DE102004030606A1 - Piezoelectric actuator for a fuel injector of an internal combustion engine and use thereof - Google Patents

Abstract

The invention relates to the temperature compensation in a piezoelectric actuator, which has a sleeve-shaped housing arrangement (12) and a piezoelectric actuator arranged therein. According to the invention, an outer peripheral surface (18) of the housing arrangement (12) has at least one recess (20), in which axially fitting or with slight axial play at least one thrust part (22) is formed, which is formed from a material which has a larger thermal expansion coefficient than that of the recess (20) adjacent material of the housing assembly (12).

Description

The The present invention relates to an actuator for a Fuel injector of an internal combustion engine according to the preamble of claim 1 and the use of such an actuator.

Such an actuator is for example from the DE 198 58 085 C1 and comprises an elongate piezoelectric actuator, the change in length resulting in the control is transmitted in the axial direction to a hydraulic servo valve of a fuel injector. For this purpose, a bottom plate of the piezoelectric actuator via a lever translator with an axially guided valve piston of the servo valve in operative connection. The movement transmitted by the piezoelectric actuator by means of the lever translator to the valve piston movement is used in the fuel injector for opening and closing a fuel injection valve.

The Use of such an actuator in an environment with changing Temperature is problematic insofar as it is due to the thermal expansion of the materials used to length changes that comes in unwanted Way to the function and drive characteristic of the actuator and thus the component controlled thereby (eg injection valve) can affect. Particularly disadvantageous here is the temperature-dependent change the axial positional relationships in the area of the active compound.

at known injector designs this temperature dependence often taken into account as a more or less big one axial gap provided in the path of action from the actuator to a valve body is used as the tolerance range for an undesirable Deviation and / or change the axial dimensions is used. But even with the provision of such Tolerance gap affect temperature changes disadvantageous since the size of the gap (Idle stroke) changed becomes.

From the DE 195 38 791 C2 a piezo control valve for fuel injection systems is known in which the piezoelectric actuator is arranged in a valve housing designed as a two-part sleeve, the sleeve parts are coaxial with each other and consist of different materials with different thermal expansion coefficients. In one embodiment, a lower sleeve part is made of ordinary steel while an upper sleeve part is made of Invar. This makes it possible to obtain an approximately equal length extension of the essentially ceramic piezoelectric actuator on the one hand and the two-part valve housing on the other hand, so that the sum of the thermal expansions of these sleeve parts corresponds to the thermal expansion of the piezoactuator. Advantageously, temperature-dependent changes of the axial distance between an actuator base and a closure piece operatively connected therewith can thus be kept relatively small. A disadvantage of this solution, however, is the lack of flexibility of the temperature compensation, since the material combination and housing construction described can only compensate for a certain dependence between temperature and change in length of the piezoceramic. Furthermore, the two-piece valve housing combining several materials is more complicated to produce compared to a housing made of only one material.

From the DE 101 30 857 A1 An electronic compensator for a piezoelectric actuator is known. To compensate for the thermal expansion under different operating conditions, the size of an axial gap in the region of an operative connection between an actuator base designed as a cap and an actuator designed as a shaft is measured by means of a scanning coil and compensated via a control loop. This compensation takes place by driving a set of several sets of piezoelectric elements of a piezo stack provided for this purpose. However, a disadvantage is the additional effort required for the detection, evaluation and control of the gap size.

Finally, out of the DE 199 09 106 A1 a temperature-compensated actuator with a piezoelectric actuator known, which is arranged in a housing consisting of three sleeves. These sleeves are positively and / or non-positively inserted into one another and connected to form a single component. The material combination of the three sleeves is chosen so that their thermal expansion is adapted to that of the piezoelectric actuator. A disadvantage of this solution, however, again limited flexibility of the temperature compensation for adaptation to modified actuator designs. Furthermore, the formation of the housing of three nested sleeves is relatively expensive in material processing and assembly.

A temperature compensation solution based on Applicant's internal operational knowledge is to make the actuator housing, which contains the substantially ceramic piezoelectric actuator, entirely of an iron-nickel alloy having a very small coefficient of thermal expansion. It has been found, however, that the thermal expansion differences, which lead to the adverse change in the axial positional relationships in the region of the active compound, thereby overcompensated. To this overcompensation to eliminate it is z. For example, it is possible to provide, instead of a steel-made actuator (valve piston), an actuator made of a material which has a smaller thermal expansion coefficient than steel (eg cermet). However, the latter measure again leads to higher material and / or processing costs for the actuator and again to a lack of flexibility with regard to the adaptation of the temperature compensation to the actual installation environment and Stellantriebskonstruktion.

It is an object of the present invention, in an actuator of the type mentioned a cost-effective and to allow easy temperature compensation.

These Task is solved with an actuator according to claim 1. The dependent claims relate advantageous developments of the invention.

at the actuator according to the invention is provided that an outer peripheral surface of housing arrangement has at least one recess in which axially matching or with slight axial play at least one thrust part is added, which is formed of a material having a larger coefficient of thermal expansion has as the recess of the adjacent material of the housing assembly. This makes it possible in a simple manner, the thermal expansion coefficient of the housing material "artificially increase," as that or the Shear parts at least from a certain temperature be an additional stretch the housing arrangement effect in the axial direction. This makes it possible in particular, a very simply from a single material like the mentioned iron-nickel alloy constructed, but in itself overcompensated with respect to the piezoceramic used casing by appropriate design and material selection of the or To optimize push parts.

Of the Term "axially fitting or with slight axial play "means Here, that the stretching effect of the pushing part from a limit temperature which does not exceed half the expected during operation maximum temperature is. If this limit temperature is below the expected minimum temperature in practice, Thus, the relevant thrust part permanently acts in the sense of an axial stretching the housing arrangement. If the limit temperature, however, within the expected in practice Temperature range is, so there is a temperature range without additional Strain effect (below the limit temperature) and an operating range with the additional Stretching effect (over the limit temperature).

Of the actuator according to the invention finds an advantageous use z. B. for a fuel injector a common rail diesel injection system, because the large temperature fluctuations that occur during the operation of such systems (typically, for example, from -40 ° C to + 160 ° C) the one or more push parts can be handled well.

at Installation environments in which the operative connection between actuator floor and actuator provides a certain idle stroke of the piezoelectric actuator, the z. B. by an axial gap between the actuator base and actuator or between other components in the path of action between the piezoactuator and realized to be adjusted device, it is advantageous possible, over this idle stroke the entire temperature range used in practice at least approximately constant to keep. Another advantage of the actuator according to the invention is that the number, arrangement and design of the recesses) and the one or more therein received push parts flexible to the Construction and temperature characteristics of the other actuator components can be adjusted. Thus, it is possible in particular in case of changes in the structure of the piezoelectric actuator from execution to execution, the a changed one thermal expansion behavior can bring, with comparatively low design effort the desired temperature compensation adapt. Such an adaptation can be done for example by minor changes in the shaping and dimensioning of the recesses and the Sliding parts.

The in principle conceivable use of a thermal Expansion coefficients specially selected and therefore rather expensive and possibly costly to be processed actuator, z. B. from cermet, is unnecessary. Rather, it can be inexpensive for the Actuator a manufacturing mostly z. B. be provided from steel, wherein the actuator, for example the valve actuating piston a hydraulic valve may be located at the second end the housing arrangement is located or attached to it.

at the actuator according to the invention This results in an increased freedom in the selection of materials of the components of the actuator and related Components, especially considering the aspect of cost savings and the aspect of flexibility interesting in the construction. The by means of the pushing parts realizable big and Individually adaptable to the overall construction length change allowed in the axial direction it, in the design of the inside of the actuator actuator components their thermal properties are largely ignored.

A manufacturing technology simple Festle tion of the housing head at the first end of the housing assembly can be z. B. by welding a portion of the housing head with the housing assembly formed of metal or a metal alloy.

In a preferred embodiment is the piezoelectric actuator as an elongated piezoelectric element stack in the axial direction educated. Leave it advantageous a comparatively large axial length change in the control cause the actor. On the other hand, with increasing size of the piezoelectric actuator in the axial direction tends to increase thermally induced expansion differences in the axial direction can be compensated by the one or more push parts.

The invention is particularly interesting for housing designs with a comparatively small coefficient of thermal expansion, which can be increased to a desired extent by the thrust member assembly. In one embodiment, it is therefore provided that the material of the housing arrangement adjacent to the recess has a coefficient of thermal expansion of less than 5 × 10 ^-6 1 / K. Also, it is usually advantageous if the recess of the adjacent material of the housing assembly has a thermal expansion coefficient which is smaller than the thermal expansion coefficient of the piezoelectric actuator. For example, the housing assembly may be at least partially, in particular special mostly or even substantially completely made of an iron-nickel alloy.

In contrast, in many applications it is preferred for the pusher to provide a thermal expansion coefficient greater than 5 × 10 ^-6 1 / K. For this example, the use of steel is suitable.

It is not excluded, several, identical or different to provide shaped recesses, in each of which one or more thrust parts be recorded. If you use more than one pusher parts, you can even with regard to the material and / or the axial play (and so that mentioned Limit temperature). When arranging several recesses and / or Pusher parts is in practice to avoid over the Scope considers uneven strain, which leads to a curvature the housing longitudinal axis to lead would, preferred, the axial thrust effect viewed in the circumferential direction preferably to provide evenly. This corresponds to a uniform distribution of shear parts in the circumferential direction. So it is conceivable, for example a circumferentially equidistant Arrangement of several, each provided with a sliding part recesses provide, which then enforce even the entire wall of the sleeve-shaped housing can.

In a preferred embodiment it is provided that the recess is closed annularly in the circumferential direction is formed circumferentially. In such a circumferential groove are then for manufacturing reasons prefers several bowl-shaped Shear parts added. In particular, in such a circulating Recess two bowl-shaped Shear parts are received, which together essentially extend around the entire circumference. This can be a particularly uniform axial Stretching guaranteed become.

in the With regard to a large-scale introduction of axial thrust force, it is preferred if at one or both axial Ends of the recess is a substantially radially extending stop surface for the it is provided in the incorporated thrust part.

In a preferred embodiment is the pushing part pressed into the recess. Alternatively, you can the thrust part in the manufacture of the actuator with axial Game are inserted into the recess and then against an exit be secured from the recess.

One not at all expected temperatures in operation with fit In the recess recorded thrust part can at an exit be secured from the recess, for example, by that a portion of the pusher glued to the housing assembly or welded becomes.

to Ensuring a sufficient additional stretch is there in many applications preferred when the proportion of recessed outer peripheral surface referred on the entire outer peripheral surface in the area from 20% to 80% and / or the maximum depth of each recess ranging from 20% to 80%.

The Invention will be described below with reference to an embodiment with reference to the attached Drawings closer described. They represent schematically:

1 a perspective view of a sleeve-shaped actuator housing according to a first embodiment,

2 an axial longitudinal section of the housing,

3 a graphic illustrating the temperature behavior of the housing,

4 a perspective view of a sleeve-shaped actuator housing according to a second embodiment,

5 a axial longitudinal section of the housing, and

6 a graphic illustrating the temperature behavior of the housing.

The 1 and 2 illustrate the design of a housing 12 a piezoelectric actuator forming an upper assembly of a fuel injector unit having in its lower portion a fuel injection valve for an internal combustion engine.

The sleeve-like, here hollow cylindrical housing 12 has a longitudinal axis L, that of an upper end 14 of the housing to a lower end 16 of the housing runs.

Except the case 12 the actuator comprises in a conventional manner the following components (not shown) arranged inside the housing: a piezoactuator which can be activated for a change in length in the axial direction L, one at the upper end 14 of the housing 12 welded housing head on which the upper end of the piezoelectric actuator is supported in the axial direction, an axially movable guided actuator base on which the lower end of the piezoelectric actuator is supported in the axial direction and which is in operative connection with an axially movable valve piston of the injection valve. The valve piston is located approximately at the level of the lower housing end 16 , Via an operative connection, an axial length change of the piezoactuator is transmitted from the bottom plate to the valve piston.

in the Operation of the fuel injector unit occurs at a temperature change the installation environment to thermal deformations of the individual components. In the manner described below, however, is avoided by Temperature variations caused shape changes the performance characteristics and the driving characteristic of the actuator or the so actuated Substantially change injection valve, in particular in the sense of an axial displacement of the positions of the actuator base and / or the valve piston act.

An outer peripheral surface 18 of the actuator housing 12 is with a recess in the form of an annular circumferential groove 20 provided, in which two identically formed halves of a push ring 22 were pressed.

The housing 12 is made of an iron-nickel alloy with a very low coefficient of thermal expansion, whereas the thrust ring is preferably made of a metal alloy with a comparatively larger thermal expansion coefficient (here: steel). The without provision of the thrust ring 22 With regard to the temperature compensation (in particular depending on the material used for the piezoelectric actuator inside the housing) too small heat meausdehnung of the iron-nickel alloy is due to the integration of the thrust ring 22 effectively made of steel. By pressing at a temperature lower than expected in the operation minimum temperature, a firm at all operating temperatures seat of the two half-shells and thus a constant change in length of the housing 12 guaranteed with the temperature.

An adverse temperature behavior of the actuator is thus by integration of the thrust ring 22 on the housing 12 eliminated.

By using the push ring 22 There is an increased freedom in the choice of materials of the components of the actuator and the device operated therewith. Advantageously, the housing 12 be formed in one piece.

If the thermal expansion behavior of the piezoceramic used change due to production, then the geometry of the groove 20 be easily adapted to the new requirements.

3 illustrates the length changes (ΔL) of the various housing components relative to the total length (L ₀ ) as a function of the temperature (T).

The Line A illustrates the comparatively large extent of the thrust ring material (steel) at rising temperature (T).

In contrast, is the course of the thermal expansion represented by the line B. for the remaining housing material (Iron-nickel alloy) much flatter.

Of the for the housing construction Total resulting coefficient of expansion is now between the coefficient of expansion of these two materials (lines A and B), so that the course represented by a line C the thermal expansion as a function of the operating temperature results. This course is in the sense of optimized temperature compensation provided the actuator.

However, the resulting thermal expansion according to line C does not depend solely on the use but also on the geometry of the groove 20 as well as the included therein thrust part 22 , Consequently, advantageously, an adaptation of the resulting thermal expansion curve can also take place by a suitable choice of a width of the groove 20 , which is the height H of the thrust ring formed by the half shells 22 (see. 2 ), and by appropriate choice of the depth of this groove 20 (ie the division of the cross-sectional area of the housing wall on the two materials).

In the material selection provided in this example, the provision of the thrust ring changes 22 the elastic behavior only a little, since both materials have e-modules of the same order of magnitude. By the choice made of the design parameters can be ensured in a simple manner that over the entire operating temperature range (here: 200 K), the burden of the housing 12 in the groove the yield strength of the same is not reached.

For the parameters of the illustrated actuator housing, the following values are given by way of example only:
Housing length in axial direction L: 39 mm
Depth of the groove 20 : 0.9 mm
Width of the groove 20 : 10 mm
casing 12 : Ni36, coefficient of expansion: 1 × 10 ^-6 1 / K
Half shells: stainless steel, coefficient of expansion: 16 × 10 ^-6 1 / K
Resulting expansion coefficient of the housing construction: 2, 6 × 10 ^-6 1 / K

In the following description of a further embodiment of the invention, the same reference numerals are used for analogous components, in each case supplemented by the small letter "a". It is essentially only on the differences to that with respect to the 1 to 3 already described embodiment and, moreover, hereby expressly to the above description of the 1 to 3 directed.

The 4 to 6 are the 1 to 3 corresponding representations of a modified embodiment in which one in an outer peripheral surface 18a provided groove 20a has a width which is the height H of a thrust ring 22a by a certain amount (axial gap width S) exceeds. Up to a certain limit temperature (here: 50 ° C), this gap exists between the axially upper end of the thrust ring 22a and the axially adjacent end of the recess 20a also in the operation of the actuator. When approaching this limit temperature, the gap width S gradually decreases to become zero at the limit temperature of 50 ° C. This is the temperature above which the thrust of the thrust ring 22a starts. Like it out 6 it can be seen, the total resulting thermal expansion (line C) for the housing construction initially corresponds to the thermal expansion of the housing 12a used material (line B) to deviate when exceeding the temperature of 50 ° C at the top.

Of the in this embodiment provided kinked course of thermal expansion in dependence from the temperature T may be beneficial at a Be fuel injector of an internal combustion engine (hot start problem).

The the thrust ring 22a forming half-shells are falling out of the recess 20a secured by a weld.

Provided a strain-temperature profile is desired, which deviates from this embodiment has several limit temperatures and thus several kinks, so This can be done in a simple manner z. B. by arranging a corresponding plurality be realized by grooves with thrust rings. For example, two or three axially spaced circumferential grooves are provided.

The dimensioning of the gap width S to be carried out as part of the production can advantageously be achieved by means of defined mechanical compression of the thrust ring 22a provided housing 12a be set. This succeeds z. As in the above-mentioned material combination particularly good, since the modulus of elasticity of the steel half shells slightly larger than the modulus of elasticity of the housing 12a is made of iron-nickel alloy, so that sets a defined air gap S depending on the compression force after plastic compression and elastic springback. The accuracy of this adjustment of the gap width S is that of a purely machining the housing 12a think.

Claims (17)

Actuator for a fuel injector of an internal combustion engine, comprising - a sleeve-shaped housing arrangement ( 12 ) with an axial direction (L) extending between a first and a second end ( 14 . 16 ) of the housing arrangement extends, - one in the housing arrangement ( 12 ) arranged and for a change in length in the axial direction (L) controllable piezoelectric actuator, - fixed in the axial direction (L) housing head at the first end ( 14 ) of the housing arrangement ( 12 ), on which a first end of the piezoactuator is supported in the axial direction, and - in the axial direction (L) movable in the hous arrangement ( 12 ) guided actuator base on which a second end of the piezoelectric actuator is supported in the axial direction and which can be brought into operative connection with an actuator to be adjusted, characterized in that an outer peripheral surface ( 18 ) of the housing arrangement ( 12 ) at least one recess ( 20 ), in which axially matching or with slight axial clearance at least one sliding part ( 22 ) is formed, which is formed of a material having a larger thermal expansion coefficient than that of the recess ( 20 ) adjacent material of the housing arrangement ( 12 ). Actuator according to claim 1, wherein the piezoelectric actuator is an elongated piezoelectric element stack in the axial direction (L). Actuator according to one of the preceding claims, wherein the recess ( 20 ) adjacent material of the housing arrangement ( 12 ) has a thermal expansion coefficient of less than 5 × 10 ^-6 1 / K. Actuator according to one of the preceding claims, wherein the recess ( 20 ) adjacent material of the housing arrangement ( 12 ) has a thermal expansion coefficient which is smaller than the thermal expansion coefficient of the piezoelectric actuator. Actuator according to one of the preceding claims, wherein the housing arrangement ( 12 ) is at least partially made of an iron-nickel alloy. Actuator according to one of the preceding claims, wherein the pushing part ( 22 ) has a thermal expansion coefficient of more than 5 × 10 ^-6 1 / K. Actuator according to one of the preceding claims, wherein the recess ( 20 ) is formed in the circumferential direction annularly closed circumferentially. Actuator according to claim 7, wherein a plurality of shell-shaped pusher parts in the recess ( 20 ) are included. Actuator according to claim 7 or 8, wherein two cup-shaped pusher parts in the recess ( 20 ), which in the circumferential direction in each case in wesentli chen over half the circumference of the recess ( 20 ). Actuator according to one of the preceding claims, wherein at one axial end of the recess ( 20 ) a substantially radially extending stop surface for the therein incorporated thrust part ( 22 ) is provided. Actuator according to one of the preceding claims, wherein the pushing part ( 22 ) in the recess ( 20 ) is pressed. Actuator according to one of claims 1 to 10, wherein the sliding part ( 22 ) with axial clearance (S) in the recess ( 20 ) is received and secured against escape from the recess. Actuator according to claim 12, wherein at least a portion of the pushing part ( 22 ) with the housing arrangement ( 12 ) is welded. Actuator according to one of the preceding claims, characterized in that the sliding part ( 22 ) axially positively in the recess ( 20 ) is arranged. Actuator according to one of the preceding claims, characterized in that the sliding part ( 22 ) axially biased in the recess ( 20 ) is arranged. Use of an actuator according to one of claims 1 to 13 for the axial adjustment of an actuator which is in operative connection with the actuator base for transmitting an axial length change of the piezoelectric actuator to the actuator, wherein the actuator has a thermal expansion coefficient of more than 5 × 10 ^-6 1 / K has. Use according to claim 14 for a fuel injector a common-rail diesel injection system.