DE102005024412A1 - Circuit board for use in motor vehicle, has piezo unit arranged at surface point of board and formed by piezo sensor, with which oscillation frequency and amplitudes are determined by oscillation stimulation of board - Google Patents

Abstract

The board has a piezo unit arranged at a surface point of the board with an oscillation deflection. The piezo unit is formed by a piezo sensor (2), with which oscillation frequency and amplitudes are determined by oscillation stimulation of the board. A memory unit is coupled with an amplitude-threshold value sensor and the piezo sensor such that an amplitude-threshold value signal is emitted by the amplitude-threshold value.

Description

The The invention relates to a circuit board as a planar component, in particular for a Motor vehicle, according to the preamble of claim 1.

components in particular large-scale components of a Motor vehicles are being used during driving by body and / or airborne sound to vibrate, on the one hand in the Vehicle interior a disturbing background noise can generate and at certain vibration amplitudes a damage can cause.

As a measure for reducing the noise caused by the vibrations, an active silencing can be provided on the flat component designed as a board. So z. B. from the JP 2000148155 A a board known as a planar component, occur at the vibration excitation at certain areas vibration deflections due to natural oscillations. For applying a controlled counter-movement piezo elements can be arranged at such a surface location.

Furthermore, in the DE 40 25 564 C1 a device for detecting impact damage to a board described. In this case, a plurality of piezoelectric film pieces are seen in front of an outer side of the board, which are arranged in a predetermined screening with defined distances from each other. With all film pieces a monitoring device is connected, with which a damage-related capacitive change in charge of the piezoelectric films is to be determined.

task The invention is designed as a flat component Board, especially for one Motor vehicle, to create, for the simple and reliable Way a damage analysis can be done.

These Task is solved with the features of claim 1.

According to claim 1, the at least one piezoelectric element is formed by a piezoelectric sensor, by means of at a vibration excitation of the board, a vibration amplitude is detected. There is also a memory unit coupled to the piezo sensor coupled to an amplitude threshold generator such that when exceeded a detected vibration amplitude over a through the amplitude threshold predefinable amplitude threshold an amplitude threshold signal for one further processing is delivered.

Additionally or Alternatively, the at least one piezoelectric element can be replaced by a Piezo sensor be formed by means of a vibration excitation the board is detected an oscillation frequency. Moreover, in a memory unit coupled to the piezoelectric sensor, the natural frequency stored at the detection location of a faultless board. With a Natural frequency threshold generator the detected vibration frequency is comparable to the stored natural frequency, with a deviation around a predefinable frequency value between the detected vibration frequency and the stored natural frequency a natural frequency threshold signal for further processing is delivered.

With Such a board can easily damage analysis for the Board performed become. For example, the amplitude threshold may be the maximum amplitude for the highest allowable voltage or Deflection of the board in the vibration excitation specified be such that when exceeded this maximum amplitude limit amplitude as a corresponding error message is stored and thus the maximum deformation detected and can be stored in the storage unit. In response For example, with an associated control / control device an error message are displayed.

Complementary or Alternatively, even with a detection of the oscillation frequency by means of the piezo sensor during a vibration excitation of the board this detected vibration frequency with one in the memory unit stored natural frequency at the detection of the error-free Board are compared. These stored in the memory unit Natural frequency of the board is in advance z. B. experimentally and / or determined by calculation in conjunction with a faultless board, so that at a deviation of the detected oscillation frequency of the stored natural frequency by a predefinable frequency value, those with the natural frequency threshold is determined, a natural frequency threshold signal for another Processing is submitted. Advantageously, a storage takes place here in a storage unit. The deviation between the detected and the stored frequency is due to a change in the structural characteristics attributed to the board, so that with it any damage the board can be determined easily.

In a preferred embodiment According to claim 2, the amplitude threshold signal and / or the natural frequency threshold signal for processing as an error message signal an error message display and / or an error message memory can be supplied. The error message display allows an immediate response to the delivered threshold signals, which may mean possible damage to the board. The error message memory can be read, for example by means of a diagnostic device, so that then the threshold signals can be evaluated.

In a further embodiment according to claim 3 is the at least one piezoelectric sensor each at least one piezoelectric actuator assigned close to the place. The piezo sensor, the amplitude threshold, the natural frequency threshold and the piezo actuator are advantageous connected to a control / control device which is present an amplitude threshold signal and / or a natural frequency threshold signal an actuator control signal outputs, by means of which the piezo actuator a opposite the with the piezo sensor detected vibration out of phase beat vibration produced to obtain a load-reduced total vibration. Through this phase-shifted overlay oscillation generated by the piezo actuator is an active reduction of in particular by body and / or Airborne sound produced vibration excitation, so that the load on the board as a whole is advantageously reduced. Here you can especially through body and / or airborne sound generated vibration amplitudes greater than the predetermined amplitude threshold are to be reduced, so that an overrun a permissible one Voltage and deflection of the board is reliably avoided. Also the noise generated by the vibration excitation of the board can by this measure be reduced advantageous. The board thus offers here in one Advantageous multiple function the possibility of using the piezoelectric sensor perform a damage analysis based on the detected vibration amplitudes, and further the possibility by the phase-shifted superimposition oscillation generated by means of the piezoactuator, a reduction of the load of the board in connection with a Achieve sound reduction.

In a development according to claim 4 can in each case two amplitude threshold values and two natural frequency thresholds can be specified. It can a beat vibration when exceeded a lower threshold and an error message when exceeding one upper threshold value. The lower threshold can be be so predetermined that when exceeding the same one Damage to the Board is avoided and the corresponding overlay vibrations to Load reduction can be provided. The upper threshold can be specified so that when exceeding the same one damage the board is created, with the associated threshold signal, for example stored in a memory unit as an error message.

alternative or additionally can according to claim 5 the at least one piezoelectric actuator for a vibration excitation the board by means of the control / regulating device a specifiable actuator signal are supplied. The generated thereby Oscillation frequency of the board is by means of at least one Piezo sensor detected and the control / regulating a corresponding Sensor signal supplied. is the memory unit is coupled to the control device, for example, with an associated comparator unit the detected vibration frequency with the natural frequency of a fault-free Board are compared, with a detected deviation an error message is issued. The shift of the natural frequency the board finally shows to injury the same way. Through the active generation of vibrations by means of The piezo actuator can thus at any time a damage analysis performed the board become. In this case, for example, via a piezo actuator a defined Actuator signal are introduced into the board, wherein the detection of the thereby produce vibrations of a plurality of piezoelectric sensors carried out which then becomes a so-called transfer function form. Here you can in the memory device also those in advance in error-free Printed circuit boards experimentally determined transfer functions so that by means of the comparator unit these transfer functions be compared to any deviations.

In a further embodiment according to claim 6, the control / control device associated with a power amplifier be by means of which the sensor signal can be amplified. By this metrological reinforcement The sensor signals will be a reliable evaluation of the damage analysis Simplified board.

In a further preferred embodiment according to claim 7, the board may be formed multi-layered, wherein the or the piezoelectric element (s) are preferably arranged in the parting plane between two adjacent layers. In a vibration excitation of such a multilayer board occur at areas in the region of the vibration deflections in the oscillating direction and varying in the oscillation frequency tensile / compressive stresses in conjunction with layer strains, starting from a middle region of the layer thickness in the manner of neutral fiber without tensile / compressive stresses in the direction of the outer layer thickness ranges larger. If the multilayer board is constructed in only two layers, it should be ensured that these layers have different material thicknesses, so that the piezoelectric element in the parting plane is not arranged in the tensile / compressive stress-free neutral fiber. It is therefore particularly preferred for the printed circuit board to have at least three layers, so that even with the same material thickness of all layers, the dividing planes and thus the arrangement of the at least one piezoelectric element can always take place in a region spaced from the neutral fiber. Although a weak point of the multilayer board is formed by the at least one piezoelectric element arranged in the parting plane of two adjacent layers of the multilayer board, since only a short length and layer section of the composite of the multilayer board is disturbed by the at least one piezoelectric element, the overall composite is only insignificantly weakened. so that a shear failure with a possible shear failure of the multilayer board is excluded.

In a development according to claim 8, the at least one piezoelectric element can be provided by a piezoceramic film element be formed, the film surface plane parallel in the parting plane runs and their electrical connection cables also run in the parting plane and led out of there from the board. Due to the area parallel Arrangement of the at least one piezoelectric element in the parting plane the entire composite of the multilayer board is only slightly disturbed, so that thereby the entire stability the multilayer board is largely unaffected. Are a majority of piezo elements, for example as piezo sensors and piezo actuators, arranged in the or the parting planes of the multilayer board, so It is advantageous to use the individual connection cables of the respective To lead piezoelectric elements to one side of the multilayer board, so that there is a corresponding summary and coupling, for example to the assigned control device, can be done.

In a further embodiment according to claim 9, the multilayer board may be fabricated as a fiber composite laminate construction be, in which the at least one piezoelectric element is laminated. It can the individual layers of the fiber composite laminate construction by tissue and / or knitted fabric and / or knitted fabric and / or braid and / or flow be. Independently from the embodiment of the fiber composite laminate structure, the at least one piezoelectric element simple and reliable in the parting plane between two layers of the fiber composite laminate construction. Basically Lich the at least one piezo element also with a sewing technique be incorporated into the fiber composite, which is an easy way to the local Fixing the at least one piezoelectric element represents.

In a further embodiment can according to claim 10 may be provided on the board a plurality of piezo elements, being at the surface locations a piezoelectric element arranged in each case a certain maximum vibration can be. At a vibration excitation of the board in different Fashions are at several surface locations the board oscillation maxima possible. These area locations with the associated oscillation maxima, the areas of the Board with the highest Structural loads, so that an arrangement of the piezoelectric elements at these areas is particularly advantageous to this particular with piezo actuators To counteract oscillation maxima.

In a concrete embodiment according to claim 11, the board can be replaced by a roof or a roof part of a Be formed motor vehicle. In principle, other large-scale motor vehicle parts through a board with appropriately introduced and arranged Piezo elements are formed. Beyond the possibility of a damage analysis also the reduction of the background noise generated by the vibrations, so can the board for Such motor vehicle parts are used, which are connected to the vehicle interior connect, such as B. door panels. in principle but also, for example, the front hood and the boot lid by a circuit board according to the invention be formed, since here in particular the possibility of damage analysis is beneficial.

Based a drawing, the invention is explained in detail.

It demonstrate:

1 a schematic plan view of a circuit board according to the invention, wherein arranged on the board piezo elements are connected to a control / control device,

2 1 is a schematic representation of a diagram in which the detection of a vibration amplitude is graphically represented;

3 a schematic representation of a graph in which a graph of a vibration frequency is shown graphically, and

4 a schematic sectional view through the board.

In 1 is a schematic plan view of an inventive, a certain areal extent and a certain layer thickness having board 1 represented, which is arranged with certain installation properties in a composite component. On the board 1 are exemplary and only very schematically arranged eight piezoelectric elements, wherein four of the piezoelectric elements by piezoelectric sensors 2 and the other four by piezo actuators 3 are formed. In each case a piezo actuator 3 is a piezo sensor 2 associated, which graphically by the spatially adjacent representation each of a piezoelectric sensor 2 and a piezo actuator 3 is expressed. The arrangement of the piezo elements 2 and 3 on the board 1 occurs at surface locations of the board 1 in which at a vibrational excitation of the board 1 Vibration deflections arise. These are preferably surface areas of the board 1 in which maximum deflections are to be expected in the case of the oscillations that occur, which is determined experimentally and / or by calculation in advance, for example.

The four piezo sensors 2 are with a control / control device 4 connected, starting from a power amplifier 5 a connection to the four piezo actuators 3 consists.

At a vibration excitation of the board 1 can by means of the piezo sensors 2 a vibration amplitude can be detected. The control / control device 4 also has a memory unit with an amplitude threshold, so that the of the piezo sensors 2 generated sensor signal corresponding to the detected vibration amplitude, in the control / control device 4 is compared with the predetermined by the threshold amplitude threshold. When exceeding the detected oscillation amplitude over the predetermined amplitude threshold value, this amplitude threshold signal in the memory unit of the control / control device 4 stored. In addition, by means of the control / control device 4 the piezo actuators 3 an actuator signal are supplied so that the piezo actuator 3 as vibration response performs a phase-shifted beat vibration, whereby the initially generated vibration of the board 1 reduced or completely suppressed.

Additionally or alternatively, with the piezo sensors 2 at a vibration excitation of the board 1 an oscillation frequency can be detected. In the rule / control device 4 is in the memory unit, the natural frequency at the detection of a faultless board 1 stored in advance, which was determined experimentally and / or by computer-aided calculation. With a natural frequency threshold, which is also in the control / control device 4 can be integrated, the detected oscillation frequency is compared with the stored natural frequency, wherein in a deviation of the detected oscillation frequency of the stored natural frequency by a predetermined frequency value, an error message is stored in the memory unit. The vibration excitation of the board 1 to check the vibration frequency generated thereby can also by the piezo actuators 3 be generated. Ie. specifically, that the piezo actuators 3 for a vibration excitation of the board 1 by means of the control / regulating device, a predetermined actuator signal is supplied. The generated oscillation frequency is determined by means of the piezo sensors 2 detected and supplied as a sensor signal of the control / regulating device. There, a comparison is made between the detected oscillation frequency and the stored natural frequency of the board.

In 2 schematically a diagram is shown, in which graphically by the piezo sensors 2 recorded vibration amplitudes are plotted against the frequency. These detected values are indicated by a solid line in 2 located. In addition, an amplitude threshold is an example 6 drawn with a dotted line, taking off 2 it can be seen that a detected oscillation amplitude exceeds the amplitude threshold value. This overshoot may occur in the memory unit of the control device 4 be stored as an error message and checked for example in a subsequent quality control with associated readout of the fault memory. In addition, there is the possibility according to the detected vibration amplitudes by the associated piezo actuators 3 phase-shifted superposition oscillations, thereby reducing the load on the board 1 be reduced. This is graphically with a dash-dotted line in 2 shown, wherein, as is further apparent from this, none of the then detected vibration amplitudes the amplitude threshold 6 exceeds.

In 3 is schematically one by means of the piezo sensors 2 detected vibration frequency shown. The solid line graph represents the oscillation frequency of a faultless board 1 the dashed line graph represents the vibration frequency of a board 1 with a damage to the structural properties. Is, for example, a vibration frequency according to the course of the dotted line by means of the piezoelectric sensors 2 detected, for example, with a comparator unit of the control / control device 4 , in which the oscillation frequency of a faultless board 1 stored, a deviation between the frequencies detected. This means in this example a shift to lower natural frequencies due to the reduced rigidity of the board 1 , so that an error message in the memory unit of the control / regulating device 4 saved becomes.

Overall, therefore, with the inventive detection of the vibration amplitude and / or the vibration frequency, a damage analysis of the board 1 be carried out in a simple and reliable way. On the one hand, when a predefinable amplitude threshold value is exceeded 6 with damage to the board 1 to calculate and on the other hand, in a shift of the detected oscillation frequency with respect to a stored oscillation frequency of a faultless board 1 to a weakening of the structural properties of the board 1 be inferred. By generating phase-shifted superposition oscillations by means of the piezo actuators 3 can damage the board 1 be counteracted at large vibration amplitudes, and also with this measure, a noise produced by the vibrations can be reduced in sound.

In 4 is a schematic sectional view through the board 1 shown, the board 1 is designed here as a multilayer board. The cutting guide is chosen so that in the illustration shown, the material thickness of the multilayer board 1 and the corresponding superimposed individual layers 7 can be seen. The multilayer board 1 is manufactured as a fiber composite laminate construction, so that by different hatching of the individual layers 7 the multilayer board 1 correspondingly different oriented fibers for the individual layers 7 of the fiber composite structure are shown schematically. In the dividing planes 8th between the layers 7 the multilayer board 1 are the piezo elements 2 and 3 arranged to the respective parting plane 8th run parallel to the surface. Electrical connection cable 9 the individual piezo elements 2 and 3 also run in the respective parting line 8th , Accordingly, the connection cables run 9 in the in 4 Selected representation of the multilayer board 1 perpendicular to the drawing plane, leaving the connecting cables 9 drawn for illustration technical reasons folded by 90 °.

In the middle region of the layer thickness of the multilayer board 1 is a neutral fiber 10 formed in the vibration deflection of the multilayer board 1 In the direction of the layer thickness ranges, these tensile / compressive stresses in connection with layer strains correspondingly increase, which is an example at two points of the multilayer board 1 in 4 drawn through, by the from the outside of the multilayer board 1 attacking arrows 11 . 11 ' such a force is shown schematically. With parallel to the layers 7 running arrows 12 is that due to the force effects 11 . 11 ' caused tensile / compressive stress within the multilayer board 1 located. This tensile / compressive stress curve is created with a corresponding vibration excitation of the multilayer board 1 in an analogous manner to the associated vibration deflections.

The piezo elements 2 and 3 are preferred at surface locations of the multilayer board 1 arranged with expected excursion maxima. The piezo elements 2 and 3 can, as in 4 shown on both sides of the neutral fiber 10 each in the appropriate parting line 8th be arranged at the respective surface locations of a certain maximum vibration. It Kings nen the opposite piezo elements as a piezo sensor 2 and as a piezo actuator 3 be executed so that through the piezo sensor 2 detects an example caused by body or airborne vibration excitation and a corresponding sensor signal of the control / control device 4 (not shown here) can be supplied. The piezo actuator 3 is by means of the control / control device 4 an actuator signal is supplied, so that the piezo actuator 3 as a vibration response generates a phase-shifted overlay vibration to reduce the vibration amplitude.

Claims (11)

Board as a planar component, in particular for a motor vehicle, with certain installation conditions in a composite component and resulting in a vibration excitation of the board natural oscillations as modes that arise at certain areas of the board with associated vibration deflections, wherein at least one piezoelectric element at a surface location of the board with a such vibration deflection is arranged, characterized in that the at least one piezoelectric element by a piezoelectric sensor ( 2 ) is formed, with which at a vibration excitation of the board ( 1 ) a vibration amplitude can be detected, wherein one with the piezo sensor ( 2 ) coupled to an amplitude threshold generator is such that when exceeding a detected oscillation amplitude over a predefinable by the amplitude threshold encoder amplitude threshold ( 6 ) is output an amplitude threshold signal for further processing, and / or that the at least one piezoelectric element by a piezoelectric sensor ( 2 ) is formed, with which at a vibration excitation of the board ( 1 ) an oscillation frequency can be detected, wherein in one with the piezo sensor ( 2 ) coupled memory unit, the natural frequency at the detection of a flawless Pla is stored and that with a natural frequency threshold the detected oscillation frequency with the stored natural frequency is comparable, wherein in a deviation by a predetermined frequency value between the detected oscillation frequency and the stored natural frequency, a natural frequency threshold signal is output for further processing. Board according to claim 1, characterized that the amplitude threshold signal and / or the natural frequency threshold signal for processing as an error message signal of an error message display and / or an error message memory is supplied. Board according to claim 1 or 2, characterized in that the at least one piezoelectric sensor ( 2 ) at least one piezo actuator ( 3 ), which is also locally close to the board ( 1 ), wherein the piezo sensor ( 2 ), the amplitude threshold value transmitter, the natural frequency threshold value transmitter and the piezo actuator ( 3 ) with a control / control device ( 4 ), which outputs an actuator control signal in the presence of an amplitude threshold signal and / or a natural frequency threshold signal in such a way that the piezo actuator ( 3 ) one opposite the one with the piezo sensor ( 2 ) detected vibration phase-shifted overlay vibration to obtain a reduced load overall vibration generated. Board according to claim 2 or 3, characterized in each case two amplitude threshold values and two natural frequency threshold values can be specified and an overlay vibration when exceeded at least one of the lower thresholds is generated and an error message when exceeded one of the upper thresholds takes place. Board according to one of claims 1 to 4, characterized in that the at least one piezoelectric sensor ( 2 ) at least one piezo actuator ( 3 ), which is also locally close to the board ( 1 ), wherein the piezo sensor ( 2 ), the amplitude threshold value transmitter, the natural frequency threshold value transmitter and the piezo actuator ( 3 ) with a control / control device ( 4 ) are connected in such a way that by means of the control / control device ( 4 ) the at least one piezoelectric actuator ( 3 ) a specifiable actuator signal is supplied for a vibration excitation of the board ( 1 ), so that the vibration frequency generated thereby by means of at least one piezoelectric sensor ( 2 ) is detected and a corresponding sensor signal of the control / control device ( 4 ) is supplied. Board according to one of claims 3 to 5, characterized in that the control / control device ( 4 ) a power amplifier ( 5 ), by means of which a sensor signal can be amplified. Board according to one of claims 1 to 6, characterized in that the board ( 1 ) an at least two-layer multilayer board is such that the at least one piezoelectric element ( 2 ; 3 ) in the parting plane ( 8th ) of two adjacent layers ( 7 ) is attached. Circuit board according to claim 7, characterized in that the at least one piezoelectric element ( 2 ; 3 ) is formed by a piezoceramic film element, the film surface in the parting plane ( 8th ) parallel to the surface and whose electrical connecting cable ( 9 ) also in the parting plane ( 8th ) and from there the board ( 1 ) are led out. Board according to claim 7 or 8, characterized in that the multilayer board ( 1 ) is produced as a fiber composite laminate structure, in which the at least one piezoelectric element ( 2 ; 3 ) is laminated. Circuit board according to one of claims 1 to 9, characterized in that a plurality of piezo elements ( 2 ; 3 ) on the board ( 1 ) is provided in such a way that at each point of a certain maximum vibration a piezo element ( 2 ; 3 ) is arranged. Board according to one of claims 1 to 10, characterized in that the board ( 1 ) is formed by a roof part of a motor vehicle.