JP2005218519A - Ultrasonic vibrator unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ultrasonic vibrator unit which can contribute to the reduction of a connection defect rate and to the reduction of a manufacturing time by improving connection workability of a hard substrate and a signal cable bundle. <P>SOLUTION: The ultrasonic vibrator unit 20 is constituted of a hard substrate 35 having an ultrasonic vibrator group with acoustic lenses, acoustic matching layers, piezoelectric elements, and back face braking layers respectively, a wiring pattern arranging a plurality of electrodes 35c and signal wires 35a electrically connected to respective piezoelectric elements of the ultrasonic vibrator group, the signal cable bundle 29 composed of a plurality of signal core lines 29a and a flexible print substrate 33 interposed between the hard substrate and the signal cable bundle and having a wiring pattern electrically connecting both. An ultrasonic vibrator portion assembly 31 constituted by electrically connecting the ultrasonic vibrator group and the hard substrate and a cable portion assembly 32 constituted by electrically connecting the signal cable bundle and the flexible print substrate are separatedly constructed. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an ultrasonic transducer unit, specifically, an ultrasonic transducer group composed of a plurality of piezoelectric elements and the like, and a signal cable bundle composed of a plurality of signal cores for transmitting signals from the piezoelectric elements of the ultrasonic transducer group. It is related with the ultrasonic transducer | vibrator unit comprised by these.

  Conventionally, an ultrasonic diagnostic apparatus that obtains a tomographic image in a subject by transmitting an ultrasonic wave toward a subject such as a human body and receiving an echo reflected by the subject is non-invasive and immediate. In particular, it is widely used in the field of diagnostic medicine and plays an important role because it can obtain image information of a tomographic image inside a subject.

  In such an ultrasonic diagnostic apparatus, for example, a plurality of ultrasonic transducers are arranged in a straight line, and ultrasonic wave transmission / reception operations by these ultrasonic transducers are electronically performed sequentially at a constant time and at regular intervals. An electronic scanning type ultrasonic probe configured to obtain a tomographic image of a subject by performing high-speed switching is used.

  A plurality of ultrasonic transducers (hereinafter referred to as an ultrasonic transducer group) provided with a piezoelectric element, an acoustic matching layer, a back surface braking layer, and the like at the tip of the electronic scanning ultrasonic probe, and the ultrasonic transducer An ultrasonic transducer unit including a signal cable unit in which a plurality of signal lines electrically connected to each transducer is bundled is provided so that each group can transmit and receive signals.

  In the above-mentioned conventional electronic scanning ultrasonic probe, assuming that it is used outside the body, there is no problem even if the outer shape of the ultrasonic transducer unit is relatively large. As means for electrically connecting the signal lines to each other, for example, a connection connector or the like is used.

  On the other hand, in a conventional electronic scanning ultrasonic probe that is configured to be used by being inserted into a body cavity, the outer shape of the ultrasonic transducer unit needs to be extremely small. is there. Therefore, in order to reduce the size of an ultrasonic transducer unit in which a plurality of ultrasonic transducers are arranged, the interval between adjacent ultrasonic transducers is extremely small (short).

  In this case, a very thin signal line connected to each of the ultrasonic transducers arranged at a narrow interval is used, and such a plurality of extremely thin signal lines are used. A bundle of signal cables bundled together is very expensive.

  Furthermore, when electrically connecting each ultrasonic transducer and each signal line, one end of each signal line of the signal cable bundle is connected to each ultrasonic wave on a hard substrate on which a plurality of ultrasonic transducers are provided. Each pad electrode that is electrically connected to each vibrator is electrically connected by connecting means such as soldering.

  FIG. 6 is an exploded view showing a schematic configuration of a conventional ultrasonic transducer unit. As shown in FIG. 6, the conventional ultrasonic transducer unit 101 includes therein an ultrasonic transducer group (not shown) each including an acoustic lens, an acoustic matching layer, a piezoelectric element, and a rear braking layer. The hard substrate 112 having a wiring pattern on both surfaces, which is electrically connected to the ultrasonic transducer section group 111 and each piezoelectric element of the ultrasonic transducer group and includes a plurality of signal lines 112a, electrodes 112b, and pad electrodes 112c. And a plurality of signal core wires 113a connected to the pad electrode 112c of the hard substrate 112 are bundled together, and the signal cable bundle 113 is formed in a form in which the signal core wires 113a are covered with a covering member 113b.

  In manufacturing the conventional ultrasonic transducer unit 101 configured as described above, for example, the ultrasonic transducer group 111 having an ultrasonic transducer group (not shown) inside, the hard substrate 112, and the like. Each cable core set 114 formed by connecting each signal core wire 113a by connecting means such as soldering is manufactured in a separate process.

  That is, a part of the hard substrate 112 to which the cable unit 114 is connected in advance is inserted into a predetermined portion inside the ultrasonic transducer unit 111, and each electrode 112b of the hard substrate 112 and the ultrasonic wave are maintained while maintaining this state. Each piezoelectric element (not shown) provided inside the vibrator unit set 111 is connected by connection means such as soldering. Thereafter, an adhesive 111a or the like is injected into the ultrasonic transducer section set 111 and solidified. The conventional ultrasonic transducer unit 101 is manufactured through the processes as described above.

  As described above, when assembling and manufacturing the conventional ultrasonic transducer unit 101, each signal core wire 113a of the signal cable bundle 113 is directly soldered to the wiring portion (pad electrode 112c) of the hard substrate 112 which is an extremely small component. There are an operation of connecting by attaching and the like, and an operation of connecting between each electrode 112b of the hard substrate 112 and each piezoelectric element (not shown) inside the ultrasonic transducer section set 111.

  However, since the wiring portion (pad electrode 112c) has an extremely small area, in order to connect the plurality of signal core wires 113a to the pad electrode 112c at a predetermined position reliably and accurately, for example, the hard substrate 112 is securely connected. It is necessary to perform the connection work in a state where the signal core wire 113a is precisely positioned at a predetermined position in a fixed and held state. In order to be able to easily perform the work, for example, it is necessary to secure a sufficiently large work space around the pad electrode 112c.

  Therefore, first, each signal core wire 113a of the signal cable bundle 113 is connected to the pad electrode 112c of the hard substrate 112 by soldering or the like, and then each electrode 112b of the hard substrate 112 and the ultrasonic transducer unit set 111 are connected. A general procedure is to make a connection between each internal piezoelectric element (not shown).

  As for the connection work as described above, the workability has not been much emphasized so far, and it is also an extremely difficult work. There is a problem that it requires a lot of manufacturing technology and a lot of work time.

  In addition, the ultrasonic transducer unit 101 thus manufactured is subjected to a predetermined inspection before shipment. In this shipping inspection, for example, a connection failure between each signal core wire 113a of the signal cable bundle 113 and the pad electrode 112c of the hard substrate 112 may be found.

  However, after the ultrasonic transducer unit 101 is completed, since the adhesive 111a is in a solidified state, it is impossible to correct the internal connection lines. Therefore, if a connection failure or the like is found in the shipping inspection, it must be discarded as a defective product.

  However, each signal core 113a of the signal cable bundle 113 used in the medical ultrasonic transducer unit used in the body cavity is very thin, and the signal cable bundle 113 using this is very expensive. Is. Therefore, the cable part set 114 (the signal cable bundle 113 and the hard board 112 connected to each other) manufactured through the above-described highly difficult work becomes a very expensive member.

  However, in the conventional ultrasonic transducer unit 101, the manufacturing process is complicated and difficult as described above, and therefore, defective products discovered at the time of shipping inspection must be discarded. Therefore, the cost of the ultrasonic transducer unit 101 as a product is increased.

  On the other hand, the conventional ultrasonic transducer unit 101 is configured to have a certain amount of spatial margin in the thickness direction with the hard substrate 112 interposed therebetween (see symbol T in FIG. 6).

  However, each signal core wire 113a of the signal cable bundle 113 in the conventional ultrasonic transducer unit 101 is connected only at the pad electrode 112c formed in a very narrow portion on the surface of the hard substrate 112 as described above. It has become.

  Therefore, the connection between the hard board 112 and the signal cable bundle 113 must be performed only in a narrow part, and thus there is a problem that a wasteful space is generated and at the same time, the efficiency of the connection work is hindered. .

  The present invention has been made in view of the above-described points, and the object of the present invention is to secure an area to be provided for a connection portion between a hard board and a signal cable bundle by efficiently utilizing a spatial margin. In addition, the connection workability between the two is greatly improved, and at the same time, the electrical connection between each signal line of the signal cable bundle and each ultrasonic transducer is ensured, and the failure rate due to connection failure, etc. It is another object of the present invention to provide an ultrasonic transducer unit that contributes to reducing the manufacturing cost and shortening the manufacturing time and reducing the manufacturing cost by increasing the efficiency of the manufacturing process.

  In order to achieve the above object, an ultrasonic transducer unit according to the present invention includes an ultrasonic transducer group including an acoustic lens, an acoustic matching layer, a piezoelectric element, and a back braking layer, and each of the ultrasonic transducer groups. A hard substrate having a wiring pattern in which a plurality of electrodes and signal lines electrically connected to the piezoelectric element are arranged, a signal cable bundle composed of a plurality of signal core wires, and interposed between the hard substrate and the signal cable bundle And an ultrasonic transducer unit comprising a flexible printed circuit board having a wiring pattern for electrically connecting them, wherein the ultrasonic transducer group and the hard substrate are electrically connected. The acoustic wave vibrator section set, and the cable section set formed by electrically connecting the signal cable bundle and the flexible printed circuit board are configured as separate structures.

  According to the present invention, it is possible to efficiently utilize a space margin to secure an area to be provided for a connection portion between the hard board and the signal cable bundle, and at the same time to greatly improve the connection workability between the two. Ensures electrical connection between each signal line of bundle and each ultrasonic transducer, contributes to reduction of defective rate due to poor connection, etc., and shortens manufacturing time by improving manufacturing process efficiency It is to provide an ultrasonic transducer unit that can contribute to the reduction of manufacturing cost and manufacturing cost.

The present invention will be described below with reference to the illustrated embodiments.
FIG. 1 is a diagram schematically showing a configuration of an ultrasonic endoscope diagnostic apparatus including an electronic scanning ultrasonic endoscope to which an ultrasonic transducer unit according to an embodiment of the present invention is applied. FIG. 2 is an enlarged perspective view of a main part showing an enlarged front end portion of the electronic scanning ultrasonic endoscope shown in FIG. FIG. 3 is a diagram schematically showing the appearance of the ultrasonic transducer unit of the present embodiment. FIG. 4 is a part of the internal components disposed in the housing of the tip portion of the ultrasonic transducer unit of the present embodiment. The ultrasonic transducer unit set and the cable unit set are taken out, and It is a principal part expansion exploded perspective view showing an outline. FIG. 5 is a part of an internal structural member disposed in the housing of the distal end portion of the ultrasonic transducer unit of the present embodiment. It is a principal part expansion perspective view shown.

  In FIG. 3, a part of the signal cable bundle 29 is broken to show the signal core wire 29a.

  The ultrasonic transducer unit of the present embodiment is used for an electronic scanning ultrasonic endoscope. Before describing the ultrasonic transducer unit in detail, first, an outline of the configuration of an ultrasonic endoscope diagnostic apparatus including an electronic scanning ultrasonic endoscope to which the ultrasonic transducer unit is applied will be described below. .

  As shown in FIG. 1, an ultrasonic endoscope diagnostic apparatus 1 includes an ultrasonic transducer unit (hereinafter referred to as vibration) having an electronic scanning ultrasonic transmission / reception unit 21 at a distal end portion of an insertion portion 2a inserted into a body cavity. An electronic scanning ultrasonic endoscope (hereinafter abbreviated as an ultrasonic endoscope) 2 having 20 (abbreviated as a sub-unit) and an illumination optical system built in the ultrasonic endoscope 2 The light source device 3 that supplies the illumination light beam, and an ultrasonic wave that generates an ultrasonic drive signal to be transmitted to the ultrasonic transmission / reception unit 21 or performs signal processing based on the ultrasonic wave received by the ultrasonic transmission / reception unit 21 It is mainly configured by an observation device 4 and a display device 4a that receives an image signal generated and output by the ultrasonic observation device 4 and displays an ultrasonic diagnostic image.

  The ultrasonic endoscope 2 and the light source device 3 are detachably connected via an endoscope connector 6 provided at the base end of the universal cord 5. The ultrasonic endoscope 2 and the ultrasonic observation apparatus 4 are detachably connected via an ultrasonic connector 8 provided at the base end of the ultrasonic cord 7.

  The ultrasonic endoscope 2 includes an insertion portion 2a that is formed in an elongated shape and is inserted into a body cavity, an operation portion 2b that is provided at a proximal end portion of the insertion portion 2a, and a proximal end portion of the operation portion 2b. The relay portion 2c is provided, and the eyepiece portion 2d is provided at the base end of the relay portion 2c. And the said universal cord 5 is extended from the side part of the said operation part 2b, and the said ultrasonic cord 7 is extended from the side part of the said relay part 2c.

  The insertion portion 2a is provided with an ultrasonic transducer unit 20 on the distal end side, a hard portion 9 provided continuously to the rear end side of the ultrasonic transducer unit 20, and a rear end side of the hard portion 9. For example, a bending portion 10 configured to be able to bend in the vertical and horizontal directions, and a small diameter and long shape provided between the bending portion 10 and the operation portion 2b. The flexible part 11 which has flexibility is connected and comprised.

  The hard part 9 is formed of a resin material excellent in chemical resistance, biocompatibility and insulation, such as polysulfone or polyethyl ether ketone. The operation unit 2b includes an angle knob 12 for bending the bending unit 10 in a desired direction, an air / water supply button 13 for performing air supply and water supply operations, and a suction button for performing a suction operation. 14, a treatment instrument insertion port 15 for introducing a treatment instrument or the like into a body cavity, and a forceps raising lever 16 for operating a later-described forceps raising base 27 (see FIG. 2) are provided.

  As shown in FIG. 2, the ultrasonic transducer unit 20 is disposed at the distal end of the insertion portion 2a, and an ultrasonic transmission / reception unit 21 is disposed at a predetermined portion of the distal end portion. The ultrasonic transmission / reception unit 21 is provided with an ultrasonic transducer group (details will be described later, see FIG. 5) in which a plurality of piezoelectric elements (array transducers) and the like are arranged. The range indicated by the symbol A can be scanned. The range indicated by the symbol A is called an ultrasonic scanning range.

  A rigid portion 9 is provided at the rear end of the ultrasonic transducer unit 20, and an illumination lens cover 23 for irradiating an illumination light beam toward a desired observation site and an optical image of the observation site are captured on the front end surface 9a. An observation lens cover 24 that constitutes an observation optical system, and an air / water supply nozzle 25 that performs an air / water supply operation to remove dirt, body fluid, and the like attached to the surface of the observation lens cover 24 are provided. . The illumination lens cover 23 includes a light guide fiber (not shown), the observation lens cover 24 includes an image guide fiber (not shown), and the air / water supply nozzle 25. An air / water supply tube (not shown) is connected to the.

  In addition, a forceps outlet 26 that is disposed so that the central axis is included in the ultrasonic scanning range A of the ultrasonic transmission / reception unit 21 opens at the distal end surface 9 a of the hard portion 9. In the vicinity of the forceps outlet 26, a forceps raising base 27 that is adjusted by swinging the protruding direction of a treatment tool (not shown) such as a tissue suction needle protruding from the forceps outlet 26 is disposed.

  In addition, as a material for forming the air / water feeding nozzle 25 and the forceps raising base 27, for example, an electrical insulator such as a ceramic member or a resin member is used.

  The light guide fiber extends through the insertion portion 2 a, the operation portion 2 b, and the universal cord 5 to the endoscope connector 6. On the other hand, the image guide fiber (not shown) extends through the insertion portion 2a, the operation portion 2b, and the relay portion 2c to the eyepiece portion 2d. The air / water supply tube extends through the insertion portion 2a and the operation portion 2b and through the air / water supply button 13 through the universal cord 5 and extends to the endoscope connector 6.

  In the ultrasonic transducer unit 20, the ultrasonic transducer group (see FIG. 5) including a piezoelectric element 43 and the like described later and a hard substrate 35 (not shown in FIG. 3; see FIGS. 4 and 5) are electrically connected. The ultrasonic transducer unit set 31 (see FIG. 4) having the ultrasonic transmission / reception unit 21 connected thereto and the ultrasonic transducer unit set 31 accommodated therein and detachable from the hard unit 9 A housing 28 (FIG. 3) to be formed, and a signal cable bundle 29 and a flexible printed circuit board 33 (FIG. 3) that are electrically connected to the ultrasonic transducer section set 31 and are disposed in an inner hollow portion of the housing 28. In FIG. 4, the cable portion set 32 (see FIG. 4) is mainly configured.

  Among these, the ultrasonic transducer section set 31 is disposed at a predetermined position inside the case 34 (indicated by a two-dot chain line in FIG. 4) having the ultrasonic transmission / reception section 21 therein, and the supersonic wave transmission section 21. It is comprised by the hard board | substrate 35 which has the wiring pattern etc. which are connected with respect to each of the sound wave oscillator group.

  Here, a schematic configuration of the constituent member disposed in the case 34 of the ultrasonic transducer section set 31, that is, the ultrasonic transmission / reception section 21 (the ultrasonic transducer group and the hard substrate 35) is illustrated in FIG. Will be described.

  Note that the ultrasonic transmission / reception unit 21 including a plurality of ultrasonic transducer groups is the same as that used in a conventional ultrasonic endoscope. Therefore, in the following description, detailed description is omitted, and only the outline is described.

  The case 34 (not shown in FIG. 4 and indicated by a two-dot chain line in FIG. 5) has a substantially semicircular cross section and is formed with a space inside and a part of the opening. As shown in FIG. 5, an acoustic lens 41, an acoustic matching layer 42, a common ground electrode (not shown), and a piezoelectric element 43 are formed on the arc-shaped inner wall portion inside the case 34 in order from the front end side (wall side). The ultrasonic transducer group including the rear braking layer 44 is provided, and the hard substrate 35 is electrically connected to the ultrasonic transducer group. Most of the hard substrate 35 is disposed inside the case 34. The ultrasonic transmission / reception unit 21 is constituted by both the ultrasonic transducer group and the hard substrate 35.

  The hard substrate 35 is formed in a substantially semicircular shape substantially the same as the cross-sectional shape of the case 34, and a plurality of ultrasonic vibrations provided on the inner wall surface of the case 34 along the arc-shaped side edges. A group of children is arranged.

  On the hard substrate 35, as shown in FIGS. 4 and 5, wiring patterns in which a plurality of signal lines 35a, electrode portions 35b, and pad electrodes 35c are arranged are formed on both surfaces thereof. The piezoelectric element 43 is electrically and mechanically connected and fixed to the electrode part 35 b arranged in the arc-shaped part of the hard substrate 35 by the wiring wire 36. As a connection means in this case, for example, means such as soldering is used.

  Each electrode portion 35b of the hard substrate 35 is connected to one end portion of each corresponding signal line 35a, and a pad electrode 35c is connected to the other end portion of the signal line 35a.

  Note that the surface of the acoustic matching layer 42 or the acoustic lens 41 is coated with, for example, polyparaxylylene so as to have water resistance and insulating properties and good acoustic characteristics.

  On the other hand, the cable section set 32 constituting a part of the ultrasonic transducer unit 20 includes a signal cable bundle 29 in which a plurality of signal core wires 29a for transmitting drive signals and ultrasonic signals are inserted, and the signal cable bundle 29. And a flexible printed board 33 having a wiring pattern that is interposed between the hard board 35 and the hard board 35 to electrically connect them.

  The wiring pattern of the flexible printed circuit board 33 includes a plurality of electrode portions 33b to which the respective tips of the signal core wires 29a of the signal cable bundle 29 are connected, a plurality of signal lines 33a to be connected to the electrode portions 33b, It is formed by a pad electrode portion 33 c formed at an end portion of the signal line 33 a and connected to the pad electrode 35 c of the hard substrate 35.

  As described above, the tip ends of the signal core wires 29a of the signal cable bundle 29 are connected to the electrode portions 33b of the flexible printed circuit board 33. In this case, the connection is made by connecting means such as soldering. The signal cable bundle 29 passes through the insertion portion 2a of the ultrasonic endoscope 2 and extends to the ultrasonic connector 8 through the operation portion 2b. The signal cable bundle 29 is connected to the ultrasonic connector 8 with respect to the signal cable. A proximal end portion (not shown) of the bundle 29 is connected.

  The connection between the pad electrode portion 33c of the flexible printed board 33 and the pad electrode 35c of the hard board 35 is made by thermocompression bonding. Thereby, electrical connection is ensured between the ultrasonic transducer group connected to the hard substrate 35 and the ultrasonic connector 8 connected to the base end portion of the signal cable bundle 29, and Transmission of electrical signals handled by the acoustic wave transducer group is realized.

  In FIG. 4, the flexible printed circuit board 33 is only shown to be connected to one surface (the upper surface side in FIG. 4) of the hard substrate 35, but the flexible printed circuit board 33 is different from this. Separately, the other surface (the lower surface side in FIG. 4) of the hard substrate 35 is disposed in the same manner. And connection with the hard board | substrate 35 is made | formed by the same thermocompression bonding. That is, the two flexible printed boards 33 are connected by thermocompression bonding so that the hard board 35 is sandwiched between both surfaces of the hard board 35.

  As described above, in the ultrasonic transducer unit of the above-described embodiment, the ultrasonic vibration formed by electrically connecting the two sets constituting the unit, that is, the ultrasonic transducer group and the hard substrate 35. The child part set 31, the cable part set 32 in which the signal cable bundle 29 and the flexible printed circuit board 33 are electrically connected are configured to have separate structures. And it is comprised so that the ultrasonic transducer | vibrator unit 20 of this embodiment may be formed by connecting both after producing both part sets.

  That is, after the ultrasonic transducer part set 31 and the pair of cable part sets 32 are formed in separate processes, first, the pad electrode 35c on one surface of the hard substrate 35 of the ultrasonic transducer part set 31 is applied. Then, the pad electrode part 33c of the flexible printed board 33 of one cable part set 32 of the pair of cable part sets 32 is connected by thermocompression bonding.

  Next, the pad electrode part 33c of the flexible printed board 33 of the other cable part set 32 is similarly connected to the pad electrode 35c on the other side of the hard board 35 by thermocompression bonding.

  Thereafter, each of the two flexible printed boards 33 is folded at a predetermined plurality of locations (valley fold B and mountain fold C in FIG. 4).

  Here, the flexible printed circuit board 33 is folded in a valley fold in the symbol B in FIG. 4 and in a mountain fold in the symbol C in FIG. That is, when the flexible printed circuit board 33 is folded, the connection portions between the electrode portions 33b of the flexible printed circuit board 33 and the signal core wires 29a of the signal cable bundle 29 are not exposed to the outside. Thereby, the connection part can be protected.

  In addition, after soldering each electrode part 33b and each signal core wire 29a, the process which covers this connection part with a predetermined insulating material is performed. Thereby, even if each connection part contacts when the flexible printed circuit board 33 is made into the folded state, an unnecessary electrical connection is prevented.

And it fixes with an adhesive etc. so that this folding state can be maintained. Thereby, even after the assembly of the ultrasonic transducer unit 20, the connection parts do not move with each other, and a possible failure, for example, a machine caused by a short circuit of the signal core wire 29 a on the flexible printed circuit board 33 or the like. It is possible to prevent a general defect and to protect the connection portion between the signal core wire 29a and the electrode 33b.

  In this way, an assembly member in a state where the ultrasonic transducer section 31 and the pair of cable sections 32 are connected and each flexible printed board 33 of the pair of cable sections 32 is folded is a predetermined inside of the housing 28. Store in position. Thereby, the assembly of the ultrasonic transducer unit 20 of the present embodiment is completed.

  As described above, according to the above-described embodiment, the ultrasonic transducer group 31 in which the ultrasonic transducer group and the hard substrate 35 are electrically connected, the signal cable bundle 29, and the flexible printed circuit board. The cable part set 32 electrically connected to the cable 33 is configured as a separate structure, and then the ultrasonic transducer part set 31 and the cable part set 32 are connected by thermocompression bonding.

Thereby, the process which manufactures the said ultrasonic transducer | vibrator part group 31 and the said cable part group 32 can be made into another line. And by advancing these two production lines simultaneously,
The manufacturing process of the ultrasonic transducer unit 20 can be made efficient. Therefore, it is possible to contribute to shortening the overall manufacturing time for manufacturing the ultrasonic transducer unit 20.

  Further, when the signal cable bundle 29 is connected to the hard substrate 35, the flexible printed circuit board 33 is interposed, and the flexible printed circuit board 33 is foldable so that the signal core wire 29a of the signal cable bundle 29 and the flexible printed circuit board 33 can be folded. It is possible to secure a wider area of the connection part.

  This can be achieved by connecting the ultrafine signal core wire 29a to the electrodes 33b of the flexible printed circuit board 33 arranged with a wider pitch than the conventional one. Therefore, compared with the conventional method (see FIG. 6), the manufacturing difficulty is lower compared to the case where the ultrafine signal core wire 113a is connected to the pad electrodes 112c arranged at a narrow pitch in the narrow region of the hard substrate 112. At the same time, it can be manufactured easily, and the occurrence of defective products is reduced, so that efficient workability can be ensured.

  Moreover, even if a defect or the like occurs at the connection portion between the electrode 33b of the flexible printed circuit board 33 and the signal core wire 29a, the expensive signal cable bundle 29 can be reused without being discarded. Therefore, it can also contribute to reduction of the final manufacturing cost.

  Furthermore, the folded form of the flexible printed circuit board 33 can laminate a plane including the connection portion of the signal core wire 29a and effectively use a space in a direction orthogonal to the plane of the hard board 35. Therefore, it is possible to suppress the occupied space while ensuring a wider area of the plane including the connection part. Thereby, it can contribute to size reduction of ultrasonic transducer unit 20 itself.

  In other words, it is possible to effectively utilize a portion (space in a direction orthogonal to the plane of the hard substrate 35) that has been a surplus space in the prior art, and thus a wider connection portion while suppressing an increase in size. An area can be secured, and a spatial margin can be secured when the signal cable bundle 29 is assembled.

  Further, in a state where the flexible printed circuit board 33 is folded a plurality of times, the connection part between the flexible printed circuit board 33 and each signal core wire 29a of the signal cable bundle 29 is arranged on the inner surface of the folded state. Yes. Thereby, the said connection site | part is protected, Therefore The said connection state of both after producing the ultrasonic transducer | vibrator unit 20 can be maintained in the stable state.

  In the above-described embodiment, when the flexible printed circuit board 33 is folded, there are two places, a valley fold portion denoted by reference numeral B and a mountain fold portion denoted by reference numeral C in FIG. There is no limitation, and a larger number of folds may be used.

  That is, as the number of folds of the flexible printed board 33 is increased, the surface area thereof is increased. Therefore, for example, when an ultrasonic transducer unit having an increased number of piezoelectric elements constituting the ultrasonic transducer group is configured, the number of signal cores 29a of the signal cable bundle 29 is increased accordingly. It is necessary to let

  Even in such a case, by increasing the number of folding of the flexible printed circuit board 33, it is possible to easily cope with this by securing a larger surface area, that is, an area of the connection portion of the signal core wire 29a. .

1 is a diagram schematically showing a configuration of an ultrasonic endoscope diagnostic apparatus including an electronic scanning ultrasonic endoscope to which an ultrasonic transducer unit according to an embodiment of the present invention is applied. FIG. The principal part expansion perspective view which expands and shows the front-end | tip part of the electronic scanning ultrasonic endoscope shown in FIG. The figure which shows schematically the external appearance of the ultrasonic transducer | vibrator unit of one Embodiment of this invention. 1. An enlarged main portion showing an outline of a part of an internal constituent member disposed in a housing at the tip of the ultrasonic transducer unit of FIG. FIG. FIG. 2 is an enlarged perspective view of a main part of a part of an internal constituent member disposed in a housing at a distal end portion of the ultrasonic transducer unit in FIG. Figure. The exploded view which shows schematic structure of the conventional ultrasonic transducer | vibrator unit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Ultrasound endoscope diagnostic apparatus 2 ... Ultrasound endoscope 20, 101 ... Ultrasonic transducer unit 21 ... Ultrasonic transmission / reception part 28 ... Housing 29, 113 ... Signal cable bundle 29a, 113a ... Signal core wires 31, 111 ... Ultrasonic transducer part set 32,114 ... Cable part set 33 ... Flexible printed circuit boards 33a, 112a ... Signal lines 33b, 112b ... Electrodes 33c, 112c ... Pad electrode parts 34 …… Cases 35, 112 …… Hard substrate 35a …… Signal wire 35b …… Electrode portion 35c …… Pad electrode 36 …… Wiring wire 41 …… Acoustic lens 42 …… Acoustic matching layer 43 …… Piezoelectric element 44 …… Back braking layer 111a …… Adhesive 113b …… Coating member agent Patent attorney Susumu Ito

Claims (3)

An ultrasonic transducer group including an acoustic lens, an acoustic matching layer, a piezoelectric element, and a back surface braking layer, and a plurality of electrodes and signal lines that are electrically connected to the piezoelectric elements of the ultrasonic transducer group are arranged. A hard board having a wiring pattern; a signal cable bundle comprising a plurality of signal core wires; and a flexible printed board having a wiring pattern interposed between the hard board and the signal cable bundle to electrically connect the two. An ultrasonic transducer unit comprising:
An ultrasonic transducer unit set in which the ultrasonic transducer group and the hard substrate are electrically connected, and a cable unit set in which the signal cable bundle and the flexible printed circuit board are electrically connected. An ultrasonic transducer unit comprising a separate structure. 2. The cable portion set according to claim 1, wherein each signal core of the signal cable bundle is connected to a plurality of electrode portions formed at one end of the signal line on the wiring pattern of the flexible printed circuit board. The described ultrasonic transducer unit. By connecting the pad electrode formed on the other end of the signal line on the wiring pattern of the flexible printed circuit board and the pad electrode formed on the hard circuit board by thermocompression bonding, the ultrasonic transducer assembly and the cable are connected. The ultrasonic transducer unit according to claim 1, wherein the unit is electrically connected.

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