DE3536921C2 - - Google Patents

Description

The invention relates to a piezoelectric Pickups for musical instruments, in particular for Stringed instruments, according to the preamble of claim 1.

Such a pickup is known from DE 31 00 326 C2 (1) and also known from DE 32 27 377 A1 (2). The the latter DE-OS corresponds to DE-GM G 82 16 744.3 (3). These known piezoelectric pickups are particular suitable for acoustic guitars by the Bridge insert of a normal acoustic guitar against the piezoelectric pickup with its bridge part is exchanged, the latter in its dimensions corresponds exactly to the channel cross-section for the web insert, or a corresponding adjustment of the dimensions can be carried out easily afterwards will. The piezoelectric pickup can also together with his magnetic pickup either at one acoustic guitar or an electric guitar (also: solid body guitar) can be used, which the possible variations of these two types of guitar can be increased because the guitar either only with the magnetic pickup, the piezoelectric pickup or operated both pickups at the same time can be.

The known piezoelectric pickups according to (1) to (3) have proven their worth in practice; the present Invention is the object of this known underlying piezoelectric pickups Building principle to develop in the direction that the The size of the pickup can be reduced even further can; in particular, a much slimmer design is intended to fit into very narrow recording channels for Bridge inserts can be achieved. A special problem with this desired reduction in size the reliable shielding and - if several piezoelectric sensors closely adjacent to each other in the Bridge part are arranged - the crosstalk attenuation. In other words, the vibration of a certain one If possible, the page should only be assigned to it Communicate the piezoelectric sensor and not the neighboring one. Shielding effect and are of considerable importance Crosstalk attenuation when using a stringed instrument in general and a guitar in particular the electronic component of a MIDI (musical instrument Digital interface). This MIDI serves for signal processing and for driving so-called Synthesizers that allow the sounds of certain instruments, e.g. B. organ, clarinet, trumpet or the like, can be replicated. The MIDI leads a frequency analysis, and it is essential that a sufficiently large amount of noise and noise Input signal from the pickup is supplied. From It would be a particular advantage if this was done with a piezoelectric Pickups could be achieved because this is independent of whether metal strings or Strings made of polyamide (trademark nylon) are used whereas the magnetic pickup only in the case of Metal strings can be used.

The invention has for its object the generic to design piezoelectric pickups so that he reduced one in size, especially has a leaner, more compact design while still being with regard to shielding effect, with regard to interference fields as well as superior in terms of crosstalk attenuation Has properties that open up the possibility with this pickup together with the associated one Musical instrument to control a so-called MIDI.

In particular, the new piezoelectric Pickups for stringed instruments with below the Strings and bridge inserts suitable for strings be, and here especially for guitars, d. H. preferably acoustic guitars, but to perfection the sound image even with electric guitars.

According to the invention, the task at one Generic piezoelectric pickups according to Preamble of claim 1 by the in the mark of the specified features solved. Beneficial Further developments are in the subclaims 2 to 7 specified.

The advantages that can be achieved with the invention are above all to be seen in the fact that the new piezoelectric pickup excellent in the extremely slim design electrical properties (shielding effect, high Crosstalk attenuation, very good reproduction of the string frequencies) which also make it suitable to serve as a signal generator for a so-called MIDI, whereby the signal amplitudes are relatively high, so that under Under certain circumstances without preamplifier or repeater and the MIDI can be controlled directly.

The time constant of the pickup (time difference between Striking the string and signal transmission) extremely low, so there is an advantage compared to a magnetic pickup. The pickup after the invention is, as mentioned, not specific String material bound.

The following is based on the drawing in which a basic embodiment with three variants is shown, the invention explained in more detail.

It shows in a partially schematic, not to scale Presentation:

Figure 1 shows a piezoelectric pickup according to the invention in a longitudinal section II of Figure 2, wherein the bridge board and the top of the body of the acoustic guitar, in which the pickup is installed, are not shown in Figure 1;

Fig. 2 shows the cross-section increases according to the line II-II of the pickup of Figure 1, strong, whereby the directly adjacent to the bridge part of the pickup parts of the Stegbrettchens are indicated in section.

FIG. 3 shows the detail X from FIG. 1, ie the passage of a positive conductor from below through a bore in the bottom wall of the bridge part and the connection electrode and the connection with a soldering support point;

Fig. 4 shows the detail Y of Figure 1, that is, a variant for the connection of Figure 3, wherein the connection electrode of the circuit board is not pierced, but only the bottom wall of the bridge part, so that the signal conductor is guided laterally to the soldering base.

Figure 5 is a plan view of a contact and shielding with a carrier foil made of copper, which is coated with a first layer of conductive adhesive and a second layer of insulating foil.

Fig. 6, the wrapping of a single piezoelectric body of a piezoelectric sensor by means of the corresponding pre-cut contact and shielding film of Figure 5, wherein the board piece shown above the piezoelectric body is included in the shroud, in a perspective view.

Fig. 7, the end result of a single piezoelectric sensor, created by sheathing a piezo body and the placed piece of circuit board with a contact and shielding film according to the principle of FIG. 6, also in perspective, and

Fig. 8 is also a perspective view of a formed of a plurality of individual piezoelectric bodies multi sensor arrangement for a pickup, wherein the escape of a plurality of individual piezoelectric bodies, is provided with a common circuit board, with a correspondingly longer contact and shielding film is coated.

The piezoelectric pickup TA according to FIG. 1 of an acoustic guitar (not shown in detail) with the strings e, a, d, g, h, e 'is inserted into the receiving groove 1 which can be seen in cross section in FIG. 2 instead of a normal bridge insert. The receiving groove 1 runs transversely to and below the strings e, a designated as a whole by GS . . . and is incorporated, in particular milled, into the footboard indicated at 2 in FIG. 2. The receiving groove has two plane-parallel groove flanks 1 a , 1 b and a groove base 1 c running at right angles thereto, the web board 2 below the groove base 1 c with suitable recesses in the form of grooves and / or bores for passing shielded signal lines is provided, of which a bore is indicated at 3 . These recesses in the bridge continue in the body of the guitar, so that the signal lines can then be routed to a jack socket attached to the guitar frame and / or to a preamplifier or other electronic signal processing stage.

Corresponding to the cross-section of the receiving groove 1 , the metallic bridge part 4 , which forms a housing for at least one piezoelectric sensor S with its interior, is of approximately U-shaped cross-section (see FIG. 2), the two planar-parallel and planar parallel boundary surfaces 4.1, 4.2 side walls with 4 a and 4 b and the bottom wall connecting the two side walls 4 a , 4 b are designated with 4 c . Furthermore, the bridge part designed in the manner of an elongated tub has 4 end wall sections 4 d and 4 e at both ends (see FIG. 1). The bridge parts are designed as inwardly drawn reinforced edge parts.

A single one of the piezoelectric sensors S shown in FIG. 2 is mounted in the interior of the bridge part 4 between a base-side base surface 4.3 of the bridge part and an associated cover-side pressure piece 5 . The piezo body 6 of the sensor S is a cuboid locking element with a rectangular cross section. In general, it can be a prismatic locking element whose cross-sectional area is not only square or rectangular, as shown, but also hexagonal, octagonal or the like.It is essential that two plane-parallel piezo body surfaces are present, a base area 6.2 and an opposite top surface 6.1 . The piezo body 6 is a crystal or ceramic body, e.g. B. from barium or lead titanate. Its base and top surfaces 6.2, 6.1 are each metallized to form and form contact surfaces by means of very thin precious metal layers 7 . Gold plating in particular is used as the metallization. The base area 6.2 and the top area 6.1 of the piezo body 6 can therefore also be referred to as the lower and upper contact area. One of these contact surfaces is, as will be explained, with a ground polarity and the other contact surface is contacted with a counter-polarity, in particular a plus potential, from corresponding electrical connecting lines, the latter, as already explained, to an electrical or electronic signal processing stage (not shown) or to a (also not shown) jack socket on the guitar frame.

The piezo body 6 , the opposing plane-parallel side flanks of which are designated 6.3 and 6.4 , is, together with a circuit board 8 attached to its underside, consisting of an electrode strip 8.1 which is in contact with the lower contact surface 6.2 and which is made of electrically good conductive metal, in particular copper, and consisting of a Isolierstoffträgerleiste 8.2, "wrapped" for the electrode strips 8.1, in a contact and shielding 9, in particular consisting of copper or encased by this film. 9 The casing, designated as a whole by M , also includes layers 10 made of conductive adhesive, which are arranged on the inside of the copper foil 9 or applied to it, and insulating material layers 11 , which the side flanks of the piezo body 6 and the side flanks of the circuit board 8 to the inside of the Cover copper foil 9 or isolate it electrically.

In any case, the piezoelectric sensor S has retained its rectangular cross-sectional structure in spite of its sheath M , so that it with its plane-parallel side flanks S ₃ , S ₄ with little play of about 0.05 to 0.1 mm into the interior of the bridge part 4 which forms a receiving groove for the sensor S can be shown to be inserted, as described with reference to FIG. 1, FIG. 2. The pressure piece 12 , which is made of a tough-elastic plastic or metal, e.g. B. brass, may have a cross-sectionally rectangular neck portion 12 a with mutually plane-parallel side flanks 12 a 1 and a compared to neck portion 12 a widened head portion 12 b with the two shoulders 12 b 1 , the widened side flanks 12 b 2 and the bevelled top surface 12 b 3 . This pressure piece 12 , as symbolized by the arrow P _GS , is exposed to the pressure of the string tension of the guitar string in engagement with it; there are the vibrational forces exerted when the string strikes the pressure piece 12 in the direction of the arrow P _GS defined on the sensor S because S is supported on the inner sides 4.1 of the side flanks 4 a , 4 b of the bridge part 4 with little play precisely guided in the string pressure direction is. In this way, the string vibrations are non-positively transmitted to the respective piezoelectric sensor S , the latter resting on the bottom surface 4.3 of the bridge part 4 . The distance 13 between the shoulder surfaces 2 b 1 of the pressure piece head 12 b and the end faces 4.4 of the side flanks 4 a , 4 b of the bridge part 4 is so large that the shoulders 12 b 1 do not come into contact with the end faces 4.4 even when the greatest string forces occur can come, so that a hindrance to the power transmission can not occur. In a practical embodiment, this distance 13 is approximately 0.5 to 1 mm.

In particular, Fig. 2 shows that the copper foil is directly contacted with the first contact surface 6.1 of the piezoelectric body 6 as a ground electrode 9. The conductive adhesive 10 , which is a non-hardening or non-hardened synthetic resin adhesive with embedded particles of conductive material, in particular of copper, thus contributes to a safe contact, the size of the metal or copper particles being in the μ range. The copper foil 9 is wrapped around the overall arrangement 6 - 8.1 - 8.2 and is double-layered on the underside of the sensor S with the inner layer 90 and the outer layer 91 and the layers 100 and 101 of conductive adhesive located therebetween, and with the underside of the outer Copper foil layer 91 , which is bare, the copper foil 9 is pressed in a contacting manner against the base surface 4.3 of the bridge part 4 .

As mentioned, the copper foil 9 is insulated from the second contact surface 6.2 of the piezo body 6 forming the opposite polarity, in particular a plus polarity, and from its piezoelectrically neutral side flanks 6.3 , 6.4 , each by an insulating layer 11 .

The second contact surface 6.2 is now in direct contact with the electrode strip 8.1 of the circuit board 8, which is made of highly conductive metal, preferably also copper, the electrode strip 8.1 being applied to the insulating carrier strip 8.2 of the circuit board 8 and, as is shown in FIGS. 1, 3, 4 and 7, 8 show in more detail that a piece 8.1 a of the electrode strip 8.1 or the board 8 protruding beyond the piezo body serves as a connecting electrode for a signal line of the opposite polarity. Fig. 1, 3 and 4 show that a bare end 14.1 of a signal conductor 14 is connected to this terminal electrode 8.1, preferably by means of soft soldering in the form of a Lötstützpunktes 15 of low temperature solder, wherein the Isolierstoffmantel of the opposite polarity leading conductor 14 and 14.2 and its shielding jacket are designated with 14.3 . The counter potential or the counter polarity is in particular a plus potential, although in principle the counter polarity can have a minus potential with respect to mass. For the sake of simplicity, the following is referred to as the plus conductor and plus potential because this is a widespread version.

It can be seen from FIG. 1 that each individual guitar string GS is assigned a pressure piece 12 and a sensor S arranged below the pressure pieces, the sensors following one another in axial alignment with one another but axially spaced apart. Rethinking respectively the pressure element 12 the not filled by the piezoelectric body 6 and the sensor S terminal space 16 of the terminal electrode and a 8.1 holds the adjacent piezoelectric body 6 and the sensor S with the pressing piece 12 at a distance. This means that the adjacent pressure pieces 12 touch each other in such a way that they can move independently of one another in the string pressure direction P _GS (see FIG. 2); in the fully inserted state, they hold the sensors S below them in position by friction, which are then completely fixed when the string pressure forces act. To mount the pickup TA, the above-mentioned frictional forces are sufficient to keep it in place; however, it would also be possible to secure the position of the sensors S by means of a soft, elastic, non-curing synthetic resin adhesive within the bridge part.

For a better understanding of the winding direction of the copper foil 9 , its individual sections are indicated in FIG. 2, starting with the lowest film section 90 clockwise with 9.1, 9.2, 9.3 , and the lowermost or outermost film section, as mentioned, with 91 . The Isolierstoffträgerleiste 8.2 of the board 8 z. B. from an epoxy resin impregnated glass fabric; Between it and the electrode strip 8.1 (copper cladding), an adhesive layer 17 made of curable epoxy resin adhesive can expediently be provided for fastening the electrode strip.

It can be seen from the embodiment of FIG. 1 to FIG. 3 and FIG. 6 and FIG. 7 that each individual piezoelectric body 6 of the sensors S with an associated printed circuit board 8 and the corresponding layers of insulating material 11 is covered by a respective separate copper foil 9 and the positive conductor 14 each a separate shielded signal line 140 insulated to the connection electrode 8.1 a of the board 8 and connected there. This design guarantees excellent mutual shielding and high crosstalk attenuation in a size of more than 90 db between adjacent sensors S , so that the sensor signals have such a low noise and interference voltage level and such a high useful amplitude that one can deal with these signals over one so-called MIDI synthesizer can control. This is possible in a single arrangement (e.g. FIG. 2 can be the single arrangement) or in a multiple arrangement of the sensors S , as shown in FIG. 1. According to the preferred embodiment, the underside serves as the second contact surface 6.2 of the piezo body 6 , the insulated conductor 14 of the plus polarity of the signal line 140 being guided through holes 18 in the bottom wall 40 c of the bridge part 4 from below into the connection space 16 and with a bare connection end 14.1 is connected to the connection electrode 8.1 a as a base, in particular is soldered on, as already stated. . In the variant of Figure 3 c is aligned with the bore 18 in the bottom wall 4, a further hole 19 in the terminal electrode 8.1 a; the bore 18 is located in the embodiment variant according to FIG. 4 in the bottom wall 4 c of the bridge portion 4 laterally offset to the terminal electrode 8.1 a, so that the positive conductor 14 is bent laterally with his bare terminal end 14.1 brought to the soldering terminal 15 °. In both solution variants according to FIG. 3 and FIG. 4, the shielding sleeve is brought 14.3 to the bottom wall 4 c and advantageously out a small piece within the bore 18 and fixed in this position under electrical contact-making with the bottom wall 4 c. As shown schematically, the individual signal conductors or plus signal conductors 140 are brought together or bundled to form a common shielding jacket 20 . This can still be done within a corresponding recess in the footboard or when the signal conductors are passed individually through the body ceiling within the interior of the body. The mass of the shielding jacket 20 is then soldered to the soldered joint 22 with a bent tongue 21 of the bridge part 4 . The string pressure forces are best transmitted to the piezo body 12 or the sensors S when - as shown in FIG. 1 - the center of the pressure pieces 12 coincides with the center of the sensors S.

Fig. 5 shows that serving as a contact and shielding copper foil 9 is a carrier film, which on its side facing the piezoelectric body is provided inside with an electrically conductive adhesive layer 10th In the unprocessed state of the carrier film 9, this adhesive layer 10 is laminated by an insulating release film 11 divided into strips 11.1 to 11.5 . In order to form the insulating material layers 11 covering the side flanks 6.3, 6.4 of the piezo body 6 and the side flanks of the circuit board 8 , the corresponding stripping film strips 11.2 and 114 remain in their adhesive position, as is also illustrated in FIG. 6, whereas those with the first contact surface 6.1 of the piezo body 6 are closed Contacting carrier film sections 9.2 and the strips of carrier film sections 90 , 101 to be folded over the board 8 can be exposed by pulling off the corresponding peeling film strips 11.3 or 11.1, 11.5 . As can be seen from the section lines 22 in FIG. 5, corresponding sections of the “sandwich” film 9, 10, 11 can be cut off in the individual coating of the piezo bodies 6 and then placed around the piezo crystal 6 according to FIG. 6. If the piezoelectric crystal 6 according to FIG. 6 has been encased in accordance with FIG. 2, the sensor arrangement S shown in perspective in FIG. 7 is obtained, however the sensor position from FIG. 6 can be rotated through 180 ° about the x-axis one arrives in the position according to FIG. 7. The copper foil 9 with its conductive adhesive layer 10 expediently does not coat the piezo body 6 over its entire axial length; At the ends of the piezo crystal there remain small uncoated projections 6.5, 6.6 , which increases the security against leakage currents. After the sheathing, the ends 90, 101 of the copper foil 9 are brought into close contact by exerting pressure forces in the direction of the arrows 23 , but the other shell surfaces are also “ironed” during the sheathing, with the application of corresponding pressure forces 24 . A film which has been found to be a "sandwich" film and which consists of a copper carrier film with applied, highly conductive adhesive containing conductive copper particles, the adhesive layer being covered by peelable paper strips or peelable plastic film strips.

Where the piezoelectric pickup is not to be used to control a MIDI, a sensor structure according to FIG. 8 can also be useful. The sensor denoted here by S ' is formed by individual piezo bodies 6 which - as seen in the longitudinal axis of the interior of the bridge part 4 - are spaced apart with their end faces 6.5 , 6.6 and are arranged in alignment with one another with their jacket surfaces. Their outer surfaces are covered by a common contact and shielding film 9 . The contact is made analogously to the individual sheathing of a piezo body 6 according to FIG. 7, ie the first contact surfaces 6.1. the piezo body 6 are contacted by a first inner strip surface of the copper foil 9 common to all the piezo bodies 6 . In contrast, the second contact surfaces 6.2 of the piezo bodies 6 are contacted by a continuous electrode strip 8.1 of a circuit board 8 , which is common to all piezo bodies 6 with its insulating support strip 8.2 and its electrode strip 8.1 . The copper foil 9 extends essentially over the entire length of the axial alignment of the piezo body 6 and looks at at least one end with a connecting electrode piece 8.1 a from the sheath M 'of the copper foil 9 . The insulating layers 11 are again between the side flanks of the respective piezo body 6 and the circuit board 8 on the one hand and the adjacent inside of the copper foil 9 on the other hand. They also extend essentially over the entire length of the axial alignment of the piezo bodies 6 . In this way, only one common plus signal conductor is required instead of the six plus signal conductors shown in FIG. 1. Favorable values for the dimensions and in particular wall thicknesses of the sensor S and its casing M and also of the other parts of the pickup can be seen in FIG. 2 if the magnification of about 45: 1 used there is observed. Of course, these dimensions are only guidelines.

Claims (8)

1. Piezoelectric pickup for musical instruments, in particular for stringed instruments,

• with a metal bridge part of approximately U-shaped cross section arranged transversely to the strings and underneath them in the manner of a web insert, which forms a housing for at least one piezoelectric sensor with its interior,
• - With the above-mentioned piezoelectric sensor, which is mounted in the interior of the bridge part between a base-side base surface of the same and an associated cover-side pressure piece, which is metallized on a base surface and on an opposite cover surface of its prismatic piezo body with the formation of contact surfaces and on these contact surfaces each with a mass - and opposite polarity of electrical connecting lines is contacted, the latter leading to an electrical or electronic signal processing stage,
• and with the pressure piece mentioned, which is exposed to the pressure of the string tension, is guided on the bridge part in the string pressure direction and transmits the string vibrations to the at least one piezoelectric sensor in a force-locking manner,

characterized by

• a) that the outer surfaces ( 6.1, 6.2, 6.3, 6.4 ) of the prismatic piezo body ( 6 ) are encased with a contact and shielding film ( 9 ) made of an electrically highly conductive material,
• b) that the film ( 9 ) is in direct contact with a first contact surface ( 6.1 ) of the piezo body ( 6 ) as a ground electrode and is pressed with a bare underside ( 91 ) against the base side surface ( 4.3 ) of the bridge part ( 4 ),
• c) that the film ( 9 ) is insulated from the second contact surface ( 6.2 ) of the piezo body ( 6 ) forming the opposite polarity and from its piezoelectrically neutral side flanks ( 6.3, 6.4 ),
• d) that the second contact surface ( 6.2 ) is in direct contact with the electrode strip ( 8.1 ) of a circuit board ( 8 ) consisting of highly conductive metal, the electrode strip ( 8.1 ) being applied to an insulating material carrier strip ( 8.2 ) of the circuit board ( 8 ) and a Piece ( 8.1 a ) of the circuit board projecting beyond the piezo body ( 6 ) serves as a connecting electrode for a signal line ( 14 ) of opposite polarity and the pressure piece ( 12 ) covers the connecting space ( 16 ) of the connecting electrode which is not filled by the piezo body ( 6 ) and the or keeps an adjacent piezo body at a distance with its pressure piece,
• e) and that by means of the film ( 9 ) the board ( 8 ) pressed with its electrode strip ( 8.1 ) against the second contact surface ( 6.2. ) is sheathed, with between the side flanks ( 6.3, 6.4 ) of the piezo body ( 6 ) and the Circuit board ( 8 ) on the one hand and the adjacent inside of the film on the other hand insulated layers ( 11 ) are inserted.

2. Pickup according to claim 1, with a plurality of piezoelectric sensors, which are accommodated with their pressure pieces in the bridge part, characterized in that each individual piezo body ( 6 ) of the sensors ( S ) with associated circuit board ( 8 ) and associated insulating material layers ( 11 ) is encased by a separate film ( 9 ) and the conductor of the opposite polarity or positive conductor is each isolated from a separate shielded signal line ( 14 ) to the connection electrode ( 8.1 a ) of the circuit board ( 8 ) and connected there. 3. Pickup according to claim 1, with a plurality of piezoelectric sensors, which are accommodated with their pressure pieces in the bridge part, characterized in that the individual piezo bodies ( 6 ) - seen in the longitudinal axis of the interior of the bridge part ( 4 ) - with their end faces to each other spaced apart and arranged with their lateral surfaces in alignment with one another and their lateral surfaces ( 6.1 ,..., 6.4 ) are covered by a common contact and shielding film ( 9 ) and that the first contact surfaces ( 6.1 ) of the piezo body ( 6 ) are surrounded by a first one Piezobodies common inner strip surface of the contact and shielding film ( 9 ) are contacted and the second contact surfaces ( 6.2 ) of the piezo body ( 6 ) are contacted by a continuous electrode strip ( 8.1 ) of a circuit board ( 8 ) which with its insulating material support strip ( 8.2. ) And its electrode strip ( 8.1 ) is common to all piezo bodies ( 6 ), with the contact and shielding olie ( 9 ) extends substantially over the entire length of the axial alignment of the piezo body ( 6 ) and at least one end with a connecting electrode piece ( 8.1 a ) looks out of the sheathing of the contact and shielding film ( 9 ), the insulating material layers ( 11 ) between the side flanks of the piezo body ( 6 ) and the circuit board ( 8 ) on the one hand and the adjacent inside of the contact and shielding film ( 9 ) on the other hand continuously extend substantially over the entire length of the axial alignment of the piezo body ( 6 ). 4. Pickup according to one of claims 1 to 3, characterized in that the second contact surface ( 6.2 ) of the or the piezo body ( 6 ) serves the underside and that the insulated conductor of the opposite polarity of the signal line ( 14 ) through holes ( 18 ) in the bottom wall ( 40 ) of the bridge part ( 4 ) is guided from below into the connection space and is connected, in particular soldered, to the connection electrode ( 8.1 a ) as a base with a bare connection end ( 14.1 ). 5. Pickup according to one of claims 1 to 4, characterized in that the contact and shielding foil ( 9 ) is a copper foil. 6. Pickup according to one of claims 1 to 5, characterized in that the contact and shielding film ( 9 ) is a carrier film which is provided on its inside facing the piezo body ( 6 ) with an electrically conductive adhesive layer ( 10 ) and the adhesive layer ( 10 ) in the as-yet unprocessed state of the carrier film is laminated by an insulating peel-off film ( 11 ) divided into strips ( 11.1, ... , 11.5 ), the coverings covering the side flanks of the piezo body ( 6 ) and the circuit board ( 8 ) Isolierstoffschichten the corresponding release film strips ( 11.2, 11.4 ) remain in their adhesive position, on the other hand, the strip-shaped carrier film parts to be contacted with the first contact surface ( 6.1 ) of the piezo body ( 6 ) or to be folded over the circuit board by pulling off the corresponding release film strips ( 11.3, 11.1, 11.5 ) are exposed. 7. Pickup according to claim 6, characterized in that the conductive adhesive layer ( 10 ) is a non-curing or non-hardened synthetic resin adhesive with embedded copper particles, the size of the copper particles being in the µm range.