DE10035168A1 - Piezoelectric actuator for e.g. dosing fuel from pressurized source for fuel injection valve, comprises hydraulic fluid which forms electrical passivation layer for actuator stack - Google Patents

Abstract

The piezoelectric actuator comprises an actuator stack with and end side between the cover element and floor element. Hydraulic fluid is provided in the actuator chamber. Hydraulic fluid forms an electrical passivation layer for the actuator stack (24). An Independent claim is included for the corresponding method of manufacture.

Description

The present invention relates to an actuator according to the preamble of claim 1, a method for Manufacture of an actuator and a valve, in particular a metering valve for metering a pressurized Dosierfluids.

Actuators and valves of the type mentioned work for example with the help of piezo actuators. piezo actuators can be used as monolithic ceramic multilayer components be trained and win in modern electrical engineering more and more important.

Piezoceramic multi-layer actuators usually consist of a plurality of alternating ceramic layers and metallic inner electrodes. Here you can for example, up to 500 individual layers can be provided. To achieve optimal deflection with minimal The internal electrodes must take up the entire space Cross section of the piezo actuator - except for the inactive one Contact zone - include. This means that Internal electrodes of alternating polarity on the side surfaces exposed to multilayer ceramics.

For this reason, an electrical passivation is this Side surfaces unavoidable to prevent electrical flashovers and Short circuits between adjacent internal electrodes too avoid. These can be caused, for example, by moisture (which in the case of ceramic materials on lead zirconate titanate Basis (PZT) can lead to AG migration) or operating materials (e.g. diesel, rapeseed methyl ester or the like) in Operation of the piezo actuator can be caused.  

The passivation process of the piezo actuator is however a very costly process. The passivation is the Multilayer ceramics usually after the external metallization spread by hand with a self-adhesive silicone compound. This silicone elastomer is then made in one Drying cabinet cured at about 150 ° C for about 30 minutes. Then the passivated actuators are under Using the same silicone elastomer with a cylindrical plastic sheath surround what as "Potting" is called.

The selection of suitable passivation plastics designed turn out to be difficult because of a number of Property criteria must be met. First of all the passivation plastics one Have permanent temperature resistance of <150 ° C. Furthermore, they must have good adhesion properties on the Have ceramics. After all, there is one for plastics high elongation at break required to avoid polarity cracks in the To be able to cope with stretching occurring actuator operation.

DE 197 15 487 A1 describes a piezoelectric actuator known that first in a prefabricated hollow profile is introduced. Then the hollow profile with a Passivation layer poured out ("potting"). The Passivation layer inside the hollow profile can for example made of sprayable silicone, which after the Processing hardens, manufactured.

In patent application DE 199 40 055 there is also a Dosing valve for dosing a pressurized Dosing fluids proposed, in which the valve needle over an actuator is actuated, which is a piezo actuator having. This piezo actuator is built into a Bourdon tube, which is required in dynamic operation of the actuator ensures static prestressing of the multilayer ceramic. With this solution, there is still a hydraulic bearing  used, which in the injector, for example by Changes in temperature and pressure, changes in length balance the entire valve needle drive automatically can to ensure a consistently safe function of the Ensure injector. In one embodiment can the actuator Bourdon tube module completely in the hydraulic bearing be integrated.

The present invention has for its object a Actuator of the type mentioned above to train that a performance improvement, a Manufacturing simplification and cost reduction achieved can be. Furthermore, a correspondingly improved Valve and an improved method for producing a such actuator are provided.

This task is solved by the actuator according to Claim 1, the valve according to claim 14, the Method of manufacturing an actuator according to Claim 17 and advantageous uses according to the Claims 15 and 16. Further advantageous features, Aspects and details of the invention result from the dependent claims, the description and the drawings. Advantages and features related to the Actuator described also apply to the Process for its manufacture and the valve. benefits and features related to the process described also apply to the actuator as well the valve. Advantages and features related to the valve are also valid for the Actuator and the process for its manufacture.

According to the first aspect of the invention, an actuator provided, with a piezo actuator that is in one of one Housing limited actuator chamber is arranged, the Piezo actuator has at least one actuator stack and the Actuator stack with its end faces between one Cover element and a bottom element is clamped and  wherein the actuator stack from one in the actuator chamber provided hydraulic fluid is or is washed. The Actuator is characterized in that the hydraulic fluid is one intended for the actuator stack Passivation layer for electrical passivation forms.

A particular advantage of the actuator according to the invention is that the piezo actuator is now without its own Passivation can be operated in the actuator. This leads, among other things, to enormous cost savings. Surprisingly, it was found that when present of the stated installation state of the piezo actuator in the actuator passivation of the piezo actuator, as with all Disadvantages described so far from the prior art is known, can be dispensed with, since this function of the hydraulic fluid is taken over. This results in compared to the solutions known from the prior art a number of advantages.

As already mentioned, so far the first one required costly passivation process now omitted. It is also a much more effective one Dissipation of the heat loss of the piezo actuator via its given direct contact with the hydraulic fluid. The means that the piezo actuator is not as strong during operation heats up, so that the temperature-dependent characteristics of the Actuator are subject to minor fluctuations. Farther is now a harder electrical control of the Piezo actuator can be implemented without the risk of overheating.

The inventive design of the actuator is the mechanical load on the further contact of the Piezo actuator (usually fine wires) through the Hydraulic fluid is extremely low and takes place very homogeneously. At the same time, the hydraulic fluid in the wires is dampened resulting vibrations. The "encapsulation" of the piezo actuator in a liquid can further reduce the Cause working noise of the actuator.  

According to the invention it is thus provided that the Hydraulic fluid one on the surfaces of the Actuator stack provided passivation layer forms. On the However, surfaces of the actuator stack are not separate, solid adhesive passivation layer is provided.

The cover element and / or the base element can be advantageous designed to be displaceable in the longitudinal direction of the piezo actuator his. The longitudinal direction of the piezo actuator corresponds to that Height of the component, which is different from each other Arrange the individual layers to form multilayer ceramics results. The longitudinal direction of the piezo actuator thus corresponds its main stretch direction.

Furthermore, the cover element as a in the longitudinal direction of the Piezoactuating hydraulic pistons can be formed.

The hydraulic piston can be advantageous with the housing Form hydraulic chamber, the hydraulic chamber with the Actuator chamber for the exchange of hydraulic fluid is fluidly connected.

An embodiment of the as described above Actuator is for example in the above Patent application DE 199 40 055 described, the Insofar as disclosed in the description of the present invention is incorporated. With this solution the piezo actuator is located in an actuator space, with an in Longitudinal direction, which is the main direction of elongation corresponds to the piezo actuator acting hydraulic piston Piezo actuator supported on one side. The hydraulic piston forms together with the housing a hydraulic chamber, which with the actuator space via a fluidic connection, in this case a fit between hydraulic piston and Housing, is hydraulically connected to each other.  

Furthermore, a compensation chamber can be used with the hydraulic piston hydraulic connection. The actuator space, the Hydraulic chamber and the compensation chamber are with one under Pressurized hydraulic fluid filled, so that System hydraulic chamber compensation room actuator room Hydraulic fluid is a dynamically rigid bearing for the Piezo actuator and a length compensation element for time forms longer processes.

In a further embodiment, the actuator stack can be used for generation a bias within a hollow cylindrical Be arranged spring element. Such a solution is for example in that of the applicant DE 198 18 068 A1 described, the In this respect, disclosure content in the description of the present invention is incorporated. That in it described spring element is designed as a hollow cylinder, the openings of an actuator base and an actuator cover Are completed. The actuator base and the actuator cover are preferably cylindrical. The spring element encloses an actuator stack inserted therein and in it introduced electrical connections. The actuator stack is with its end faces between the actuator cover and the Actuator floor clamped flat and is in by the spring element Longitudinally biased against expansion.

Preferably, the spring element can have a number of Have recesses over the surface of the spring element are distributed. The number, size and that Arrangement pattern of the recesses over the area of the The spring element determines its spring stiffness. To the others allow the recesses that the Hydraulic fluid unhindered by the spring element can pass through and reach the actuator stack in order to to rinse it to passivate it.  

The hydraulic fluid used in the actuator can for example for use in a temperature interval of -40 ° C to + 150 ° C can be used.

The hydraulic fluid can preferably be a Trade silicone oil. Here are long-chain ones in particular Silicone oils, for example polydimethylsiloxanes and the like beneficial in addition to their chemical inertness are also known for their good electrical Isolation properties, or high electrical Dielectric strengths. It is particularly advantageous if the silicone oil is filled in bubble-free in the basic state.

In a further embodiment, the actuator stack can be within a hollow profile can be arranged. With such a Hollow profile is, for example "Potting jacket" as described in DE 197 15 487 A1 is the disclosure content in this respect in the description of the present invention.

Such a cylindrical encapsulation of the piezo actuator can in addition to the measures described above take place, which for example handling advantages with Assembly of piezo actuator and hollow cylindrical spring element can bring with it. The hollow profile must be such be designed so that the located in the actuator space Hydraulic fluid pass through this and to the Surfaces of the piezo actuator can reach, so that on the Hydraulic fluid the required electrical Passivation of the piezo actuator is achieved. In one However, the case can - in comparison to that in DE 197 15 487 A1 described solution -, a much cheaper Potting compound with lower temperature resistance and Elongation at break and poorer adhesive properties from the Ceramics can be selected.

The piezo actuator can preferably have one or more Have contact elements, for fixing the  Contact elements a corresponding number of adapter sleeves is provided in the housing and / or the cover element and / or the base element and / or the hollow cylindrical one Spring element is / are provided.

The actuator stack can, for example, consist of at least two Ceramic layers and at least one between two adjacent ceramic layers arranged electrode layer be educated. It therefore consists of an alternating one Sequence of one ceramic layer, one Electrode layer, one in turn adjoining it Ceramic layer etc.

The invention is not limited to any number of Individual layers, or ceramic layers and Electrode layers limited because the number of each required layers depending on the embodiment of the ceramic multilayer component results.

The at least one ceramic layer can advantageously be on Lead zirconate titanate base (PZT), lead zinc niobate titanate (PZN- PT), lead magnesium niobate titanate (PMN-PT) or the like be trained. The at least one electrode layer can preferably have a substance from the group Copper, nickel, palladium, platinum, gold and / or silver is selected.

In a special embodiment, the actuator stack has a ceramic layer which has a lead zirconate titanate (PZT, PbZr _X Ti _1-X O ₃ ). An electrode layer in particular has a substance that is selected from the group consisting of palladium and / or silver. An alloy of the substances mentioned with a ratio of palladium to silver of 30:70 is particularly advantageous.

According to a second aspect of the invention, a valve, in particular a metering valve for metering one under pressure standing metering fluids, provided with a valve chamber  and a valve housing for receiving a valve needle, and an inventive as described above Actuator, the valve needle with the actuator is connected and is or can be moved via the latter.

Such a valve is, for example, in the patent application DE 199 40 055 proposed, the disclosure content in With regard to the design of the valve in the Description of the present invention.

Such a valve can be advantageous as Fuel injection valve for an internal combustion engine be used. Likewise, one as above described inventive actuator preferably for Controlling a valve needle of a fuel injector can be used for an internal combustion engine.

According to a further aspect of the invention, a method for producing an actuator, in particular an actuator according to the invention as described above, is provided, which has the following steps:

• a) One consisting of at least one actuator stack Piezo actuator is in one of one without passivation Housing limited actuator chamber inserted and between clamped a cover element and a base element;
• b) The actuator chamber is filled with a hydraulic fluid, so that the hydraulic fluid flows around the actuator stack and thereby one intended for the actuator stack Passivation layer for electrical passivation forms.

The piezo actuator is inserted into the actuator chamber without passivation used. In the presence of an appropriate one Hydraulic fluids can passivate such Piezo actuator can also be dispensed with, as this function of the Hydraulic fluid is taken over.

Advantageously, the piezo actuator can first be passed in without passivation a hollow cylindrical spring element, for example one  Bourdon tube, used to preload the Generate actuator stack. The piezo actuator spring element unit can then according to step a) in the actuator chamber be used.

This will be explained using an example. First the actuator is directly in without passivation and encapsulation the hollow cylindrical spring element, for example a Bourdon tube, used. Fixing the contact pins of the Piezo actuator can be fitted with electrically insulating adapter sleeves take place in corresponding pin bushings of the Base plate of the Bourdon tube can be used. The fixation can also by the connector of the electrical Supply is done. Centering the piezo actuator or the actuator stack can be via suitable Centering, for example laterally through the Recesses of the spring element inserted centering grippers, respectively. Inserting the piezo actuator into the hollow cylindrical spring element can for example have a appropriate guide sleeve. By such Guide sleeve can also fix the contact pins of the Piezo actuator and the centering of the piezo actuator or the actuator stack within the hollow cylindrical spring element are adopted.

In a further embodiment, the piezo actuator can be without Passivation is first introduced into a hollow profile, the hollow profile piezo actuator unit then in the Actuator space or the hollow cylindrical spring element used becomes.

If the piezo actuator without passivation, but with one Potting jacket, provided, in the actuator space, or that hollow cylindrical spring element is used, the Fixing the contact elements of the actuator and the Centering the piezo actuator, or the Actuator stack, done through the potting jacket.  

Are the side surfaces of the piezo actuator during the Insertion process into the hollow cylindrical spring element, for example during a corresponding Welding process, contamination by arising Exposed to welding fumes, a corresponding Suction device, a welding process in an oil bath, or the like can be provided.

The invention will now be explained in more detail using an exemplary embodiment with reference to the accompanying drawings. Here, 1 is the only Fig. A metering valve with a piezoelectric actuator, a valve needle and a hydraulic damping system, wherein a hydraulic chamber is connected to the actuator chamber.

In the single Fig. 1 in a sectional view a side view of a metering valve 10 is shown as an injection valve for fuel in an internal combustion engine.

The valve 10 initially consists of an actuator 20 and a valve element 50 .

The valve element 50 has a valve housing 51 in which a valve needle 52 is slidably arranged. A valve seat 54 is incorporated into the valve housing 51 and , together with the valve disk 53 located at the lower end of the valve needle 52, forms a poppet valve. The valve needle 52 is connected via a suitable connection, in the present case a welded connection, to a base element 26 which is movably arranged in an actuator chamber 22 of the actuator 20 .

Furthermore, a prestressed return spring 31 is provided, which keeps the poppet valve closed with a restoring force in the initial state of the valve 10 . The return spring 31 is supported on a housing 21 of the actuator and on the base element 26 .

A part of the valve needle 52 is surrounded by a valve chamber 55 , which is formed by the valve needle 52 and the valve housing 51 . The valve chamber 55 can be pressurized by means of a fluid or fuel supply 56 and is hydraulically connected to the poppet valve, so that when the poppet valve is open, i.e. when the valve disk 53 is lifted from the valve seat 54 , a fluid flow flows from the valve chamber to the poppet valve and the fluid flows through the poppet valve is delivered outside.

The valve chamber 55 is hermetically sealed from the actuator chamber 22 by a seal that is flexible in the direction of displacement of the valve needle 52 , here a corresponding metal bellows 57 .

The actuator 20 initially has the actuator chamber 22 , which is delimited by a housing 21 . A piezo actuator 23 is provided within the actuator chamber 22 and is formed by one or more actuator stacks 24 , each actuator stack 24 in turn being formed from a number of alternating ceramic and electrode layers.

The piezoelectric actuator 23 is clamped with its end faces 39 between the bottom member 26 and a lid member 25th

In order to achieve a corresponding bias of the piezo actuator 23 , a hollow cylindrical spring element 27 , in the present case a tubular spring, is also provided. The tubular spring 27 is also connected to the cover element 25 and the base element 26 and has a number of recesses 28 which are arranged distributed over the surface of the hollow cylindrical spring element 27 . The spring stiffness of the spring element 27 is determined via the number, size and the arrangement pattern of the recesses 28 .

The piezo actuator 23 has a number of contact elements 32 which are fixed by means of adapter sleeves 33 which run through the base element 26 .

The actuator chamber 22 is in an unthrottled fluidic connection via a compensating bore 34 with a compensating chamber 35 . Furthermore, a compression spring 37 surrounded by a metal bellows 38 is provided in the compensation space 35 , which is supported on one side on the housing 21 and on its other side on an end plate 36 . Compression forces of a hydraulic fluid located in the actuator chamber 22 are thereby avoided.

A hydraulic chamber 29 is also provided above the cover element 25 and is connected to the actuator chamber 22 in terms of flow technology via a fit 30 . The cover element 25 thus functions as a hydraulic piston.

The hydraulic chamber 29 , the actuator chamber 22 , the compensating bore 34 and the compensating chamber 35 are filled with a hydraulic fluid, for example a silicone oil, without bubbles in the basic state of the valve 10 . The hydraulic fluid is, for example, put under a low admission pressure by the compression spring 37 . If the spring action of the flexible seals, here the metal bellows 38 , 57 itself is sufficient to sufficiently preload the hydraulic fluid, the compression spring 37 can be dispensed with.

The individual hydraulic elements form a hydraulic bearing that acts as a hydraulic length compensation element. Such changes in length that take place in time spans of several seconds to minutes, for example thermal changes in length, should be taken into account. In FIG. 1, the desired characteristic of the hydraulic bearing described above is achieved by the tight fit 30 . For this purpose, it is necessary to design the fit 30 in such a way that practically no exchange of the hydraulic fluid can take place within typical injection times. On the other hand, the liquid exchange should take place unhindered within typical times for thermal changes in length or the like.

In previously known solutions, it was necessary to passivate the surfaces 40 of the piezo actuator 23 electrically, since inner electrodes of alternating polarity are generally exposed on the side surfaces 40 of the piezo actuator 23 . Such passivation has so far been carried out in such a way that the surfaces 40 of the piezo actuator 23 had to be coated with a self-adhesive silicone compound. This silicone mass then had to be cured.

It has now surprisingly been found that such a separate, firmly adhering passivation layer on the surfaces 40 of the piezo actuator 23 can be dispensed with if the surfaces 40 are flushed with the hydraulic fluid which is located in the actuator chamber 22 , among other things. The hydraulic fluid takes on the role of the passivation layer previously required, which brings with it the advantages mentioned in the general description.

Due to the corresponding arrangement of the piezo actuator 23 within the hollow cylindrical spring element 27 and the fact that the spring element 27 has a series of recesses 28 , the hydraulic fluid can pass through the spring element 27 unhindered, so that the piezo actuator 23 , or its surfaces 40 , completely are surrounded by hydraulic fluid.

Silicone oils are particularly advantageous as hydraulic fluids, Advantageously, longer-chain silicone oils are used in addition to their chemical inertness also for their good electrical Isolation properties, or high electrical Dielectric strengths are known.  

In addition to the electrical passivation, the direct contact of the piezo actuator 23 with the hydraulic fluid also has the advantage of very good dissipation of the waste heat generated at the piezo actuator 23 to the environment. In addition, the piezo actuator 23 is well protected against environmental influences.

Claims (19)

1. Actuator, with a piezo actuator ( 23 ) which is arranged in an actuator chamber ( 22 ) delimited by a housing ( 21 ), the piezo actuator ( 23 ) having at least one actuator stack ( 24 ) and the actuator stack ( 24 ) with its end faces ( 39 ) is clamped between a cover element ( 25 ) and a base element ( 26 ), and wherein the actuator stack ( 24 ) is or is washed around by a hydraulic fluid provided in the actuator chamber ( 22 ), characterized in that the hydraulic fluid is one for the actuator stack ( 24 ) provided passivation layer for electrical passivation. 2. Actuator according to claim 1, characterized in that the hydraulic fluid forms a passivation layer provided on the surfaces ( 40 ) of the actuator stack ( 24 ). 3. Actuator according to claim 1 or 2, characterized in that no separate, firmly adhering passivation layer is provided on the surfaces ( 40 ) of the actuator stack ( 22 ). 4. Actuator according to one of claims 1 to 3, characterized in that the cover element ( 25 ) and / or the bottom element ( 26 ) is designed to be displaceable in the longitudinal direction of the piezo actuator ( 23 ). 5. Actuator according to one of claims 1 to 4, characterized in that the cover element ( 25 ) is designed as a hydraulic piston acting in the longitudinal direction of the piezo actuator ( 23 ). 6. Actuator according to claim 5, characterized in that the hydraulic piston ( 25 ) with the housing ( 21 ) forms a hydraulic chamber ( 29 ) and that the hydraulic chamber ( 29 ) is fluidically connected to the actuator chamber ( 22 ) for the exchange of hydraulic fluid. 7. Actuator according to one of claims 1 to 6, characterized in that the actuator stack ( 24 ) for generating a biasing force is arranged within a hollow cylindrical spring element ( 27 ). 8. Actuator according to claim 7, characterized in that the spring element ( 27 ) has a number of recesses ( 28 ) which are arranged distributed over the surface of the spring element ( 27 ). 9. Actuator according to one of claims 1 to 8, characterized in that the Hydraulic fluid for use in one Temperature range from -40 ° C to + 150 ° C can be used. 10. Actuator according to one of claims 1 to 9, characterized in that the Hydraulic fluid is a silicone oil. 11. Actuator according to one of claims 1 to 10, characterized in that the actuator stack ( 24 ) is arranged within a hollow profile. 12. Actuator according to one of claims 1 to 11, characterized in that the piezo actuator ( 23 ) has one or more contact elements ( 32 ) and that a corresponding number of adapter sleeves ( 33 ) is provided for fixing the contact elements ( 32 ) is / are provided in the housing ( 21 ) and / or the cover element ( 25 ) and / or the base element ( 26 ) and / or the hollow cylindrical spring element ( 27 ). 13. Actuator according to one of claims 1 to 12, characterized in that the actuator stack ( 24 ) is formed from at least two ceramic layers and at least one electrode layer arranged between two adjacent ceramic layers. 14. valve, in particular metering valve ( 10 ) for metering a pressurized metering fluid, with a valve chamber ( 55 ) and a valve housing ( 51 ) for receiving a valve needle ( 52 ) and an actuator ( 20 ) according to one of claims 1 to 13, wherein the valve needle ( 52 ) is connected to the actuator ( 20 ) and is moved or can be moved via the latter. 15. Use of an actuator ( 20 ) according to any one of claims 1 to 13 for controlling a valve needle ( 52 ) of a fuel injection valve for an internal combustion engine. 16. Use of a valve ( 10 ) according to claim 14 as a fuel injection valve for an internal combustion engine. 17. A method for producing an actuator, in particular an actuator according to one of claims 1 to 13, with the following steps:

• a) A piezo actuator consisting of at least one actuator stack is inserted without passivation into an actuator chamber delimited by a housing and clamped between a cover element and a base element;
• b) The actuator chamber is filled with a hydraulic fluid so that the hydraulic fluid flows around the actuator stack and thereby forms a passivation layer for the electrical passivation provided for the actuator stack.

18. The method according to claim 17, characterized characterized in that the piezo actuator without Passivation first in a hollow cylindrical Spring element is used to bias the Generate actuator stack and that the piezo actuator Then the spring element unit according to step a) in the Actuator chamber is used. 19. The method according to claim 17 or 18, characterized characterized in that the piezo actuator without Passivation is first introduced into a hollow profile and that the hollow profile piezo actuator unit subsequently in the actuator space or the hollow cylindrical spring element is used.