EP1336045B1 - Injector housing with an actuator and intermediate damping disc - Google Patents

Abstract

The actuator comprises a head plate (K) with a guide pin (F). The injector housing comprises a housing body (AK) with a recess (U), into which the guide pin (F) is introduced. A first damping disc (D1) is arranged between the head plate (K) of the actuator and the housing body (AK). A means for exerting a force on the guide pin (F) is arranged in the housing body (AK), by means of which the actuator is pressed against the first damping disc (D1).

Description

The invention relates to an injector with an actuator unit.

For fuel supply of internal combustion engines, accumulator injection systems are increasingly being used in which very high injection pressures and fast switching speeds are used. In these accumulator injection systems fuel is conveyed by means of a high pressure pump in a high-pressure accumulator, from which the fuel is injected by means of injectors in the internal combustion engine. In this case, the injector is actuated by an electrically actuated actuator unit, wherein above all the use of piezoelectric actuator units for achieving sufficiently short switching times has proved to be advantageous.

In particular, the extremely fast-switching actuator units with switching times in the range of less than 200 microseconds but their high-frequency mechanical vibrations to the surrounding injector from. These vibrations then propagate along the injector housing and are directed into the cylinder head of the engine. On the surface of the injector housing and the cylinder head, these mechanical vibrations lead to significant noise that adversely affect ride comfort.

In a piezoelectric actuator unit, a longitudinal expansion is caused in a quartz ceramic piezoelectric element by applying a voltage, which is transmitted to a servo valve in the injector, which in turn opens or closes an injection nozzle in the injector. Such an actuator unit has only small travel paths at high restoring forces. To avoid lifting losses, the piezoelectric Actuator be made very stiff. This leads to a particularly high noise emission.

In order to reduce the noise emission of electrically actuated actuator units, these are conventionally provided with additional covers. However, this sound insulation by sheathing is complicated and expensive, since an additional component must be manufactured and assembled, which also has a large space requirement.

From US 4,995,587 an injection valve is known which increases a deflection of a piezoelectric actuator via a translation device. To transmit the deflection of the piezoelectric actuator to a valve assembly, two pistons are used. The movement of the first piston produces an increased movement of the second piston. Preferably, an elastomer is used to transfer force between the first and second pistons.

From DE 197 27 992 an injection valve is known in which a compensating element is provided to compensate for temperature-induced changes in length. The compensation element consists of an oil-filled chamber, which is arranged between the actuator housing and a piezoelectric actuator. By a corresponding filling of the chamber different temperature-induced changes in length between the piezoelectric actuator and the actuator housing can be compensated.

EP 0 218 895 A1 discloses a metering valve for metering liquids or gases. The metering valve uses a piezo stack as actuator. To compensate for temperature-induced changes in length of the piezo stack a damping piston is provided which limits a liquid-filled damping chamber. The damping piston is in operative connection with one end of the piezo stack. The damping chamber is connected via a throttle gap with a compensation frame in connection. The damping chamber and the compensation chamber form a hermetic sealed, gas-free liquid cushion, which fixes this stationary with respect to the valve housing during the excitation of the piezo stack.

From the post-published international patent application WO 01/25613 A1, a fuel injection valve is known, which has an annular piezoelectric actuator. The actuator is placed in an actuator housing and biased by a biasing spring to pressure. The biasing spring is inserted between a center flange and an upper end plate of the actuator housing. The center flange is located on the piezoelectric actuator and is also connected to an actuating body which is guided through the recess of the piezoelectric actuator. The actuator body is connected at one end to the valve needle. The other end is passed through the upper portion of the actuator housing and through an opening of the housing cover. Between the Aktorgehäusedeckel and a cover of the valve housing an attenuator is introduced. Between the lid of the valve housing and the actuating body, a further biasing spring is arranged. In addition, a second attenuator is arranged between a lower end plate of the actuator housing and the valve housing. With the help of arranged between the valve housing and the actuator housing attenuators compensation of the temperature expansion is achieved.

The invention has for its object to provide an arrangement of an injector and an actuator unit, which has a simpler structure and allows better damping of the actuator unit.

The object is achieved by an injector housing with an actuator unit having the following features: The actuator unit has a top plate with a guide pin. The injector housing has a receiving body with a recess in which the guide pin is inserted. Between the top plate of the actuator and the receiving body is a first Damping disc arranged. In the receiving body, a means for exerting a force on the guide pin is arranged, through which the actuator unit is pressed against the first damping disc. The first damping disc prevents a transmission of structure-borne noise from the actuator unit to the injector housing. On voluminous covers to reduce the noise emission can be omitted.

Through the recess, the guide pin and the means for exerting a force on the guide pin, the actuator unit is non-positively connected to the injector. Adhesive layers of adhesive between the injector housing and the first damping disk and between the first damping disk and the actuator unit can be dispensed with.

This is advantageous because layers of adhesive are compressible and result in a loss of lift. The arrangement of injector and actuator unit is therefore suitable for use of a piezoelectric actuator unit having only small travel paths.

However, actor units which are based on another - for example magnetostrictive - effect can also be used as the actuator unit.

For example, the guide pin on a shoulder which is arranged in the recess of the receiving body and having a first surface which faces the top plate. This paragraph thus forms a lateral projection of the guide pin. The receiving body has in the recess on a shoulder which has a second surface which faces the first surface. The first surface and the second surface are thus opposite each other. The means for exerting a force on the guide pin is clamped between the first and second surfaces and forces the first surface and the second surface apart. As a result, the guide pin is pressed into the recess, whereby the actuator unit is pressed against the first damping disc.

Preferably, the shoulder of the guide pin and the shoulder of the receiving body are formed radially around the guide pin circumferentially. As a result, the force with which the actuator unit is pressed against the first damping disk can be increased since the means for exerting a force on the guide bolt has larger engagement surfaces available.

For example, the shoulder of the guide pin is formed as a disc.

The means for exerting a force on the guide pin can be designed as a spring. When using a piezoelectric Actuator unit, the spring should be designed very hard to avoid lifting losses.

The spring may be formed, for example, as a spiral spring, plate spring or tube spring.

To simplify the mounting of the actuator in the injector, it is advantageous if the receiving body has an opening through which the guide pin is laterally accessible from the outside. Preferably, the means for exerting a force on the guide pin comprises a stack of crescent discs arranged between the first surface and the second surface. In this case, the assembly can be carried out by first the guide pin is inserted into the recess of the receiving body and then from the side of the crescent discs are placed around the guide pin. In order to prevent falling out of the crescent discs after insertion, it is advantageous to rotate the crescent discs around the guide pin.

The opening of the receiving body can be closed again after inserting the crescent discs by, for example, a plastic insert is inserted as a lid or the opening is potted with plastic foam.

To further reduce the noise emission is advantageous to arrange a second damping disc on the second surface.

The first damping disk and the second damping disk are made, for example, of ceramics, fiber-reinforced plastic materials or metal foams which are produced from a paste of metal particles and binder by means of a sintering process. The materials for the first damping disk and the second damping disk have the smallest possible elasticity and at the same time low sound transmission properties to avoid lifting losses of the actuator unit.

Instead of clamping the means for exerting a force on the guide pin between a shoulder of the guide pin and a shoulder of the receiving body, this means can also be configured differently. For example, for this purpose, the guide pin on a lower part and an adjacent upper part, wherein the lower part has a smaller cross-section and a smaller distance from the top plate than the upper part. In this case, the recess of the receiving body has a lower portion whose cross section corresponds to the cross section of the lower part of the guide pin, and an upper portion adjacent thereto, whose cross section corresponds to the cross section of the upper part of the guide pin. The upper part of the guide pin is arranged in the upper portion of the receiving body, while the lower part of the guide pin is partially disposed in the lower portion and partially in the upper portion of the recess. The means for exerting a force on the guide pin has a receiving space arranged in the pressure chamber, which opens into a region of the upper portion of the recess in which the lower part of the guide pin is arranged. The pressure chamber is filled with a liquid. The means for applying a force on the guide pin is such that it pressurizes the liquid. Due to the pressure in the pressure chamber, a force is exerted on the upper part of the guide pin from below, by means of which the actuator unit is pressed against the first damping disc.

To prevent leakage of liquid from the pressure chamber, it is advantageous if the lower part of the guide pin in the region of the lower portion of the recess has a circumferential groove in which a first sealing ring is arranged. Also for sealing the pressure chamber, it is advantageous if the upper part of the guide pin has a circumferential groove in which a second sealing ring is arranged.

Figur 1

zeigt einen Querschnitt durch einen Teil eines Injektorgehäuses und einen Teil einer ersten Aktoreinheit mit einem Aktorelement, einer Rohrfeder einer Kopfplatte, einem Führungsbolzen, einer ersten Dämpfungsscheibe, einem Aufnahmekörper, einer Ausnehmung, einer zweiten Dämpfungsscheibe, einer Feder, einer Sicherungsscheibe, einer Scheibe und einer Verschlussschraube.

Figur 2a

zeigt einen Querschnitt durch einen Teil eines zweiten Injektorgehäuses und einen Teil einer zweiten Aktoreinheit mit einem Aktorelement, einer Rohrfeder, einer Kopfplatte, einem Führungsbolzen, einer ersten Dämpfungsscheibe, einem Aufnahmekörper, einer Ausnehmung, einer zweiten Dämpfungsscheibe, einer Öffnung, einer Sicherungsscheibe und einem Stapel von Halbmondscheiben.

Figur 2b

zeigt eine Aufsicht auf eine Halbmondscheibe aus Figur 2a.

Figur 3

zeigt einen Querschnitt durch einen Teil eines dritten Injektorgehäuses und einen Teil einer dritten Aktoreinheit mit einem Aktorelement, einer Rohrfeder, einer Kopfplatte, einer ersten Dämpfungsscheibe, einem Aufnahmekörper, einem unteren Teil eines Führungsbolzens, einem oberen Teil des Führungsbolzens, einem unteren Abschnitt einer Ausnehmung, einem oberen Teil der Ausnehmung, einem Druckraum, einem ersten Dichtungsring, einem zweiten Dichtungsring, einem Dichtelement, einer Stiftschraube, einer Verschlussschraube und einer Sicherungsscheibe.

In the following, embodiments of the invention will be explained in more detail with reference to FIGS.

FIG. 1

shows a cross section through a part of an injector and a part of a first actuator unit with an actuator element, a bourdon tube of a top plate, a guide pin, a first damping disc, a receiving body, a recess, a second damping disc, a spring, a lock washer, a disc and a Screw.

FIG. 2a

shows a cross section through a part of a second injector and a part of a second actuator unit with an actuator element, a tube spring, a top plate, a guide pin, a first damping disc, a receiving body, a recess, a second damping disc, an opening, a lock washer and a stack of crescent slices.

FIG. 2b

shows a plan view of a crescent disk of Figure 2a.

FIG. 3

shows a cross section through a part of a third injector and a part of a third actuator unit with an actuator element, a tube spring, a top plate, a first damping disc, a receiving body, a lower part of a guide pin, an upper part of the guide pin, a lower portion of a recess, an upper part of the recess, a pressure chamber, a first sealing ring, a second sealing ring, a sealing element, a stud, a screw plug and a lock washer.

In a first embodiment, an arrangement of a first injector housing and a first actuator unit is provided.

The first actuator unit has a piezoelectric actuator element A, which is fixedly connected to a top plate K of the actuator unit (see FIG. 1). Between the top plate K and a bottom plate of the actuator unit, not shown, a tubular spring R is arranged, which biases the actuator element A.

With the top plate K, a guide pin F is firmly connected, which projects into a recess U of a receiving body AK of the injector (see Figure 1). Between the top plate K and the receiving body AK, a first damping disk D1 made of carbon or glass fiber reinforced plastic is arranged.

In a lower region of the receiving body AK a paragraph ABK of the receiving body AK extends radially around the guide pin F. The guide pin F has a disc S, which forms a shoulder of the guide pin F. The disk S is held in place by a lock washer SI disposed in a groove of the guide bolt F and by a step of the guide bolt F (see FIG. 1). The disc S has a first surface F1, which faces the top plate K. The paragraph ABK of the receiving body AK has a second surface F2, which faces the first surface F1 (see Figure 1). On the second surface F2, a second damping disk D2 made of carbon or glass fiber reinforced plastic is arranged.

Between the second damper disc D2 and the disc S, a helical spring FE is arranged, which presses apart the first F1 and the second surface F2.

The recess U of the receiving body AK is bounded from above by a screw plug V.

In a second embodiment, an arrangement of a second injector housing and a second actuator unit is provided.

Like the first actuator unit of the first exemplary embodiment, the second actuator unit has an actuator element A ', a tubular spring R', a top plate K ', a guide pin F'.

As in the first embodiment, a first damping disk D1 'is arranged between a receiving body AK' of the second injector housing and the top plate K '.

The guide pin F 'has a crescent-shaped disc S', which forms a shoulder with a first surface F1 '. As in the first embodiment, the receiving body AK 'on a paragraph ABK', which forms a second surface F2 '.

In the receiving body AK 'a lateral opening O is provided through which the guide pin F' is accessible from the side (see Figure 2a).

On the second surface F2 'as in the first embodiment, a second damping disc D2' is arranged. Between the second damping disk D2 'and the disk S', a stack of half moon disks H is arranged. The crescent discs H each have the shape of a non-closed ring. The opening of this ring is so large that the half-moon disk H can be placed around the guide pin F 'from the lateral opening O (see FIG. 2b).

The half-moon discs H are rotated by 90 ° about the guide pin F '.

The opening O is then potted with plastic foam.

In a third exemplary embodiment, an arrangement of a third injector housing is provided in a third actuator unit. As in the first embodiment, the third actuator unit comprises an actuator element A ", a tube spring R", a top plate K "and a guide pin F".

The guide pin F '' has a lower part UT and an upper part OT adjacent thereto. The lower part UT has a smaller cross-section than the upper part OT (see FIG. 3).

As in the first embodiment, a first damping disk D1 "is arranged between a receiving body AK" of the third injector housing and the top plate K ".

As in the first embodiment, the receiving body AK '' on a recess U '' on. The recess U '' has an upper portion OA and a lower portion UA. The upper part OT of the guide pin F '' is arranged in the upper portion OA of the recess U ''. The lower part UT of the guide pin F "is partly arranged in the lower section UA and partially in the upper section OA of the recess U" (see FIG. 3).

The receiving body AK '' has a pressure chamber D, which opens in the region of the lower part UT of the guide pin F '' in the upper portion OA of the recess U '' (see Figure 3). The pressure chamber D is bounded from above by the upper part OT of the guide pin F '' and by a sealing element I and an adjoining stud SS. By the stud SS the pressure chamber D is pressurized so that the liquid arranged in the pressure chamber D on a head plate K '' facing surface of the upper part OT of the guide pin F '' exerts a force, and thus the third actuator unit against the first Damping disk D1 '' is pressed. The sealing element I prevents leakage of the liquid in the pressure chamber D past the stud SS.

To prevent leakage of the liquid in the pressure chamber D to the lower part UT of the guide pin F '' over, a groove is provided in the lower part OT of the guide pin F '', in which a first sealing disc Il is arranged.

To prevent leakage of the liquid in the pressure chamber D to the upper part OT of the guide pin F '' over, a groove is provided in the upper part OT of the guide pin F '', in which a second sealing washer I2 is arranged. The groove is formed by a piston KO and a disc S '', wherein the disc S '' by a lock washer SI '' is held.

The recess U '' of the receiving body AK '' is bounded from above by a screw plug V ''.

Claims (8)

1. Injector housing with an actuator,

   - in which the actuator has a cover plate (K, K', K'') with a guide bolt (F, F', F''),

   - in which the injector housing has a receiving body (AK, AK', AK'') with a recess (U, U', U'') into which the guide bolt (F, F', F'') is inserted,

   - in which a first damping disc (D1, D1', D1'') is arranged between the cover plate (K, K', K'') of the actuator and the receiving body (AK, AK', AK''),

   - in which in the receiving body (AK, AK', AK''), the means for applying a force to the guide bolt (F, F', F'') is arranged whereby the actuator is pressed against the first damping disc (D1, D1', D1'').
2. Injector housing with an actuator according to claim 1,

   - in which the guide bolt (F, F') has a shoulder which is arranged in the recess (U, U') of the receiving body (AK, AK') and has a first area (F1, F1') which faces the cover plate (K, K'),

   - in which the receiving body (AK, AK') has a shoulder (ABK, ABK') in the recess (U, U'); said shoulder having a second area (F2, F2') which faces the first area (F1, F1'),

   - in which the means for applying a force to the guide bolt (F, F') is clamped between the first area (F1, F1') and the second area (F2, F2') and pushes the first area (F1, F1') and the second area (F2, F2') apart.
3. Injector housing with an actuator according to claim 2,

   - in which the shoulder of the guide bolt (F, F') and the shoulder (ABK, ABK') of the receiving body (AK, AK') are embodied in such a way that they encircle the guide bolt (F, F').
4. Injector housing with an actuator according to claim 2 or 3,

   - in which the means for applying a force to the guide bolt (F) is embodied as a spring (FE).
5. Injector housing with an actuator according to claim 3,

   - in which the receiving body (AK') has an opening (O) through which the guide bolt (F') can be accessed laterally from the outside,

   - in which the means for applying a force to the guide bolt (F') has a stack of crescent-shaped discs (H) arranged between the first area (F1') and the second area (F2').
6. Injector housing with an actuator according to one of the claims 2 to 5,

   - in the case of which a second damping disc (D2, D2', D2'') is arranged on the second area (F2, F2', F2'').
7. Injector housing with an actuator according to claim 1,

   - in which the guide bolt (F'') has a bottom part (UT) and a bordering top part (OT) in which case the bottom part (UT) has a smaller cross-section and a shorter distance to the cover plate (K'') than the top part (OT),

   - in which the recess (U'') of the receiving body (AK'') has a bottom section (UA) whose cross-section conforms to the cross-section of the top part (UT) of the guide bolt (F'') and a bordering top section (OA) whose cross-section conforms to the cross-section of the top part (OT) of the guide bolt (F''),

   - in which the top part (OT) of the guide bolt (F'') is arranged in the top section (OA) of the recess (U''),

   - in which the bottom part (UT) of the guide bolt (F'') is arranged partially in the bottom section (UA) and partially in the top section (OA) of the recess (U''),

   - in which the means for applying a force to the guide bolt (F'') has a pressure chamber (D) arranged in the receiving body (AK'') which enters an area of the top section (OA) of the recess (U'') in which the bottom part (UT) of the guide bolt (F'') is arranged,

   - in which the pressure chamber (D) is filled with a liquid in which the means for applying a force to the guide bolt (F'') is such that it pressurizes the liquid.
8. Injector housing with an actuator according to claim 7,

   - in which the bottom part (UT) of the guide bolt (F'') in the area of the bottom section (UA) of the recess (U'') has an encircling groove in which a first seal (I1) is arranged for sealing the pressure chamber (D),

   - in which the top part (OT) of the guide bolt (F'') has an encircling groove in which a second sealing ring (I2) is arranged for sealing the pressure chamber (D).

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