamber are, the storage chamber with the hydraulic chamber over one throttle is connected and the second one re piston element movable and with a pressure-effective force acts between the first and the third piston element ment is arranged. This structure reliably does one automatic compensation even with large length changes in the Fluid metering device between the piezo actuator and the actuator, caused by thermal, printing or setting effects can be. This arrangement can also be used  Make the transmission module compact, so that a simple Assembly of the transmission module is guaranteed.

According to a preferred embodiment, by suitable Choice of the size ratio of the active surfaces of the second middle piston and the third, in contact with the Actuating piston a stroke translation of the Ak door movement on the actuator. This will make him is enough that even when using a piezo element as an actuator generates a sufficient stroke for actuating the actuator becomes.

According to a further preferred embodiment, the second middle piston over metal bellows between the two outer piston hung. The use of metal bellows has the advantage that when the walls are pressurized of the metal bellows only small changes in force at the ends of the bellows attached to both sides occur. The axial defor The bellows waves are certainly not ge ring, but stand out just like that on the individual Bellows waves acting forces in total over the total length of the metal bellows almost.

According to a further preferred embodiment, one is the metal bellows on which the second middle piston is suspended is biased so that the second middle piston with egg ner corresponding pressure-effective force is applied. This configuration enables a particularly simple and compact design of the transmission module.

Further advantageous embodiments of the invention are in the dependent claims.

The invention is explained in more detail below with reference to the drawings explained. Show it  

Fig. 1, a fuel injection valve with a fiction, modern transmission module; and

Fig. 2 is an enlarged view of the transmission module according to the invention.

In the injection valve shown schematically in Fig. 1, a drive unit is installed in an upper part of a housing 1 , which has a piezoelectric rule multilayer actuator 8 in low voltage technology as an essential component. This piezoelectric multilayer actuator 8 is surrounded by a tubular spring 9 , which is welded between a head plate 10 and a base plate 11 , the tubular spring 9 being pretensioned such that the piezoelectric multilayer actuator 8 is under a mechanical compressive prestress. The housing 1 of a injection valve is as rigid as possible with the base plate 11 of the drive unit, preferably via a weld seam 12 , a related party.

The piezoelectric multilayer actuator 8 acts when it is controlled elec trically via its feed lines 32 , via a transmission module on the rear end of a valve needle 3 . The valve needle 3 is arranged in the front part of the housing 1 of the injection valve and closes in the basic state with a valve plate 4 arranged at the front end of the valve needle 3 , a valve seat 2 on the housing 1 . The closed ge state of the injection nozzle formed by the valve seat 2 and the valve plate 4 in the injection valve is thereby ensured by a preloaded nozzle spring 5 which is connected to the valve needle 3 via a snap ring 6 . When the piezoelectric Mul tilayeraktors 8 is actuated, the deflection transmitted by the transmission module to the rear end of the valve needle 3 lifts the valve plate 4 from the valve seat 2 , so that fuel that is fed into a fuel chamber 13 in the housing 1 via a fuel supply line 7 , past the valve needle 3 into a combustion chamber of an internal combustion engine.

The injection valve shown in FIG. 1 is operated with a fuel pressure of up to approximately 500 bar. The area in the housing 1 of the injection valve, in particular the fuel chamber 13 , in which this high pressure is present, must therefore be sealed reliably from the other areas in the housing 1 of the injection valve, in particular by the drive area in which, for example, ambient pressure prevails his. For hermetically sealed and axially very soft implementation of the valve needle 3 from the fuel chamber 13 in a pressureless, air-filled space 14 in which the drive unit is installed with the transmission module, a connecting ring 16 is used , which is arranged adjacent to the fuel chamber 13 . The connecting ring 16 is firmly welded to the housing 1 of the injection valve or can also be machined out of the housing 1 . At the rear end of the valve needle 3 , an annular connector 17 is also attached. Between the connecting piece 17 at the rear end of the valve needle 3 and the connecting ring 16 on the housing 1 , a cylindrical metal bellows 15 is welded in, which hermetically seals the fuel chamber 13 against the unpressurized, air-filled space 14 in which the drive unit and the transmission module are located , serves.

The needle bushing consisting of the metal bellows 15 , the connecting piece 16 and the connection ring 17 is preferably manufactured as an independent module and then welded to the housing 1 or the valve needle 3 , respectively. The injection valve is typically assembled in the following order:

First, the valve needle 3 is inserted into the housing 1 and biased with the nozzle spring 5 over the snap ring 6 . Since, according to the needle bushing of the metal bellows 15, the connector 16 and the connector ring is ben introduced scho to the valve needle 3 around as an independent module in the housing 1 17, is seated on a cross-section recess 18 in the housing 1 to the connecting ring 17th Subsequently, the connector 16 is welded tightly to the housing 1 and the connecting ring 17 with the valve needle 3 .

The use of the metal bellows 15 in the needle bushing enables a perfect, permanent and reliable sealing of the high pressure area in the injection valve from the drive area. As calculations and tests have shown, the metal bellows 15 withstands very high pressures despite its small wall thicknesses of, for example, 50 to 500 μm, due to its high radial rigidity, without being irreversibly deformed. The metal bellows 15 can also be designed so that a high mechanical resilience, ie low spring rate in the direction of movement of the valve needle 3 is achieved by a sufficient number of shafts, so as not to affect the deflection of the valve needle 3 and the temperature-related changes in length of the To keep the needle passage into the valve needle 3 as low as possible. Furthermore, fuel leakage can be prevented with high reliability by using the metal bellows 15 in the needle bushing.

The needle bushing can also be designed such that the pressure-related forces acting on the valve needle 3 compensate each other, so that the valve needle 3 is kept pressure-free overall. For this purpose, the hydraulically effective diameter of the bellows connection is selected so that it corresponds exactly to the diameter of the valve seat 2 . This ensures that the pressure forces released by the pressurized fuel on the valve needle 3 with the valve plate 4 and the pressure-induced forces introduced by the metal bellows 15 into the valve needle 3 compensate each other and thus no resulting pressure force component on the valve needle 3 works. This ensures that the injection valve shows a switching behavior that is almost independent of fuel pressure, since the opening and closing forces are determined solely by the piezoelectric multilayer actuator 8 and the force of the prestressed nozzle spring 5 .

The metal bellows 15 also has a wide working temperature range with constant functionality due to its metallic material. Thermal changes in the length of the metal bellows 15 themselves, due to the low axial spring constant of the metal bellows 15, result in only negligible changes in force on the valve needle 3 in the axial direction. The metal bellows 15 can also partially or completely replace the nozzle spring 5 due to its mechanical spring action in the axial direction.

In order to transmit the extremely short stroke of the piezoelectric multilayer actuator 8 to the valve needle 3 , the transmission element is provided between the drive unit and the valve needle 3 as a stroke translator. Furthermore, the transmission module serves as a hydraulic compensation element to rule out any play between the piezoelectric multilayer actuator 8 and the valve needle 3 . The transmission module, which is shown in FIG. 2 in an enlarged view, consists of a mounting ring 19 , a perforated plate 20 , a primary piston 21 with a throttle point 22 , a secondary piston 23 , a plunger 24 and three metal bellows 25 , 26 and 27 . The transmission module is so arranged between the drive unit with the piezoelectric multilayer actuator 8 and the valve needle 3 that the stamp 24 of the transmission module rests on the top plate 10 of the drive unit and the secondary piston 23 is in contact with the rear end of the valve needle 3 .

The primary piston 21 of the transmission module is preferably cup-shaped, the throttle point 22 being arranged centrally in a bottom surface 211 . The stamp 24 of the transmission module engages with a foot part 241 in the pot-shaped primary piston 21 , the stamp 24 being held by the first metal bellows 25, which is welded between a head part 242 of the stamp 24 and the bottom surface 211 of the primary piston 21 . Here, a storage chamber 31 is formed between the bottom surface 211 of the primary piston 21 and an end face on the foot part 241 on the plunger 24 .

The primary piston 21 is also held by the second metal bellows 26 on the block-shaped perforated plate 20 , the metal bellows 26 being welded between a flange 212 at the upper edge of the primary piston 21 and an upper end face 201 of the perforated plate 20 . The mounting ring 19 is arranged in the inner bore of the perforated plate 20 adjacent to a lower end face 202 and carries via the third tall tall bellows 27 the disk-shaped secondary piston 23 , which is essentially on one level with the upper end face 201 of the perforated plate 20 . The third metal bellows 27 is firmly welded to the mounting ring 19 and the two sides of the secondary piston 23 . Between the primary piston 21 and the secondary piston 23 , a Hydraulikkam mer 36 is formed, which is connected via the throttle point 22 to the storage chamber 31 . All elements of the transmission module are welded together in a sealed manner, the resulting interior of the transmission module being completely bubble-free with a hydraulic fluid. The metal bellows 25 , 26 and 27 are still, similar to the tall tallow 15 , designed to withstand sufficient pressure, and ra dial very stiff and axially very soft.

As shown in FIG. 1, a thrust washer 29 is arranged on the flange 212 of the primary piston 21 of the transmission module in the installed state, which surrounds the head part 242 of the plunger 24 and is pressure-loaded with a soft compression spring 28 which is arranged around the tube spring 9 and is supported on the base plate 11 of the drive unit. The bias voltage of the compression spring 28 is transmitted via the pressure plate 29 to the primary piston 21 , so that in the transmission module a constant base pressure acts on the hydraulic fluid in the storage chamber 31 and the hydraulic chamber 36 .

This base pressure causes the plunger 24 of the transmission module to always be held with a small force against the head plate 10 of the drive unit and that the secondary piston 23 rests on the rear end of the valve needle 3 with a small force. The position of the primary piston 21 between the plunger 24 and the secondary piston 23 is set such that the hydraulic chamber 36 , which is formed between the primary piston 21 and the secondary piston 23 , has a height HK of approximately 50 to 1000 μm and that Height HS of the storage chamber 31 , which is formed between the end face of the foot part 241 of the plunger 24 and the bottom surface 211 of the primary piston 21 , is in the range from 50 to 1000 μm.

As shown in FIG. 2, the transmission module is preferably an independent module that is ideally assembled in the following order:

After attaching the needle guide the entire transmission module is a set in the housing 1 of the injection valve, whereby the orifice plate 20 having a weld at the Ge housing is fixed. 1 Then the thrust washer 29 and the compression spring 28 are placed on the flange 212 on the primary piston 21 of the transmission module. Finally, the pre-assembled drive unit from the piezoelectric multi-layer actuator 8 , the top plate 10 , the base plate 11 and the Bourdon tube 9 is pressed into the housing 1 until the compression spring 28 is loaded by the base plate 11 with the desired voltage, so that the Hydraulic fluid in the transmission module is below the desired base pressure. The drive unit is then rigidly and firmly connected to the housing 1 in this position via the weld seam 29 between the base plate 11 . The selected configuration thus enables a particularly simple manufacture and assembly of the transmission module in the injection valve.

The injection valve with the transmission module works like follows:

To initiate the injection process, the piezoelectric multilayer actuator 8 is charged via the electrical leads 32 . This causes the piezoelectric multilayer actuator 8 to deflect and press on the head part 241 of the stamp 24 with high force via the head plate 10 . In the transmission module, the throttle point 22 in the primary piston 21 is further dimensioned such that during the typical control times of the piezoelectric multilayer actuator 8 from 1 to 5 ms, only a negligible exchange of hydraulic fluid between the storage chamber 31 and the hydraulic chamber 36 can take place. This means that the volume of the storage chamber 31 during the injection time can be regarded as in compressible.

Since the metal bellows 25 , which is arranged between the plunger 24 and the primary piston 21 , is designed to be radially very rigid and, as explained, only a little hydraulic fluid can flow out of the storage chamber 31 via the throttle point 22 , the one triggered by the piezoelectric multi-layer actuator 8 is transmitted Movement of the plunger 24 directly onto the primary piston 21 . The movement of the primary piston 21 increases the pressure in the hydraulic chamber 36 between the primary piston 21 and the secondary piston 23 . If the resulting force on the secondary piston 23 exceeds the restoring force of the nozzle spring 5 , the valve needle 3 is pressed down by the secondary piston 23 so that the Ven tilteller 4 lifts off the valve seat 2 and the injection valve opens.

The deflection of the piezoelectric multilayer actuator 8 is translated according to the ratio of the pressure-effective areas of the primary piston 21 and the secondary piston 23 in the hydraulic chamber 36 in a stroke of the valve needle 3 . The primary piston surface acts from the inner diameter of the connection to the metal bellows 26 circular area of the primary piston 21st The secondary piston surface, on the other hand, is determined by the outer diameter of the connection of the metal bellows 27 . By suitable coordination of the primary piston surface to the secondary piston surface, a suitable transmission ratio of the stroke of the piezoelectric multilayer actuator 8 can be set in relation to the stroke of the valve needle 3 . This can reliably ensure that the extremely short stroke of the piezoelectric multilayer actuator 8 is sufficient in all operating conditions of the injector to open the valve needle 3 Ven.

The injection process is ended by the piezoelectric multilayer actuator 8 being discharged again via the electrical feed lines 32 . This shortens the piezoelectric multilayer actuator 8 to its initial length, the Rohrfe of 9 prevents the piezo-ceramic due to inertia effects when contracting under tension. By the restoring force of the nozzle spring 5 , the valve needle 3 is brought back into its closed position, in which the Ventiltel ler 4 sits on the valve seat 2 . Furthermore, the secondary piston 23 of the transmission module is pushed back into its starting position by the rear end of the valve needle 3 , as a result of which the pressure in the hydraulic chamber 36 increases. Since the volume of the hydraulic chamber 36 is almost incom pressible and the throttle point 22 is dimensioned such that the rapid pressure increase in the hydraulic chamber 36 cannot be reduced by the outflow of hydraulic fluid through the throttle selsel 22 in the storage chamber 31 , the pressure increase on the primary piston 21 passed so that it moves upward against the biasing force of the compression spring 28 . This causes an increase in pressure in the storage chamber 31 , as a result of which the stamp 24 is moved in the direction of the base plate 10 on the piezoelectric multilayer actuator 8 until it comes into contact with it.

The inventive design of the transmission module it is still possible to automatically switch all thermal or caused by setting effects of the drive unit or pressure-related changes in length in the injection valve by the Compensate transmission module. The transmission module be Length compensation works in the following way:

Z. B. due to the thermal expansion of the housing 1 of the injection valve, the distance between the upper end of the valve needle 3 and the head plate 10 , the pressure in the storage chamber 31 drops compared to the pressure in the hy draulic chamber 36 . The value of the pressure difference depends on the speed of the change in distance between the upper end of the valve needle 3 , the head plate 10 and the dimensioning of the throttle point 22 .

The pressure drop in the storage chamber 31 is limited and can be a maximum of the value hydraulic pressure minus ambient pressure. The hydraulic pressure is essentially determined by the prestressing force of the compression spring 28 and the pressure-effective surface of the metal bellows 26 .

Furthermore, the throttle point 22 in the primary piston 21 is laid out in such a way that during the thermal processes, which lie in the time range from a few seconds to minutes, hy draulic liquid can be exchanged via the throttle point 22 between the hy draulic chamber 36 and the storage chamber 31 . The hydraulic fluid then flows as long as the hydraulic chamber 36 via the orifice 22 into the SpeI cherkammer 31, sets up the hydraulic pressure in the storage chamber 31 and the pressure difference disappears. Then the full pressure force between the punch 24 and the head plate 10 is reached again.

When overflowing, the height of the hydraulic chamber 36 decreases while the height of the storage chamber 31 increases, so that the stamp 24 is moved upwards in the direction of the drive unit until the head part 242 of the stamp 24 rests against the head plate 10 .

Assuming that the pressure-effective area of the plunger 24 , which is determined by the pressure-effective diameter of the metal bellows 25 , A _A , the pressure-effective area of the primary piston A _P and the pressure-effective area of the secondary piston A _S , the following relationships result for the Compensation paths from punch 24 , primary piston 21 and secondary piston 23 :

As a first case, it is considered that the position of the secondary piston 23 remains unchanged and that there is a length compensation between the primary piston 21 and the plunger 24 . Assuming that the x-axis points upwards in the direction of the injection valve

-A _P dx _P = A _A d _HS
dx _A = dx _P + d _HS
dx _P = -dx _A A _A / (A _P -A _A )

in which

x _P = position of the primary piston;
dx _P = change in the position of the primary piston;
HS = height of the storage volume;
d _HS = change in the amount of the storage volume;
x _A = position of the compensating piston;
dx _A = change in the position of the compensating piston.

From the above equations it follows that it for a length compensation between the primary piston 21 and the plunger 24 is necessary for the effec tive in the storage chamber 31 primary piston surface is larger than the pressure effective in the storage chamber 31 face of the punch 24th Assuming that the pressure-effective primary piston surface corresponds to the double th stamp pressure surface, a minimum hy draulic chamber height HS of 50 μm is sufficient to compensate for a change in length between the primary piston 21 and the stamp 24 of 50 μm.

As a second case, a thermal elongation should be considered, in which the stamp 24 remains unchanged and a length compensation between the primary piston and the secondary piston should take place. The following applies here:

-A _P dx _P = -A _A dx _P - A _S dx _S
dx _P = dx _S A _S / (A _P + A _A )

in which

x _S = position of the secondary piston;
dx _S = change in the position of the secondary piston.

Assuming that the pressure-effective area of the primary piston 21 in the hydraulic chamber 36 is twice the size of the pressure-effective area of the secondary piston 23 , a length change of 50 µm can be compensated for with a hydraulic chamber height of 50 μm.

For a reliable function of the transmission module according to the invention, in particular a hermetic seal of the hydraulic fluid in the transmission module with respect to the fuel chamber or the drive part, in particular the use of the metal bellows 25 , 26 , 27 between the plunger 24 , the primary piston 21 , the perforated plate 20 and the secondary piston 23 is advantageous. For such metal bellows, simulation calculations or tests have shown that the bellows walls fixed at their ends with several waves hardly change their volume when subjected to fluid pressure. E.g. at a pressure of 200 bar and a metal bellows geometry with twelve shafts, an inner diameter of 3.5 mm, an outer diameter of 5.3 mm, a wall thickness of 100 µm and a wall length of 12.1 mm, a volume enclosed by the bellows wall of Set approx. 169.963 mm ³ compared to a volume of 169.386 mm ³ when depressurized. This corresponds to a volume increase of only 0.581 mm ³ due to the pressurization. Assuming that the hydraulic fluid is incompressible, there is an apparent compressibility of the hydraulic medium of 0.1715 / GP _A. This apparent compressibility is extremely low. B. compared to a compressibility of diesel fuel under normal conditions of 0.685 / GP _A. This means that the rigidity of a hydraulic transmission module constructed from metal bellows is essentially determined by the volume content of the hydraulic fluid in the transmission module. In order to be able to achieve fast switching operations in the injection valve, it is therefore advantageous to keep the volume of the hydraulic fluid in the transmission module to a minimum.

Furthermore, there is also the possibility of the mechanical spark tion of the compression spring 28, the supply module is adjusted by loading of the primary piston 21 to the base pressure of the hydraulic fluid in the Übertra, partially or wholly by spring action of the metal bellows to replace 26th For this purpose, it is neces sary to weld the metal bellows 26 under a corresponding pretension between the primary piston 21 and the perforated plate 20 .

Furthermore, the use of bellows shafts in the metal bellows advantageous, because it has a very small axial spring cone can be set for the metal bellows. The axial deformation of the metal bellows due to a pressure lining are not at all low, but they stand out precisely like the forces acting on the individual bellows waves in ih sum over the entire length of the metal bellows almost. One has proven to be a particularly favorable form for the bellows shafts from, viewed in longitudinal section joined together semicircle existing geometry proved. Opposite a si nus-shaped wave pattern shows the semicircular segments standing wall lower mechanical stresses in the axial Direction with higher axial compliance.  

According to the invention, a transmission module is provided which has a simple and modular structure and can therefore be easily installed in an injection valve. Furthermore, the stroke of the actuator can be translated in relation to the needle stroke by suitable coordination of the primary piston surface to the secondary piston surface. In addition, the transmission module ensures automatic compensation of changes in length in the injection valve. The use of metal bellows for connecting the individual components of the transmission module and for sealing the storage chamber 31 and the hydraulic chamber 36 ensures a stable hermetic seal of the hydraulic fluid against the fuel chamber 13 and the drive part.

The in the above description, the drawings and the Features of the invention disclosed in claims can be both individually as well as in any combination for the entanglement chung of the invention in its various configurations to be of importance.

Claims (11)

1. Device for transmitting the movement of an actuator ( 8 ) to an actuator ( 3 ) with
a transmission module ( 19 , 20 , 21 , 23 , 24 , 25 , 26 , 27 , 28 ), which establishes an operative connection between the actuator ( 8 ) and the actuator ( 3 ) and a hydraulic chamber ( 36 ) and a storage chamber ( 31 ) specifies that are filled with a hydraulic medium and are connected to each other via a throttle ( 22 ),
characterized in that
the transmission module has a first, a second and a third piston element ( 21 , 23 , 24 ), the first piston element ( 24 ) being in contact with the actuator ( 8 ) and the third piston element ( 23 ) being in contact with the actuator ( 3 ) and the second piston element ( 21 ) is movable and pressurized with a force between the first and third piston element, so that between the first piston element ( 24 ) and the second piston element ( 21 ) the storage chamber ( 31 ) and between the second piston element ( 21 ) and the third piston element ( 23 ) the hydraulic chamber ( 36 ) is formed. 2. Device according to claim 1, characterized in that the stroke which the actuator ( 8 ) generates in the first piston element ( 24 ) of the transmission module from the third piston element ( 23 ) of the transmission module to the actuator ( 3 ) accordingly the ratio of pressure-effective surfaces of the second piston element ( 21 ) and the third piston element ( 23 ) in the hydraulic chamber ( 36 ) is transmitted. 3. Device according to claim 1 or 2, characterized in that the second piston element ( 21 ) is suspended in the transmission module on metal bellows ( 25 , 26 ). 4. The device according to claim 3, characterized in that the metal bellows ( 25 , 26 ) are composed of semicircular segments. 5. The device according to claim 4, characterized in that straight sections are provided between the semicircular segments of the metal bellows ( 25 , 26 ). 6. Device according to one of claims 1 to 5, characterized in that the pressure-effective area of the second piston element ( 21 ) in the storage chamber ( 31 ) is larger than the pressure-effective area of the first piston element ( 24 ) in the storage chamber. 7. Device according to one of claims 1 to 6, characterized in that the second piston element ( 21 ) is pot-shaped, wherein the Dros selstelle ( 22 ) is formed in a bottom surface ( 211 ) that the first piston element ( 24 ) is stamp-shaped and engages with a foot part ( 241 ) in the cup-shaped second piston element ( 21 ), the first piston element ( 24 ) being held by a first metal bellows ( 25 ) which is between the head part ( 242 ) of the first piston element ( 24 ) and the bottom surface ( 211 ) of the second piston element ( 21 ) is arranged, and wherein the second piston element ( 21 ) is held by a second metal bellows ( 26 ) on a perforated plate ( 20 ), and that the third piston element ( 23 ) is disc-shaped and with a third metal bellows ( 27 ) in the perforated plate ( 20 ) is held. 8. The device according to claim 7, characterized in that the second piston element ( 21 ) by a spring element ( 28 ) is pressure-loaded. 9. The device according to claim 7, characterized in that the first metal bellows ( 25 ) or the second metal bellows ( 26 ) is biased. 10. Fluid dispenser with a piezo actuator ( 8 ) and a Ven tilnadel ( 3 ), wherein the movement of the piezo actuator ( 8 ) on the valve needle ( 3 ) is transmitted with a device according to one of claims 1 to 9. 11. Fluid dispenser according to claim 10, with another Me tallbalg ( 15 ) as a feed-through element for the rear end of the valve needle ( 3 ) from a fluid chamber ( 13 ) outwards to the third piston element ( 23 ) of the device for transmitting the movement of the piezo actuator ( 8 ) on the valve needle ( 3 ).