DE10321208A1 - Circuit arrangement for reducing sound emissions and high frequency oscillations of piezoelectric actuator e.g. for motor vehicle, has filter with small or large apparent resistance in acoustically disturbing frequency range - Google Patents

Abstract

The circuit arrangement has a control unit (V) for driving the actuator (P) with drive signals and at least one filter (F1) connected in parallel or series with the actuator. The filter or filters has a small or a large impedance in the acoustically disturbing frequency range. A first filter can be connected in series with the actuator and a second filter in parallel with the series circuit of first filter and actuator.

Description

The The invention relates to a circuit arrangement for reducing noise emissions and high-frequency vibrations of a piezoelectric actuator, in particular a piezoelectrically driven actuator, such as it for example in brakes, metering devices, optical mirrors and lens devices, Injection systems or valve adjustments is used.

On Piezoelectric actuator can also be found in a fuel injector, for example Use. In this case, a control valve is indirect or too actuated directly by the actuator.

at piezoelectric actuators occur due to high switching speeds and high inner powers strong vibrations during their operation. These vibrations are spectrally very broadband and generate a high level of structure-borne noise. That structure-borne noise is used in a fuel injector from the whole Engine block reinforced and by the user of the motor vehicle as a metallic, disturbing rhythmic noise perceived.

The frequency spectrum of a current driving the piezoelectric actuator (cf. 5 Control current IST) has a maximum in a frequency range between 7 and 13 kHz. This maximum of the control current leads to the piezoelectric actuator being excited by the control current in the audible range.

at the control of a piezo actuator as a drive in a fuel injector Currents are used required in the range of 30 A and rise times of less than 50 μs. The strong slope changes Mechanical vibrations stimulate in the current course of the control current.

There Internal combustion engines, especially diesel engines, due to such mentioned soft combustion process by multiple injection and / or Charging can be achieved, becoming quieter, it is perceived as a nuisance, that the noise of the piezoelectric actuators from the total noise of the To hear the internal combustion engine is.

From the published application DE 199 46 965 A1 a silenced piezoelectric drive is known. In this piezoelectric drive, the piezo element is surrounded by a housing which is at least partially made with an outer layer made of a material with vibration-damping properties. In this known drive, the structure-borne noise is reduced in that it is prevented from being transmitted and propagated by a suitable mechanical decoupling and isolation.

Further procedures exist that are about Sensors record the vibrations of the entire system and through a counteract adaptive control of vibration. Also exist Approaches, by means of suitable antiphase excitation after the actual one first control of the piezoelectric drive the vibrations counteract.

task the invention is a circuit arrangement for reducing Sound emissions and high frequency vibrations of a piezoelectric To create an actuator.

This The object is achieved by a circuit arrangement according to claim 1.

Between a unit controlling the piezoelectric actuator and the actuator even an electronic filter is arranged. This filter filters out the frequency components of a signal driving the piezoelectric actuator out the cause of which as disturbing perceived noise emissions and the high-frequency vibrations of the piezoelectric actuator.

advantage the circuit arrangement according to the invention is that from the control unit, the piezoelectric Actuator and the existing system operated by the actuator only needs to be supplemented by at least one filter and no constructive changes must be carried out on the system.

In case of changes on this system, the filter can be easily connected to one changed system frequency response be adjusted.

advantageous Embodiments of the invention are described in the subclaims.

In an advantageous embodiment of the invention, the filter the piezoelectric actuator can be connected in series. The filter is designed here so that its resonance frequency is in the range of disturbing Components lies and the impedance of the filter in this Is high-impedance and so the disruptive components from the Driving current of the piezoelectric actuator are filtered.

In a further advantageous embodiment of the invention, the filter is arranged parallel to the piezoelectric actuator. The properties of the filter are also selected here so that the resonance frequency is in the range of the interfering components and thus the interfering components of the pi ezoelectric actuator are "sucked away" (so-called suction circuit).

Becomes the piezoelectric actuator for operating a fuel injector an internal combustion engine used, so can easily disturbing in this application Components of the control signal are filtered. Kick due to of changes Changed acoustic on the fuel injector or on the internal combustion engine Requirements on the actuator, so the filter can be simple Way to be adjusted.

Based the schematic drawings are several embodiments the circuit arrangement according to the invention exemplified. Show it:

1 2 shows a block diagram of a first exemplary embodiment of a circuit arrangement according to the invention,

2 2 shows a block diagram of a second exemplary embodiment of a circuit arrangement according to the invention,

3 2 shows a block diagram of a third exemplary embodiment of a circuit arrangement according to the invention,

4 a block diagram of a fourth embodiment of a circuit arrangement according to the invention, and

5 the amplitude response of several currents driving the piezo actuator.

1 shows a first embodiment of a circuit arrangement according to the invention. This has a control unit V with a voltage amplifier, an ohmic output stage, a current amplifier or a charge amplifier. The control unit V controls at least one piezoelectric actuator P with a control current IST. A filter F1 is on the one hand electrically connected to the control unit V and on the other hand to the piezoelectric actuator P. The piezoelectric actuator P is electrically connected via its second connection to a second connection of the control unit V.

The frequency spectrum of a drive current IS, as it is for example in 5 is shown, has in a frequency range between 7 and 13 kHz signal components which prove to be disruptive during operation of the piezoelectric actuator P because of the mechanical vibrations generated by these frequency components.

The filter F1 is connected in series with the piezoelectric actuator P. The filter F1 is preferably a parallel resonant circuit which has a capacitor C and a coil L which are arranged in parallel with one another. This parallel resonant circuit is flowed through by the control current IST, which drives the piezoelectric actuator. The filter F1 represents a so-called “blocking circuit”, whose impedance for the area around the resonance frequency f _R is large with a corresponding bandwidth and dampens the frequency components of the control current IST lying in this area. By a suitable choice of the resonance frequency f _R and the bandwidth of the Parallel resonant circuit, that is, by suitable choice of the capacitor C and the coil L, disturbing frequency components of the control current IST can thus be kept away from the piezoelectric actuator P, which improves the acoustic behavior of the piezoelectric actuator P.

2 shows a block diagram of a second embodiment of a circuit arrangement according to the invention. Here, functionally identical components have the same reference numerals as in 1 ,

In contrast to the exemplary embodiment 1 a filter F2 is arranged parallel to the piezoelectric actuator P. This filter F2 is preferably a series resonant circuit - a series circuit of a capacitor C and a coil L - which has a small impedance at its resonance frequency f _R and thus practically an electrical one when the filter F2 is excited in the range of the resonance frequency f _R Represents short circuit. This filter F2 is also referred to as a "suction circuit". It "sucks" the frequency components of the control current IST in the frequency range around the resonance frequency f _R.

3 shows a combination of the embodiments of FIG 1 and 2 , Here, a first filter F13, preferably a parallel resonant circuit, is arranged in series with the piezoelectric actuator. A second filter F23, preferably a series resonant circuit, is arranged in parallel with the series connection of filter F13 and piezoelectric actuator P.

If the same resonance frequency f _{R is} selected for the filters F13 and F23, the damping increases in the range around the resonance frequency f _R. Alternatively, the filters F13 and F23 can be suitably tuned to two slightly offset resonance frequencies f _R13 and f _{R23 to increase} the bandwidth of the filter consisting of F13 and F23 and thus the range in which the control current IS is damped.

4 shows another embodiment of a circuit arrangement according to the invention. Here is a filter F24 the piezoelectric actuator P connected in series. This filter F24 is preferably a series resonant circuit. This so-called “control circuit” only lets through the frequency components of the control current IST that lie in the range of the bandwidth of the filter F24. The bandwidth of the filter F24 is coordinated such that only the frequency components of the control current IST that are in operation of the piezoelectric actuator P are not perceived as disturbing.

The The bandwidth of the filter F depends on the quality of the respective filter F dependent and denotes the area in which the filter's apparent resistance or the signal level is greater than or equal 70.7% (-3dB) of the maximum value - the occurs at the resonance frequency fR - is.

5 shows the amplitude response of the control current IST for an unfiltered control current IST1, one with a circuit arrangement according to 2 filtered control current IST2 and one with a circuit arrangement according to 3 filtered control current IST3.

The filtered control current IST2 indicates at a frequency of 10kHz Minimum on. Compared to the course of the unfiltered control current IS are the amplitudes of the control current IST2 in the frequency domain 10KHz smaller.

Comes a filter arrangement with a filter F23, F13 arranged in parallel and in series - as in 3 is shown - the amplitudes in the frequency range between 7 and 13 kHz can be reduced even further and the acoustic properties of the piezoelectric actuator P can be further improved.

The Filters F1, F2, F12, F23 and / or F24 used here are preferred housed together with the control unit V in a housing. The filters F1, F2, F12, F23 and / or F24 can but also together with the piezoelectric actuator P in one casing be arranged.

at Filters F1, F2, F12, F23 and F24 can be analog, as well as digital filters.

Claims (3)

Circuit arrangement for reducing noise emissions and high-frequency vibrations of a piezoelectric actuator, that has - one Control unit (V), of which the piezoelectric actuator (P) with a drive current (IST) is driven, and - at least a filter (F1, F2, F12, F23, F24) that can be used in parallel or in series with piezoelectric actuator (P) is switched, where that or the filters (F1, F2, F12, F23, F24) in the acoustically disturbing frequency range a small or a large one Have impedance. Circuit arrangement according to claim 1, characterized in that a first filter (F13) in series with the piezoelectric actuator (P) is connected and a second filter (F23) in parallel to the series connection from the first filter (F13) and the piezoelectric actuator (P) is switched. Circuit arrangement according to claim 1 or 2, characterized characterized in that the piezoelectric actuator (P) is a fuel injector controls an internal combustion engine.