EP1165956A1 - Valve for controlling liquids - Google Patents

Abstract

The invention relates to a valve (1) for controlling liquids that is provided with a piezoelectric unit (4) that actuates a valve member (3) that is axially slidable within the bore (10) of a valve housing (7). The valve member (3) is configured as a multiple component consisting of at least one adjusting piston (9) adjoining the piezoelectric unit (4) and one actuation piston (12) adjoining the valve closing member (11), a hydraulic chamber (13) being disposed in between the two pistons. The bore (10) opens into a valve chamber (17) in which the valve closing member (11) can be displaced between a first valve seat (14) limiting a low-pressure zone (18) and a second valve seat (15) leading to a high-pressure zone (19). In its intermediate position, the valve closing member (11) is stabilized by a spring device (20) which interacts with a tapered section (21) of the valve member (3). Said tapered section (21) and the spring device (20) engage with each other when the valve closing member (11) is in its intermediate position.

Description

Valve for controlling liquids

State of the art

The invention is based on a valve for controlling liquids according to the kind defined in the preamble of claim 1.

Such a valve is known from DE 197 328 02 in a fuel injection device for internal combustion engines with a high-pressure fuel source.

The fuel injection device has two valve seats, which interact with sealing surfaces of a valve closing member when actuated by a piezo drive in a movement sequence, the valve closing member being initially in the closed position on the first valve seat, then being brought into an intermediate position between the valve seats and then being brought back in again to reach a closed position on the second valve seat. For this purpose, a piezoelectric actuator is charged to a rail pressure-dependent voltage, which lengthens the actuator and results from it. ting movement of the valve closing member to the second valve seat results. The actuator is discharged to reverse the valve closing member in the direction of the first valve seat.

In this way, the movement of the valve closing member from one valve seat to the other provides a brief relief for a valve control chamber under high pressure, the pressure level of which determines an open or closed position of a valve needle in the force-balanced fuel injection device and thus controls the fuel injection. The fuel injection is made possible while the valve closing member is in an intermediate position between the two

Valve seats. In this way a double fuel injection, e.g. a pre-injection and a main injection can be realized by means of a single excitation of the piezo drive.

However, it has been shown that overshoots of the valve closing member can occur if this is to be brought into a central position between the two valve seats. As soon as the valve closing member swings too far in the direction of the first or the second valve seat, this can disadvantageously lead to inaccuracies in the metering of the injection quantity. This problem exists especially at high rail pressures. Furthermore, in the case of higher voltages on the piezo drive which are dependent on the operating point or rail pressure and thus very fast actuating movements, the time in which the valve closing element is in the central position can be so short that this has no effect on the valve needle and none Fuel injection takes place.

Attempts are known to stabilize the central position of the valve closing member between the valve seats by means of a suitable dimensioning of a spring which is often arranged between the second valve seat and the valve closing member in order to keep the latter in the closed position on the first valve seat when the valve control chamber is depressurized , However, this has the disadvantage that the valve closing member would have to be moved out of the first valve seat into its closed position on the second valve seat against the spring force over its entire travel range. Accordingly, the piezo drive would have to be dimensioned correspondingly large, as a result of which the manufacturing costs and the structural dimensions of the injection device are adversely affected.

There is also the possibility of controlling the piezoelectric drive in such a way that, in order to move the valve closing element from the first to the second valve seat, it is loaded with such high voltage that the time in which the valve closing element is in the intermediate position is too short to have an impact on the overall opening behavior of the valve ben. The injection could be achieved by gradually reducing the voltage on the piezo drive during the return movement into the first valve seat, the injection duration and thus the injection quantity being controlled via the duration of an application of a medium voltage to the piezoelectric actuator. The disadvantage of this is that the effect of a double-switching valve is lost. Furthermore, this solution is problematic in terms of energy, in particular with regard to the power consumption and the power loss, at least at high speeds and several injections.

Advantages of the invention

The valve according to the invention for controlling liquids with the features of claims 1 and 6 has the advantage that the actuating movements of the valve closing element are damped by means of a spring device according to the invention in such a way that the valve closing element in its intermediate or middle position between the two valve seats simple and inexpensive means is mechanically stabilized.

The invention enables the reliable realization of an average valve lift independent of a high pressure prevailing at the second valve seat, the valve being able to be operated with double-switching with an energetically favorable control. This means that even high-frequency and small injections of liquids, especially fuel, can be carried out through the Valve according to the invention can be made exactly without there being any fluctuations in the injection quantity due to overshoots of the valve closing element or an injection being completely absent.

Further advantages and advantageous configurations of the subject matter of the invention can be gathered from the description, the drawing and the patent claims.

drawing

Two embodiments of the valve for controlling liquids according to the invention are shown in the drawing and are explained in more detail in the following description. Show it

1 shows a schematic, partial representation of a first embodiment of the invention in a fuel injection valve for internal combustion engines in longitudinal section, with a valve closing member in an intermediate position between the first valve seat and a second valve seat;

FIG. 2 shows a schematic cross section along the line I-I in FIG. 1; Figure 3 is a graph of a qualitative curve of a force that dampens the movement of the valve closing member in its intermediate position; and

FIG. 4 shows a schematic, partial representation of a further exemplary embodiment of the invention in a fuel injection valve for internal combustion engines in a longitudinal section. Description of the exemplary embodiments

The first exemplary embodiment shown in FIG. 1 and FIG. 2 shows the use of the valve according to the invention in a fuel injection valve 1 for

Internal combustion engines for motor vehicles. In the present case, the fuel fine injection valve 1 is designed as a common rail injector, the fuel injection being controlled via the pressure level m in a valve control chamber 2, which is rather connected to a high pressure supply.

In order to set an injection start, an injection duration and an injection quantity via force ratios in the fuel injection valve 1, a valve member 3 is controlled via a piezoelectric unit designed with a piezoelectric actuator 4, which is arranged on the side of the valve member 3 facing away from the valve control chamber and combustion chamber.

The piezoelectric actuator 4 is constructed in a known manner from several layers and has an actuator head 5 on its side facing the valve member 2 and an actuator foot 6 on its side facing away from the valve member, which is supported on a valve housing 7. An actuator piston 9 of the valve member 3 bears on the actuator head 5 via a support 8, the piston being of stepped diameter.

The valve member 3 is axially displaceable in a

Long bore bore 10 of the valve housing 7 is arranged and comprises, in addition to the actuating piston 9, an actuating piston 12 actuating a spherical valve closing member 11. The actuating piston 9 and the actuating piston 12 are coupled to one another by means of a hydraulic transmission.

The hydraulic transmission is designed as a hydraulic chamber 13, which transmits the deflection of the piezoelectric actuator 4. The hydraulic chamber 13 encloses a common compensation volume between the two pistons 9 and 12 delimiting it, of which the actuating piston 12 is designed with a smaller diameter and the actuating piston 9 with a larger diameter.

The hydraulic chamber 13 is clamped between the actuating piston 9 and the actuating piston 12 in such a way that the actuating piston 12 makes a stroke which is increased by the ratio of the piston diameter when the larger actuating piston 9 is moved by a certain distance by the piezoelectric actuator 4. The actuating piston 9, the actuating piston 12 and the piezoelectric actuator 4 lie one behind the other on a common axis.

In addition to the hydraulic power transmission, tolerances based on temperature gradients in the component or different coefficients of thermal expansion of the materials used, and any

Setting effects are compensated for without this Change in the position of the valve closing member 11 to be controlled occurs. The filling of the hydraulic chamber 13 is not shown in FIG. 1.

At the valve control chamber end of the valve member 3 or actuating piston 12, the spherical valve closing member 11 cooperates in a valve chamber 17 with valve seats 14, 15 formed on the valve housing 7, the first or upper valve seat 14 forming a low-pressure region 18 and the second or lower one Valve seat 15 leads to valve control chamber 2, which is under high pressure. A spring 16 is assigned to the lower valve seat 15 and holds the valve closing member 11 on the upper valve seat 14 when the valve control chamber 2 is relieved.

In the valve control chamber 2 of the high pressure area 19, a movable valve control piston is arranged, which is not shown in the drawing. By means of axial movements of the valve control piston in the valve control chamber 2, an injection nozzle of the fuel injection valve 1 is controlled in a manner known per se. An injection line, which supplies the injection nozzle with fuel, usually also flows into the valve control chamber 2. The injection line is connected to a high-pressure storage space (common rail) that is common to several fuel injection valves. The high-pressure storage space is fed in a known manner from a high-pressure fuel pump with high-pressure fuel from a storage tank. To stabilize the valve closing member 11 in its central position, a spring device 20 is arranged in a region between the hydraulic chamber 13 and the valve chamber 17, in which the valve closing member 11 is arranged. The spring device 20 interacts in operation of the fuel injection valve 1 with a taper 21 on the actuating piston 12, the taper 21 and the spring device 20 being arranged relative to one another in such a way that they engage with one another when the valve closing member 11 is in its intermediate position.

As can be seen in Figure 1 and Figure 2, the spring device 20 is formed in the embodiment shown with a tension spring 22 which is supported at its end facing away from the valve member 3 or actuating piston 12 on the valve housing 7 and at its other, the actuating piston 12 facing end has a sliding device 23.

In the present embodiment, the slider

23 formed with three balls 24 distributed uniformly over the circumference of the actuating piston 12, which interact with the geometry of the taper 21 on the actuating piston 12 in such a way that the valve closing member 11 is braked in its central position during an actuating movement. The position of the balls

24 and the geometry of the taper 21 of the actuating piston 12 are to be adapted by the person skilled in the art in accordance with the desired braking of the valve closing element 11. A valve system pressure chamber 25 connects to the piezo-side end of the bore 10. This is delimited on the one hand by the valve housing 7 and on the other hand by a sealing element 26 which is connected to the actuating piston 9 of the valve member 3 and the valve housing 7 and which is designed here as a bellows-like membrane and prevents the piezoelectric actuator 4 from contacting the valve system pressure chamber 25 contained fuel comes into contact. A filling device 27 is indicated schematically for filling the low-pressure region 18.

The fuel injection valve 1 according to FIG. 1 and FIG. 2 operates in the manner described below.

In the closed state of the fuel injection valve 1 and the uncharged piezoelectric actuator 4, the valve closing member 11 of the valve member 3 is held in contact with the upper valve seat 14 assigned to it, so that no fuel can get from the valve control chamber 2 connected to the high-pressure storage chamber into the low-pressure region 18.

In the event of slow actuation, as occurs when the length of the piezoelectric actuator 4 or other valve components, such as the valve housing 7, changes due to temperature, the actuating piston 9 penetrates into the compensating volume of the hydraulic chamber 13 as the temperature rises or withdraws therefrom when the temperature drops, without that this affects has the closed and open position of the valve member 3 and the fuel valve 1 as a whole.

When the fuel injection valve 1 is to be injected, the piezoelectric actuator 4 is charged, as a result of which the axial expansion of the actuator is suddenly increased. This elongation of the piezoelectric actuator 4 is transmitted to the actuating piston 12 via the actuating piston 9 and the hydraulic chamber 13, as a result of which the valve closing member 11 is lifted out of the first, upper valve seat 14 and is moved against the applied rail pressure against the second, lower valve seat 15 , If the actuating piston 12 with its taper 21 now reaches the area in which the balls 24 of the sliding device 23 are arranged, the control valve experiences a braking force directed against the direction of movement of the valve closing member 11, which leads to stabilization around this position.

FIG. 3 shows, in an extremely simplified manner, a course of this braking force which occurs with the engagement between the taper 21 of the actuating piston 12 and the spring device 20 and which has its maximum in the central position h_middle of the valve closing member 11. If the actuating piston 12 is moved further from the central position by a correspondingly large piezo force, the taper 21 moves out of the area of the balls 24 pressed against the actuating piston 12, the force suddenly decreasing counter to the direction of valve movement. The valve closing member 11 can thus can be moved into its maximum stroke position h_max, ie to the second valve seat 15, without any counterforce being exerted by the spring device 20.

When the piezoelectric actuator 4 is discharged, the valve closing member 11 is now moved in the opposite direction with the support of the rail pressure, wherein the engagement of the spring device 20 in the taper 21 of the actuating piston 12, as described above, in turn stabilizes the valve closing member 11 in its central position ,

The piezoelectric actuator is generally controlled in such a way that it is charged or discharged to an intermediate voltage level for injection. The resulting actuator stroke ensures that the control valve can be positioned approximately centrally between the seats. The device according to the invention ensures that this middle position can be maintained safely and with high precision.

With reference to FIG. 4, a further exemplary embodiment of the fuel injection valve 1 is shown, in which, for reasons of clarity, functionally identical components are designated by the reference symbols used previously.

Compared to the embodiment according to FIGS. 1 and 2, the spring device 20 shown here differs in that a spring 28 in the valve chamber 17 of the valve is arranged on the one hand at the end of the valve chamber 17 associated with the second valve seat 15 and on the other hand against a stop 29 in a region between the first valve seat 14 and the second valve seat 15. By suitably positioning the stop 29, the spring 28 is positioned such that its spring force dampens the actuating movement of the valve closing member 11 from the first valve seat 14 into the second valve seat 15 once it has reached its intermediate position.

Of course, the described embodiments can be used alternatively or next to one another in the valve according to the invention. When the spring devices are used in combination, the mode of operation or the central position of the valve closing member can be further stabilized.

Claims

Expectations

1. Valve for controlling liquids, with a piezoelectric unit (4) for actuating a valve member (3) which can be axially displaced in a bore (10) of a valve housing (7) and which has several parts with at least one to the piezoelectric unit (4) adjoining actuating piston (9) and at least one actuating piston (12) adjoining a valve closing element, between which one operates as a hydraulic transmission and tolerance compensation element

Hydraulic chamber (13) is arranged, one end of the bore (10) facing away from the piezoelectric unit (4) bordering into a valve chamber (17) in which the valve closing member (11) is arranged, which is located between one at the end of the bore (10 ) formed and delimiting a low pressure region (18) and a second valve seat (15) leading to a valve control chamber (2) of a high pressure region (19) for opening and closing the valve (1), wherein it can be moved in an intermediate position between the valve seats (14, 15) the low pressure area (18) fluidly connects to the valve control chamber (2), characterized in that a spring device (20) stabilizing the valve closing member (11) in its intermediate position interacts with a taper (21) of the valve member (3), the taper (21) and the spring device ( 20) are arranged with respect to one another in such a way that they are in engagement with one another when the valve closing member (11) is in its intermediate position.

2. Valve according to claim 1, characterized in that the taper (21) is formed on the actuating piston (12).

3. Valve according to claim 1 or 2, characterized in that the spring device (20) is formed with a tension spring (22) which is supported on its end facing away from the valve member (3) on the valve housing (7) and on its the valve member (3) facing end has a sliding device (23).

4. Valve according to claim 3, characterized in that the sliding device (23) is formed with balls (24), wherein preferably three equally spaced balls (24) are provided.

5. Valve according to one of claims 1 to 4, characterized in that the spring device (20) is arranged in a region between the hydraulic chamber (13) and the valve chamber (17).

6. Valve for controlling liquids, in particular according to one of claims 1 to 5, characterized in that the spring device (20) with a spring (28) in the valve chamber (17) of the valve closing member (11) is arranged, which on the one hand on the the second

Valve seat (15) facing end of the valve chamber (17) and on the other hand at a stop (29) m an area between the first valve seat (14) and the second valve seat (15) is supported, the stop (29) being arranged such that the spring force vaporizes an actuating movement of the valve closing member (11) from the first valve seat (14) into the second valve seat (15) after reaching its intermediate position.

7. Valve according to one of claims 1 to 6, characterized in that between the second valve seat (15) facing end of the valve chamber (17) and the valve closing member (11), a further spring element (16) is provided, by means of the spring force of the valve - Closing member (11) is held on the first valve seat (14) when the valve control chamber (2) is relieved of pressure.

8. Valve according to one of claims 1 to 7, characterized by its use as a component of a fuel injection valve for internal combustion engines, in particular a common rail injector (1).