JP2021159641A - Ultrasonic probe and ultrasound diagnostic apparatus - Google Patents

Abstract

To provide an ultrasonic probe which is strong against EMI, and to facilitate manufacture of the ultrasonic probe.SOLUTION: An ultrasonic probe includes: an acoustic sensor part which includes FPC32A having a plurality of piezoelectric transducers for transmitting and receiving ultrasonic waves and a signal line terminal 321A1 of a signal line electrically connected to the plurality of the piezoelectric transducers; a coaxial cable 60 which is connected to an ultrasound diagnostic apparatus body that generates ultrasound image data based on a received signal obtained by transmitting a drive signal to the acoustic sensor part and has a signal line; and a connector CA which electrically connects the signal line terminal 321A1 of FPC32A and the signal line of the coaxial cable 60. The connector CA has a grounded GND part 401A, 501A which covers a connecting part between the signal line terminal 321A1 of FPC32A and the signal line of the coaxial cable 60.SELECTED DRAWING: Figure 6

Description

The present invention relates to an ultrasonic probe and an ultrasonic diagnostic apparatus.

Ultrasound diagnosis is a simple operation in which an ultrasonic probe is applied from the body surface or inside the body cavity of the patient's subject, and the state of the heart or foetation can be obtained as an ultrasonic image, and it is highly safe, so repeated examinations are performed. It can be performed. An ultrasonic diagnostic apparatus used for performing such ultrasonic diagnosis is known.

An FPC (Flexible Printed Circuit) extending from an ultrasonic sensor unit containing multiple piezoelectric bodies is mounted inside the housing of the ultrasonic probe, and is electrically connected to a coaxial cable connected to the main body of the ultrasonic diagnostic device. Connected to. For example, an FPC and a ground plate extending in two directions perpendicular to the azimuth direction of the ultrasonic vibrator plate are soldered to the electrodes on the back surface of the ultrasonic vibrator plate as a piezoelectric vibrator, and the end portion of the FPC is formed. An ultrasonic probe (ultrasonic probe) connected to a signal transmission / reception circuit or the like via a connector and a wiring material is known (see Patent Document 1).

Further, there is known an ultrasonic probe having a male connector mounted on two flexible substrates (FPCs) connected to a plurality of piezoelectric elements and having two female connectors connected to the core wire of a coaxial cable (an ultrasonic probe). See Patent Document 2). The flexible substrate has a conductive path and is electrically connected to the bottom electrode of each piezoelectric element. The male connector is provided on the tip side of each flexible substrate and has a pin that electrically connects to the conductive path. Then, the two male connectors and the two female connectors are connected. The top electrode of each piezoelectric element is commonly connected by, for example, a thin metal wire (not shown) and grounded to the ground potential.

Japanese Unexamined Patent Publication No. 8-89505 Japanese Unexamined Patent Publication No. 2002-315751

As for the ultrasonic probe, it is preferable to take measures against noise by EMI (ElectroMagnetic Interference). However, with the conventional ultrasonic probe, additional measures for the attached shield cover were required. The attached shield cover must be wrapped around the track parts, making it difficult to miniaturize the ultrasonic probe and complicating the manufacturing process.

An object of the present invention is to be strong against EMI and to facilitate the manufacture of an ultrasonic probe.

In order to solve the above problems, the ultrasonic probe according to claim 1 is
An acoustic sensor unit including a plurality of piezoelectric vibrators for transmitting and receiving ultrasonic waves and a flexible substrate having signal line terminals of signal lines electrically connected to the plurality of piezoelectric vibrators.
A cable connected to an ultrasonic diagnostic apparatus main body that generates ultrasonic image data based on a received signal obtained by transmitting a drive signal to the acoustic sensor unit and having a signal line.
A connector for electrically connecting the signal line terminal of the flexible board and the signal line of the cable is provided.
The connector is an ultrasonic probe having a grounded shield portion that covers a connection portion between a signal line terminal of the flexible substrate and a signal line of the cable.

The invention according to claim 2 is the ultrasonic probe according to claim 1.
The connector electrically connects the signal line terminal of the flexible board and the signal line of the cable without going through a wiring board.

The invention according to claim 3 is the ultrasonic probe according to claim 1 or 2.
The connector has a first signal line for connecting the signal line terminal of the flexible board and the signal line of the cable.
The number of poles and the pitch of the contact on the flexible substrate side and the contact on the cable side of the signal line of the connector are equal.

The invention according to claim 4 is the ultrasonic probe according to claim 3.
The number of poles of the contact on the flexible substrate side of the first signal line of the connector and the number of poles of the contact on the cable side are multiples of 8.

The invention according to claim 5 is the ultrasonic probe according to claim 1 or 2.
The cable has a plurality of coaxial cables having a signal line and a shielded line.
The shield portion has a first shield portion and a second shield portion.
The connector is
The signal line terminal of the flexible substrate is inserted, and the first shield portion and the first connector portion having the second signal line are
The signal line and the shielded wire of the coaxial cable are inserted, and the second shielded portion and the second connector portion having the third signal line are provided.
The second connector portion electrically connects the signal line of the inserted coaxial cable and the third signal line, and connects the shielded wire of the inserted coaxial cable and the second shielded portion. Electrically connected
In the first connector portion, the second connector portion is inserted, and the signal line terminal of the inserted flexible substrate and the third signal line of the inserted second connector portion are inserted into the second signal line. The second shield portion of the inserted second connector portion and the first shield portion are electrically connected by the signal line of the above.

The invention according to claim 6 is the ultrasonic probe according to claim 1 or 2.
The cable has a plurality of coaxial cables having a signal line and a shielded line.
The connector is
Having a fourth signal line, the signal line terminal of the flexible board and the coaxial cable are inserted, and the signal line terminal of the inserted flexible board and the signal line of the inserted coaxial cable are inserted into the fourth signal line. It has a third connector portion that is electrically connected by the signal line of the above and electrically connects the shielded wire of the inserted coaxial cable and the shielded portion.

The invention according to claim 7 is the ultrasonic probe according to any one of claims 1 to 6.
The flexible substrate has a conductive GND layer and has a conductive substrate.
The GND layer and the shield portion are electrically connected to each other, and a conductive GND plate is provided.

The invention according to claim 8 is the ultrasonic probe according to claim 7.
The GND plate covers the connector.

The invention according to claim 9 is the ultrasonic probe according to claim 7 or 8.
The flexible substrate has a GND terminal of the GND layer to which the GND plate is connected.

The invention according to claim 10 is the ultrasonic probe according to any one of claims 1 to 6.
The flexible substrate has a GND layer having conductivity, and includes a GND coating portion having a part of the GND layer.
The GND coating covers the connector and electrically connects the GND layer and the shield.

The invention according to claim 11 is the ultrasonic probe according to any one of claims 1 to 6.
The flexible substrate has a conductive and includes a GND layer having a GND terminal.
The connector has a GND wire on the flexible substrate side that is electrically connected to the shield portion and electrically connected to the GND terminal.

The invention according to claim 12 is the ultrasonic probe according to claim 11.
In the flexible substrate, the GND terminal and the signal line terminal are arranged side by side.

The invention according to claim 13 is the ultrasonic probe according to claim 11.
The flexible substrate has the signal line terminal on one surface and the GND terminal on the other surface behind the one surface.
The connector has a signal line electrically connected to the signal line of the cable and electrically connected to the signal line terminal of the flexible substrate on the one surface side, and has the signal line on the other surface side. It has a GND line.

The invention according to claim 14 is the ultrasonic probe according to claim 13.
In the flexible substrate, the GND terminal provided on one surface is bent, and the GND terminal is formed on the other surface.

The invention according to claim 15 is the ultrasonic probe according to claim 13 or 14.
The one surface is a surface on the piezoelectric vibrator side or a surface behind the surface on the piezoelectric vibrator side.

The invention according to claim 16 is the ultrasonic probe according to any one of claims 7 to 15.
A GND film formed on the upper surface of the piezoelectric vibrator and electrically connected to the GND layer is provided.

The ultrasonic diagnostic apparatus of the invention according to claim 17 is
The ultrasonic probe according to any one of claims 1 to 16.
The ultrasonic diagnostic apparatus main body is provided.

According to the present invention, the EMI can be made strong and the ultrasonic probe can be easily manufactured.

It is a figure which shows the appearance structure of the ultrasonic diagnostic apparatus of 1st Embodiment of this invention. It is a block diagram which shows the functional structure of an ultrasonic diagnostic apparatus. It is a perspective view which shows the appearance structure of the ultrasonic probe. It is a perspective view of the acoustic sensor part of 1st Embodiment. (A) is a top view of the FPC of the first embodiment. (B) is a cross-sectional view of the FPC of the first embodiment. It is a perspective view which shows the FPC, the connector part and the coaxial connector part before connection of 1st Embodiment. (A) is a transparent side view which shows the FPC, the connector part and the coaxial connector part before the connection of the 1st Embodiment. (B) is a transparent side view which shows the FPC, the connector part and the coaxial connector part after the connection of the 1st Embodiment. (A) is a perspective view which shows the FPC, the connector part and the coaxial connector part after the connection of the 1st Embodiment. (B) is a perspective view showing an FPC, a connector portion, and a coaxial connector portion to which a GND plate is connected. (C) is a perspective view showing an FPC, a connector portion, and a coaxial connector portion after mounting the GND plate. It is a perspective view which shows the acoustic sensor part which connected the coaxial cable of 1st Embodiment. It is a transparent side view which shows the FPC and the coaxial connector part before connection of the 1st modification. It is a top view which shows the FPC of the 2nd Embodiment. FIG. 1A is a perspective view showing the front side of the FPC, the connector portion, and the coaxial connector portion to which the GND covering portion of the second embodiment is connected. (B) is a perspective view showing an FPC, a connector portion, and a coaxial connector portion in which the GND coating portion of the second embodiment is coated. (C) is a perspective view showing the back side of the FPC, the connector portion, and the coaxial connector portion covered with the GND plate portion of the second embodiment. It is a perspective view of the acoustic sensor part of the 3rd Embodiment. (A) is a top view of the FPC of the third embodiment. (B) is a cross-sectional view of the FPC of the third embodiment. It is a transparent side view which shows the FPC, the connector part and the coaxial connector part after the connection of the 3rd Embodiment. (A) is a top view of the FPC of the fourth embodiment. (B) is a cross-sectional view of the FPC of the fourth embodiment. (C) is a bottom view of the FPC of the fourth embodiment. It is a transparent side view which shows the FPC, the connector part and the coaxial connector part after the connection of 4th Embodiment. (A) is a top view of the FPC of the fifth embodiment. (B) is a cross-sectional view of the FPC of the fifth embodiment. (C) is a bottom view of the FPC of the fifth embodiment. (A) is a top view of the FPC of the second modification. (B) is a cross-sectional view of the FPC of the second modification. (C) is a bottom view of the FPC of the second modification.

The first embodiment, the first modification, the second to fifth embodiments, and the second modification according to the present invention will be described in detail in order with reference to the accompanying drawings. The present invention is not limited to the illustrated examples.

(First Embodiment)
A first embodiment according to the present invention will be described with reference to FIGS. 1 to 9. First, the apparatus configuration of the ultrasonic diagnostic apparatus 100 of the present embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a diagram showing an external configuration of the ultrasonic diagnostic apparatus 100 of the present embodiment. FIG. 2 is a block diagram showing a functional configuration of the ultrasonic diagnostic apparatus 100.

As shown in FIG. 1, the ultrasonic diagnostic apparatus 100 includes an ultrasonic diagnostic apparatus main body 1 and an ultrasonic probe 2A. The ultrasonic probe 2A transmits ultrasonic waves (transmitted ultrasonic waves) to a subject such as a living body (not shown), and the reflected waves of ultrasonic waves reflected in the subject (reflected ultrasonic waves: echo). To receive. The ultrasonic diagnostic apparatus main body 1 is connected to the ultrasonic probe 2A, and transmits an electric signal drive signal to the ultrasonic probe 2A to transmit the ultrasonic wave to the subject to the ultrasonic probe 2A. Is transmitted, and the inside of the subject is based on the received signal, which is an electric signal generated by the ultrasonic probe 2A in response to the reflected ultrasonic waves from the subject received by the ultrasonic probe 2A. The state is imaged as ultrasonic image data.

The ultrasonic probe 2A includes a piezoelectric vibrator (piezoelectric body, piezoelectric element, vibrator) 311 (see FIG. 2) on the tip side, and the piezoelectric vibrator 311 is, for example, in the azimuth direction (scanning direction). Multiple pieces are arranged in a one-dimensional array. The piezoelectric vibrators 311 may be arranged in a two-dimensional array. Further, the number of piezoelectric vibrators 311 can be arbitrarily set. Further, in the present embodiment, the electronic scanning probe of the linear scanning method is adopted as the ultrasonic probe 2A, but either the electronic scanning method or the mechanical scanning method may be adopted, and the linear scanning may be adopted. Any method, a sector scanning method, or a convex scanning method can be adopted.

Next, the functional configuration of the ultrasonic diagnostic apparatus 100 will be described with reference to FIG. As shown in FIG. 2, the ultrasonic diagnostic apparatus main body 1 includes, for example, an operation input unit 11, a transmission unit 12, a reception unit 13, an image generation unit 14, an image processing unit 15, and a display control unit 16. , A display unit 17 and a control unit 18.

The operation input unit 11 receives operation inputs of operators such as doctors and technicians. The operation input unit 11 is, for example, various switches for inputting a command for instructing the start of diagnosis, data such as personal information of a subject, ultrasonic image data, and various image parameters for displaying on the display unit 17. , Buttons, trackballs, mice, keyboards, etc., and outputs operation signals to the control unit 18. The operation input unit 11 may be configured to include a touch panel provided on the display panel of the display unit 17 and accepting the touch input of the operator.

The transmission unit 12 is a circuit that supplies a drive signal, which is an electric signal, to the ultrasonic probe 2A and generates a transmission ultrasonic wave to the ultrasonic probe 2A under the control of the control unit 18. Further, the transmission unit 12 includes, for example, a clock generation circuit, a delay circuit, and a pulse generation circuit. The clock generation circuit is a circuit that generates a clock signal that determines the transmission timing and transmission frequency of the drive signal. The delay circuit sets a delay time for each individual path corresponding to each piezoelectric vibrator 311, delays the transmission of the drive signal by the set delay time, and focuses the transmission beam composed of the transmitted ultrasonic waves. It is a circuit of. The pulse generation circuit is a circuit for generating a pulse signal as a drive signal at a predetermined cycle. The transmission unit 12 configured as described above comprises, for example, a continuous part (for example, 64) of a plurality (for example, 192) of piezoelectric vibrators 311 arranged on the ultrasonic probe 2A. Drive to generate transmitted ultrasonic waves. Then, the transmission unit 12 scans (scans) by shifting the piezoelectric vibrator 311 that is driven each time the transmitted ultrasonic waves are generated in the directional direction (scanning direction).

The receiving unit 13 is a circuit that receives a received signal, which is an electric signal, from the ultrasonic probe 2A under the control of the control unit 18. The receiving unit 13 includes, for example, an amplifier, an A / D conversion circuit, and a phasing addition circuit. The amplifier is a circuit for amplifying a received signal at a preset amplification factor for each individual path corresponding to each piezoelectric vibrator 311. The A / D conversion circuit is a circuit for analog-to-digital conversion (A / D conversion) of the amplified received signal. The phase-adjusting addition circuit adjusts the time phase by giving a delay time for each individual path corresponding to each piezoelectric vibrator 311 to the A / D-converted received signal, and adds (phase-adjusting addition) these. This is a circuit for generating sound line data.

The image generation unit 14 performs envelope detection processing, logarithmic compression, and the like on the sound line data from the reception unit 13 under the control of the control unit 18, adjusts the dynamic range and gain, and performs luminance conversion. , B (Brightness) mode image data composed of pixels having a luminance value as reception energy can be generated. That is, the B-mode image data represents the strength of the received signal by the brightness. The image generation unit 14 includes B-mode image data as ultrasonic image data whose image mode is B mode, A (Amplitude) mode, M (Motion) mode, an image mode by the Doppler method (color Doppler mode, etc.), and the like. It may be capable of generating ultrasonic image data of other image modes.

The image processing unit 15 performs image processing on the B-mode image data output from the image generation unit 14 according to various image parameters being set according to the control of the control unit 18. Further, the image processing unit 15 includes an image memory unit 15a configured by a semiconductor memory such as a DRAM (Dynamic Random Access Memory). The image processing unit 15 stores the image-processed B-mode image data in the image memory unit 15a in frame units under the control of the control unit 18. Image data in frame units may be referred to as ultrasonic image data or frame image data. The image processing unit 15 sequentially outputs the image data generated as described above to the display control unit 16 under the control of the control unit 18.

According to the control of the control unit 18, the display control unit 16 converts the image data received from the image processing unit 15 into an image signal for display and outputs the image data to the display unit 17.

A display device such as an LCD (Liquid Crystal Display), a CRT (Cathode-Ray Tube) display, an organic EL (Electronic Luminescence) display, an inorganic EL display, or a plasma display can be applied to the display unit 17. The display unit 17 displays a still image or a moving image of ultrasonic image data on the display screen according to the image signal output from the display control unit 16 under the control of the control unit 18.

The control unit 18 includes, for example, a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory), and reads various processing programs such as a system program stored in the ROM and expands them into the RAM. , The operation of each part of the ultrasonic diagnostic apparatus 100 is controlled according to the developed program. The ROM is composed of a non-volatile memory such as a semiconductor, and stores a system program corresponding to the ultrasonic diagnostic apparatus 100, various processing programs that can be executed on the system program, and various data such as a gamma table. These programs are stored in the form of a computer-readable program code, and the CPU sequentially executes operations according to the program code. The RAM forms a work area for temporarily storing various programs executed by the CPU and data related to these programs.

For each part included in the ultrasonic diagnostic apparatus 100, a part or all the functions of each functional block can be realized as a hardware circuit such as an integrated circuit. The integrated circuit is, for example, an LSI (Large Scale Integration), and the LSI may be referred to as an IC (Integrated Circuit), a system LSI, a super LSI, or an ultra LSI depending on the degree of integration. Further, the method of making an integrated circuit is not limited to the LSI, but may be realized by a dedicated circuit or a general-purpose processor, and the connection and setting of the FPGA (Field Programmable Gate Array) and the circuit cell inside the LSI can be reconfigured. A reconfigurable processor may be used. Further, a part or all of the functions of each functional block may be executed by software. In this case, this software is stored in one or more storage media such as ROM, an optical disk, a hard disk, or the like, and this software is executed by an arithmetic processor.

Then, the apparatus configuration of the ultrasonic probe 2A will be described with reference to FIGS. 3 to 9. FIG. 3 is a perspective view showing an external configuration of the ultrasonic probe 2A. FIG. 4 is a perspective view of the acoustic sensor unit 30A. FIG. 5A is a top view of the FPC32A. FIG. 5B is a cross-sectional view of the FPC 32A. FIG. 6 is a perspective view showing the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A before connection. FIG. 7A is a transparent side view showing the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A before connection. FIG. 7B is a transparent side view showing the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A after connection. FIG. 8A is a perspective view showing the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A after connection. FIG. 8B is a perspective view showing the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A to which the GND plate 301A is connected. FIG. 8C is a perspective view showing the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A after the GND plate 301A is attached. FIG. 9 is a perspective view showing an acoustic sensor unit 30A to which the coaxial cable 60 is connected.

As shown in FIG. 3, the ultrasonic probe 2A includes an ultrasonic probe main body 3A, a cable 6, and a probe connector 7. The ultrasonic probe main body 3A is a main body portion of the ultrasonic probe 2A, and has an acoustic sensor portion 30A (FIG. 4) and a connector portion 40A (FIG. 6) as a first connector portion inside the housing. And a coaxial connector portion 50A (FIG. 6) as a second connector portion is provided.

The cable 6 is a cable that electrically connects the ultrasonic probe main body 3A and the probe connector 7, and has a plurality of coaxial cables 60 (FIG. 6). The plurality of coaxial cables 60 are thin coaxial cables. Despite being a thin cable, each thin coaxial cable has a coaxial structure, has excellent transmission characteristics, and has high flexibility and twistability, so ultrasonic detection is possible. Often used for tentacles. It is assumed that the number of coaxial cables 60 is, for example, an integral multiple of 8.

The probe connector 7 is a connector for connecting the cable 6 to the ultrasonic diagnostic apparatus main body 1. The probe connector 7 has a storage unit for storing the type information of the ultrasonic probe 2A, and has a configuration for transmitting the stored type information of the ultrasonic probe 2A to the ultrasonic diagnostic apparatus main body 1. You may.

As shown in FIG. 4, the acoustic sensor unit 30A has a back load material 314, an FPC 32A as a flexible substrate, a piezoelectric vibrator 311, an acoustic matching layer 312a, a GND film 33, an acoustic matching layer 312b, and an acoustic lens from the lower surface to the upper surface. The 313s are stacked in order.

The piezoelectric vibrator 311 is a piezoelectric element having electrodes on both sides for transmitting and receiving ultrasonic waves. A ground electrode layer is formed on the upper surface of the piezoelectric vibrator 311 as a first electrode layer, and a positive electrode layer is formed on the lower surface as a second electrode layer in advance.

The acoustic matching layer 312a is for efficiently transmitting and receiving ultrasonic waves to a subject (living body), is composed of a conductor having acoustic impedance between the piezoelectric vibrator 311 and the living body, and is pressure-cured and has insulating properties. It is laminated on the upper surface (ground electrode layer side) of the piezoelectric vibrator 311 via an adhesive layer. The acoustic matching layer 312a may be arranged on the GND film 33.

The GND film 33 is laminated on the acoustic matching layer 312a via a pressure-cured insulating adhesive layer. The GND film 33 includes a film body 331 of a polymer film such as polyimide, which is a polymer material, as an acoustic matching layer, and a GND layer 332 as a conductor layer (copper layer) formed on the adhesive layer side of the film body 331. It consists of two layers. The GND layer 332 functions as a GND terminal at the end portion. The GND terminal of the GND film 33 is electrically connected to the exposed GND terminal of the GND layer 322A of the FPC 32A by soldering or the like.

The acoustic matching layer 312b is made of a material such as a polymer material having an acoustic impedance between the acoustic matching layer 312a and the living body in order to further achieve acoustic matching with the living body, and is formed on the surface of the film body of the FPC 32A. It is laminated via an adhesive layer.

The acoustic lens 313 is provided on the surface of the acoustic matching layer 312b and converges the ultrasonic waves. Further, the acoustic matching layer 312a, the GND film 33, and the acoustic matching layer 312b laminated on the FPC 32A, the piezoelectric vibrator 311 and the piezoelectric vibrator 311 are divided into a plurality of electrically independent arrays by dicing. The groove g1 is formed. As a result, the number of piezoelectric vibrators 311 is set to an integral multiple of 8, for example, 8, 16, 32, 40, 48.

FPC32A is laminated on the lower surface (positive electrode layer side) of the piezoelectric vibrator 311 via a pressure-cured insulating adhesive layer. In the FPC32A, a conductive pattern corresponding to the piezoelectric vibrator 311 is formed on the polyimide base portions 3261A and 3262A (FIG. 5B) and on the piezoelectric vibrator 311 side on the base portions 3261A and 3262A. Further, both sides of the piezoelectric vibrator 311 of the FPC 32A in a drunken direction extend from the laminated portion with the piezoelectric vibrator 311, and the GND terminals exposed of the GND layer 322A are formed on both ends of the extending portion. The signal line terminal 321A1 is formed. Further, the FPC 32A has a reinforcing material 324 for reinforcing the signal line terminal 321A1 and the like on the base portion 3262A side of the FPC 32A.

The back load material 314 is attached to the base portion 3262A side of the FPC 32A via an adhesive, mechanically supports the piezoelectric vibrator 311 and acoustically brakes the piezoelectric vibrator 311 to shorten the ultrasonic pulse waveform. do.

The drive signals as a plurality of electric signals transmitted from the transmission unit 12 of the ultrasonic diagnostic apparatus main body 1 are transmitted to the plurality of piezoelectric vibrators 311 arranged in an array via the cable 6 (coaxial cable 60) and the FPC 32A. It is applied. The piezoelectric vibrator 311 excites (transmits) ultrasonic waves (mechanical vibration) in response to the applied drive signal. The excited ultrasonic waves are acoustically matched with the living body by the acoustic matching layers 312a and 312b and the acoustic lens 313, converged by the acoustic lens 313, and sent into the living body. Further, the piezoelectric vibrator 311 generates (receives) an electric signal in response to the ultrasonic waves returned from the living body due to the piezoelectric effect. After being converted into an electric signal, it is input to the receiving unit 13 of the ultrasonic diagnostic apparatus main body 1 via the coaxial cable 60. The received signal received by the receiving unit 13 is processed to generate ultrasonic image data, and by displaying the ultrasonic image data on the display unit 17 of the ultrasonic diagnostic apparatus main body 1, the user can view the ultrasonic image inside the patient's body. Can be visually confirmed.

As shown in FIGS. 5A and 5B, the FPC32A has a reinforcing material 324, a base portion 3262A, a signal line layer 321A, a base portion 3261A, a GND layer 322A, and a coverlay 323A from the lower surface to the upper surface. They are stacked in order. As shown in FIG. 5A, in the FPC 32A, the vibrator bonding portion 325 is arranged in the central portion when viewed from the upper surface, and the directions are opposite to each other perpendicular to the directional direction of the piezoelectric vibrator 311 of the vibrator bonding portion 325. The exposed portions (GND terminals) of the six GND layers 322A and the four signal line terminals 321A1 of the signal line layer 321A are exposed in each of the two directions.

The base portions 3261A and 3262A are insulators such as film-shaped polyimide. The signal line layer 321A is a conductor such as a copper foil, and is a layer having lines for driving signals and received signals. The GND layer 322A is a conductor such as a copper foil and is a layer to be grounded. The vibrator bonding portion 325 is a solid conductor surface of a part of the signal line layer 321A, and the piezoelectric vibrator 311 is bonded.

As shown in FIG. 6, one signal line terminal 321A1 of the FPC 32A of the acoustic sensor unit 30A is connected to the coaxial connector unit 50A connected to the coaxial cable 60 via the connector unit 40A. The connector CA shall have a connector portion 40A and a coaxial connector portion 50A. The connector portion 40A is a connector that does not need to be attached to a PCB (Printed Circuit Board). The connector portion 40A has an FPC insertion port 411A and a coaxial connector portion insertion port 421A. The FPC 32A is inserted into the FPC insertion slot 411A and connected to the connector portion 40A. The coaxial connector portion 50A is inserted into the coaxial connector portion insertion port 421A and connected to the coaxial connector portion 40A.

In order to connect the acoustic sensor unit provided with the FPC and the coaxial cable, the PCB on which the FPC connector is mounted and the coaxial cable is solder-connected, or the receptacle side of the coaxial connector connected to the FPC connector and the coaxial cable A configuration using the mounted PCB is also conceivable. However, in a configuration using a PCB, the outer shape of the PCB must be designed so that it can be housed inside the housing of the ultrasonic probe. Further, since a PCB is used, the sensitivity and band of the ultrasonic probe deteriorate due to the influence of waveform disturbance and crosstalk noise due to the reflection of electric signals due to the characteristic impedance of the PCB, and the wiring resistance of the PCB. Further, a method of directly connecting the coaxial cable to the FPC and eliminating the connector is also conceivable, but the connection work is not easy and causes a deterioration in yield.

In the ultrasonic probe 2A, the signal line 61 of the coaxial cable 60 connecting the signal line terminal 321A1 of the FPC 32A extending from the acoustic sensor unit 30A to the ultrasonic diagnostic apparatus 100 by the connector portion 40A (FIG. 7A). , FIG. 7 (b) can be easily connected, and the extra electric signal path by the PCB is eliminated. Therefore, the sensitivity of the ultrasonic probe 2A is increased and the band is widened.

As shown in FIG. 7A, the connector portion 40A includes a base portion 400A, a shield portion, a GND portion 401A as a first shield portion, a flip 402A, a first signal line, and a second signal line. The signal line 403A and the like are provided. Further, the connector portion 40A has a configuration in which the FPC connector portion 41A to which the FPC 32A is connected and the coaxial connector portion 42A to which the coaxial connector portion 50A is connected are integrated.

The base portion 400A is a base of the connector portion 40A, and is made of, for example, an insulator material. The GND portion 401A is composed of a grounded conductor provided on the base portion 400A, and shields the signal lines 403A, FPC32A, and signal line 503A from noise due to disturbance as a metal cover. The flip 402A is a component that is provided on the base portion 400A of the FPC connector portion 41A and is folded to lower the terminal at the tip of the signal line 403A on the FPC side.

The signal line terminal 321A1 of the FPC 32A has a number of poles (number of terminals) that is an integral multiple of 8 corresponding to the number of poles of the cable 6 (the number of coaxial cables 60), and is provided with spare terminals as necessary. It is assumed that they are arranged side by side. The signal line 403A is a number of conducting wires corresponding to the number of coaxial cables 60, and is arranged in two rows in a staggered manner corresponding to the signal line terminal 321A1. The pitch between the terminals of the FPC32A and the signal line 403A can be narrowed by arranging them in two rows in a staggered manner, and are the same, for example, 0.3, 0.4, and 0.5 [mm].

As shown in FIG. 7B, when the FPC32A is inserted into the FPC insertion slot 411A and the flip 402A is folded, the signal line terminal 321A1 and the signal line 403A are pressure-welded and face each other on a one-to-one basis for electricity. Is connected. However, the terminals on the FPC side of the signal line terminals 321A1 and the signal line 403A may be arranged in a row. The terminals on the coaxial cable side of the signal line 403A are arranged, for example, in a row.

As shown in FIG. 7A, the coaxial cable 60 has a signal line (inner conductor) 61, an insulator layer (not shown), and a coaxial shielded wire as a shielded wire coaxially outward from the center of the cross section in the axial direction. It has (outer conductor) 62 and a coating layer 63. The signal line 61 is a line made of a conductor through which a drive signal and a received signal flow. The insulator layer is made of an insulator and insulates the signal line and the coaxial shielded line. The coaxial shielded wire 62 is a wire made of a conductor and grounded, and protects the signal wire 61 from noise due to disturbance. The coating layer 63 is made of an insulator and protects the inside of the coaxial cable 60 from an external impact.

The coaxial connector portion 50A includes a base portion 500A, a shield portion, a GND portion 501A as a second shield portion, a connection portion 502A, and a signal line 503A as a first signal line and a third signal line. Be prepared. The base portion 500A is a base of the coaxial connector portion 50A, and is made of, for example, an insulator material. The GND portion 501A is made of a conductor to be grounded, and as a metal cover, shields the signal line 503A and the coaxial cable 60 from noise due to disturbance. The connecting portion 502A is a conductor connected to the GND portion 501A and is electrically connected to the exposed coaxial shielded wire 62. The signal line 503A is a number of copper wires corresponding to the number of coaxial cables 60, and is arranged, for example, in a row corresponding to the signal line 403A. The plurality of signal lines 503A and the plurality of signal lines 61 are soldered one-to-one, respectively, and are electrically connected by the solder connection portion s1. Further, it is assumed that the number of poles and the pitch of the signal lines 403A and 503A are the same.

In this way, the coaxial connector portion 50A is attached to the input end (output end) of the ultrasonic diagnostic apparatus main body 1 via the coaxial cable 60, and the high frequency signal can be attached and detached without loss. In the coaxial connector portion 50A, the coaxial cables 60 are collectively connected by soldering, but they may be connected by pressure welding. The coaxial connector portion 50A is formed so as to surround the coaxial connector portion 50A by the GND portion 501A, and noise countermeasures due to disturbance are taken.

As shown in FIG. 7B, the signal line 403A and the signal line 503A are electrically opposed to each other on a one-to-one basis by inserting the coaxial connector portion 50A into the coaxial connector portion insertion port 421A and pressing them together. Be connected. At the same time, the GND unit 401A is electrically connected to the coaxial shielded wire 62 via the connection unit 502A by the connection with the GND unit 501A and is grounded. In this way, the signal line terminal 321A1 of the FPC 32A and the signal line 61 of the coaxial cable 60 are connected via the connector portion 40A and the coaxial connector portion 50A.

As shown in FIG. 8A, the FPC 32A and the coaxial connector portion 50A are connected via the connector portion 40A. In this state, as shown in FIG. 8B, one end of the GND plate 301A is soldered to the GND layer 322A and the GND portion 401A of the FPC 32A, and is electrically connected by the solder connection portion s2. The GND plate 301A is a conductor plate such as a copper foil. As a result, the GND layer 322A is grounded via the GND plate 301A, and the GND film 33 is also grounded. Then, the GND plate 301A is folded so as to cover the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A. Then, as shown in FIG. 8C, the other end of the GND plate 301A is soldered to the GND plate 301A and electrically connected by the solder connection portion s3. The GND plate 301A shields the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A from noise caused by disturbance.

Then, as shown in FIG. 9, the coaxial cable 60 is connected to the four signal line terminals 321A1 of the FPC 32A of the acoustic sensor unit 30A via the connector portion 40A and the coaxial connector portion 50A to which the GND plate 301A is attached, respectively. Will be done. The acoustic sensor portion 30A, the connector portion 40A, the coaxial connector portion 50A, and the GND plate 301A assembled in this way are housed in the housing of the ultrasonic probe main body 3A.

As described above, according to the present embodiment, the ultrasonic probe 2A has a plurality of piezoelectric vibrators 311 that transmit and receive ultrasonic waves, and a signal line terminal 321A1 of a signal line electrically connected to the piezoelectric vibrator 311. The signal line 61 is connected to the acoustic sensor unit 30A including the FPC 32A having the above and the ultrasonic diagnostic apparatus main body 1 that generates ultrasonic image data based on the received signal obtained by transmitting the drive signal to the acoustic sensor unit 30A. The cable 6 is provided with a connector CA for electrically connecting the signal line terminal 321A1 of the FPC 32A and the signal line 61 of the cable 6. The connector CA has grounded GND portions 401A and 501A that cover the connection portion between the signal line terminal 321A1 of the FPC 32A and the signal line 61 of the cable 6. Therefore, since the GND units 401A and 501A shield noise due to disturbance, it can be made strong against EMI, and the signal line of FPC32A can be easily electrically connected to the signal line 61 of the cable 6 by the connector CA, and ultrasonic detection can be performed. The child 2A can be easily manufactured.

Further, the connector CA electrically connects the signal line terminal 321A1 of the FPC 32A and the signal line 61 of the cable 6 without going through the wiring board (PCB). Therefore, since it does not go through the PCB, the waveform disturbance due to the reflection of the electric signal due to the characteristic impedance of the PCB, the influence of crosstalk noise, and the wiring resistance of the PCB are eliminated, and the ultrasonic probe 2A is made highly sensitive and wide band. can.

Further, the connector CA has signal lines 403A and 503A for connecting the signal line terminal 321A1 of the FPC 32A and the signal line 61 of the cable 6, the contacts on the FPC side of the signal lines 403A and 503A, and the cable side. The number of poles and pitch with the contacts are equal. Therefore, the signal line terminal 321A1 of the FPC 32A and the signal line 61 of the cable 6 can be reliably and easily connected, and the connector CA can be miniaturized and the structure can be simplified.

Further, the number of poles of the contacts on the FPC side of the signal lines 403A and 503A and the number of poles of the contacts on the cable side are multiples of 8. Therefore, the piezoelectric vibrators 311 are provided in multiples of 8, and the piezoelectric vibrators 311 and the signal line 61 of the cable 6 can be reliably and easily connected via the FPC 32A and the connector CA.

Further, the cable 6 has a plurality of coaxial cables 60 having a signal line 61 and a coaxial shielded wire 62. In the connector CA, the signal line terminal 321A1 of the FPC 32A is inserted, the connector part 40A having the GND part 401A and the signal line 403A, and the signal line 61 and the coaxial shielded line 62 of the coaxial cable 60 are inserted, and the GND part 501A and the signal line are inserted. It has a coaxial connector portion 50A having 503A and a coaxial connector portion 50A. The coaxial connector portion 50A electrically connects the signal line 61 and the signal line 503A of the inserted coaxial cable 60, and electrically connects the coaxial shielded wire 62 of the inserted coaxial cable 60 and the GND portion 501A. .. The connector portion 40A was inserted by electrically connecting the signal line terminal 321A1 of the FPC 32A into which the coaxial connector portion 50A was inserted and the signal line 503A of the inserted coaxial connector portion 50A by the signal line 403A. The GND section 501A and the GND section 401A of the coaxial connector section 50A are electrically connected. Therefore, the signal line terminal 321A1 of the FPC 32A extending from the acoustic sensor unit 30A and the signal line 61 of the coaxial cable 60 can be easily electrically connected, and the GND units 401A and 501A and the coaxial shielded wire 62 of the coaxial cable 60 can be connected. Can be easily connected electrically.

Further, the FPC 32A has a conductive GND layer 322A. The ultrasonic probe 2A electrically connects the GND layer 322A and the GND section 401A, and includes a conductive GND plate 301A. Therefore, the GND layer 322A of the FPC 32A on the acoustic sensor unit 30A side can be reliably grounded.

Further, the GND plate 301A covers the connector CA. Therefore, noise due to disturbance to the acoustic sensor unit 30A can be reduced.

Further, the FPC 32A has a GND terminal (exposed portion) of the GND layer 322A to which the GND plate 301A is connected. Therefore, the GND layer 322A of the acoustic sensor unit 30A can be reliably and easily grounded.

Further, the ultrasonic diagnostic apparatus 100 includes an ultrasonic probe 2A and an ultrasonic diagnostic apparatus main body 1. Therefore, it is possible to generate ultrasonic image data in which noise due to disturbance is reduced, and it is possible to facilitate the manufacture of the ultrasonic diagnostic apparatus 100 having the ultrasonic probe 2A.

Further, the ultrasonic probe 2A includes a GND film 33 formed on the upper surface side of the piezoelectric vibrator 311 and electrically connected to the GND layer 322A. Therefore, noise due to disturbance to the piezoelectric vibrator 311 and the like can be reduced.

(First modification)
A first modification as a modification of the first embodiment will be described with reference to FIG. FIG. 10 is a transparent side view showing the FPC 32A and the coaxial connector portion 50B before connection.

The device configuration of this modification is the coaxial connector as a third connector portion in the ultrasonic diagnostic apparatus 100 of the first embodiment, instead of the connector portion 40A and the coaxial connector portion 50A of the ultrasonic probe 2A. The configuration is such that the portion 50B is provided. Therefore, the same components as those of the ultrasonic diagnostic apparatus 100 of the first embodiment are designated by the same reference numerals, and mainly different components will be described.

As shown in FIG. 10, the coaxial connector portion 50B includes a base portion 500B, a GND portion 501B as a shield portion, a first signal line, a signal line 503B as a fourth signal line, and a flip 504B. Be prepared. The connector CB shall have only the coaxial connector portion 50B. The base portion 500B is a base of the coaxial connector portion 50B, and is made of, for example, an insulator material. The GND unit 501B is made of a grounded conductor, and as a metal cover, shields the signal line 503B, the FPC 32A, and the coaxial cable 60 from noise caused by disturbance. The connecting portion 502B is a conductor connected to the GND portion 501B and is electrically connected to the exposed coaxial shielded wire 62. The signal line 503B is a number of copper wires corresponding to the number of coaxial cables 60, and terminals on the FPC side are arranged side by side in two rows, for example, in a staggered manner corresponding to the signal line terminals 321A1 of the FPC 32A. The plurality of terminals on the coaxial cable side of the signal line 503B and the plurality of signal lines 61 are solder-connected, respectively, and are electrically connected one-to-one at the solder connection portion s1.

The flip 504B is a component provided on the base portion 400A and that lowers the terminal at the tip of the signal line 503B on the FPC side by being folded. The signal line terminal 321A1 and the signal line 503B are electrically connected to each other on a one-to-one basis by inserting the FPC 32A into the FPC insertion port of the coaxial connector portion 50B and folding and pressing the flip 504B. However, the terminals on the FPC side of the signal line terminals 321A1 and the signal line 503B may be arranged in a row. In this way, the signal line terminal 321A1 of the FPC 32A and the signal line 61 of the coaxial cable 60 are connected via the coaxial connector portion 50B.

According to this modification, the connector CB has a signal line 503B, and the signal line terminal 321A1 of the FPC 32A and the coaxial cable 60 are inserted, and the signal line terminal 321A1 of the inserted FPC 32A and the inserted coaxial cable 60 are inserted. It has a coaxial connector portion 50B that electrically connects the signal line 61 with the signal line 503B and electrically connects the coaxial shielded wire 62 of the inserted coaxial cable 60 and the GND portion 501B. Therefore, the number of parts of the connector CB can be reduced, and the ultrasonic probe 2A can be manufactured more easily. Since the flip 504B is easily damaged, the coaxial connector portion 50B and the cable 6 are discarded when the flip 504B is damaged.

(Second Embodiment)
A second embodiment according to the present invention will be described with reference to FIGS. 11 to 12 (c). FIG. 11 is a plan view showing the FPC 32C. FIG. 12A is a perspective view showing the FPC 32C, the connector portion 40A, and the coaxial connector portion 50A to which the GND covering portion 320C1 is connected. FIG. 12B is a perspective view showing the front side of the FPC 32C, the connector portion 40A, and the coaxial connector portion 50A coated with the GND covering portion 320C1. FIG. 12C is a perspective view showing the back side of the FPC 32C, the connector portion 40A, and the coaxial connector portion 50A coated with the GND covering portion 320C1.

The device configuration of the present embodiment is such that the ultrasonic diagnostic apparatus 100 of the first embodiment is provided with an FPC 32C instead of the FPC 32A of the acoustic sensor unit 30A of the ultrasonic probe 2A. Therefore, the same components as those of the ultrasonic diagnostic apparatus 100 of the first embodiment are designated by the same reference numerals, and mainly different components will be described.

As shown in FIG. 11, in the FPC 32C, a reinforcing material 324, a base portion (not shown), a signal line layer 321C, a base portion (not shown), a GND layer 322C, and a coverlay 323C are laminated in this order from the lower surface to the upper surface. ing. The base portion, the signal line layer 321C, the base portion, the GND layer 322C, and the coverlay 323C are the base portion 3262A, the signal line layer 321A, the base portion 3261A, and the GND layer 322A of the FPC 32A of the first embodiment, respectively. It has the same configuration as the coverlay 323A, but the shape seen from the top is different.

When viewed from the upper surface, the FPC 32C has an oscillator bonding portion 325, a coverlay 323C, an exposed portion (GND terminal) of a plurality of GND layers 322C, a signal line terminal 321C1 of four signal line layers 321C, and a GND covering portion 320C1, 320C2. It has 320C3 and 320C4. The signal line terminal 321C1 is the same as the signal line terminal 321A1 of the FPC 32A of the first embodiment.

The GND covering portions 320C1, 320C2, 320C3, 320C4 are rectangular plate-shaped portions connected in the vicinity of each of the four signal line terminals 321C1. Since the GND covering portions 320C1, 320C2, 320C3, and 320C4 have the same configuration, the GND covering portion 320C1 will be described as a representative.

The GND covering portion 320C1 has a coverlay 323C, an opening o1 which is a through hole, and GND terminals 322C1, 322C2, 322C3 as exposed portions of the GND layer 322C when viewed from the upper surface. The GND terminal 322C1 has an annular shape and is arranged around the opening o1. The GND terminal 322C2 has a band shape and is arranged between the signal line terminal 321C1 and the opening o1. The GND terminal 322C3 has a band shape and is arranged at an end opposite to the signal line terminal 321C1.

Then, as shown in FIG. 12 (a), the connection is the same as the connection between the FPC 32A having one signal line terminal 321A1 of FIG. 8 (a) of the first embodiment, the connector portion 40A, and the coaxial connector portion 50A. The FPC 32C having one signal line terminal 321C1 and the GND covering portion 320C1, the connector portion 40A, and the coaxial connector portion 50A are connected to the FPC 32C. Then, the GND covering portion 320C1 is folded so as to cover (enclose) the signal line terminal 321C1, the connector portion 40A, and the coaxial connector portion 50A.

Then, as shown in FIG. 12B, the GND terminal 322C1 is soldered to the GND portion 401A of the connector portion 40A exposed through the opening o1, and is electrically connected by the solder connection portion s4.

Then, as shown in FIG. 12C, the GND terminal 322C3 is soldered to the GND terminal 322C2 on the back surface of the solder connection portion s4, and is electrically connected by the solder connection portion s5.

The above connection is made to the four signal line terminals 321C1 (GND covering portions 320C1, 320C2, 320C3, 320C4), and the connected acoustic sensor portion, connector portion 40A and coaxial connector portion 50A are ultrasonically detected. It is stored in the housing of the child main body 3A.

As described above, according to the present embodiment, the FPC 32C includes a GND coating portion 320C1, 320C2, 320C3, 320C4 having a conductive GND layer 322C and a part of the GND layer 322C. The GND covering portions 320C1, 320C2, 320C3, 320C4 cover the connector CA and electrically connect the GND layer 322C and the GND portion 401A. Therefore, the GND layer 322C of the FPC 32C on the acoustic sensor unit 30A side can be reliably grounded, and the GND coating units 320C1, 320C2, 320C3, 320C4 can reduce noise due to disturbance, and no additional measures such as a separate GND plate are required. The structure of the ultrasonic probe 2A can be simplified, and the ultrasonic probe 2A can be manufactured more easily.

(Third Embodiment)
A third embodiment according to the present invention will be described with reference to FIGS. 13 to 15. FIG. 13 is a perspective view of the acoustic sensor unit 30D. FIG. 14A is a top view of the FPC32D. FIG. 14B is a cross-sectional view of the FPC 32D. FIG. 15 is a transparent side view showing the FPC 32D, the connector portion 40D, and the coaxial connector portion 50D after connection.

In the device configuration of the present embodiment, in the ultrasonic diagnostic apparatus 100 of the first embodiment, the acoustic sensor unit 30A, the connector unit 40A, and the coaxial connector unit 50A of the ultrasonic probe 2A are replaced with the acoustic sensor unit. 30D, a connector portion 40D as a first connector portion, and a coaxial connector portion 50D as a second connector portion are provided. Therefore, the same components as those of the ultrasonic diagnostic apparatus 100 of the first embodiment are designated by the same reference numerals, and mainly different components will be described.

As shown in FIG. 13, in the acoustic sensor unit 30D, the back load material 314, the FPC32D, the piezoelectric vibrator 311, the acoustic matching layer 312a, the GND film 33, the acoustic matching layer 312b, and the acoustic lens 313 are laminated in this order from the lower surface to the upper surface. Has been done.

As shown in FIGS. 14A and 14B, the FPC32D has a reinforcing material 324, a base portion 3262D, a signal line layer 321D, a GND layer 3222D, a base portion 3261D, and a GND from the lower surface to the upper surface. The layer 3221D and the coverlay 323D are laminated in this order. The base portion 3262D, the signal line layer 321D, the base portion 3261D, the GND layer 3221D, and the coverlay 323C are the base portion 3262A, the signal line layer 321A, the base portion 3261A, and the GND layer 322A of the FPC 32A of the first embodiment, respectively. It has the same configuration as the coverlay 323A.

The signal line layer 321D and the GND layer 3222D are in the same layer, but their positions when viewed from above are different. The FPC 32D includes four signal line terminals 321D1 of the signal line layer 321D at the end centered on the vibrator bonding portion 325 and GND terminals 322D1 provided at both side ends of each signal line terminal 321D1 when viewed from the upper surface. , And the GND layer 3222D provided at both side ends of the signal line layer 321D corresponding to each signal line terminal 321D1. The GND layer 3221D and the GND layer 3222D are electrically connected to each other via a through hole t1.

As shown in FIG. 15, the connector portion 40D includes a base portion 400D, a GND portion 401D, a flip 402D, a first signal line, a signal line 403D as a second signal line, a shield portion, and a first signal line. It is provided with a GND wire 404D as a shield portion. Further, the connector portion 40D has a configuration in which the FPC connector portion 41D to which the FPC 32D is connected and the coaxial connector portion 42D to which the coaxial connector portion 50D is connected are integrated. The connector CD shall have a connector portion 40D and a coaxial connector portion 50D.

The base portion 400D is a base of the connector portion 40D, and is made of, for example, an insulator material. The GND unit 401D is composed of a grounded conductor provided on the base unit 400D, and shields the signal lines 403D, FPC32D, and signal line 503D from noise due to disturbance as a metal cover. The flip 402D is a component provided on the base portion 400D of the FPC connector portion 41D, and when folded, lowers the terminals at the tips of the signal line 403D and the GND line 404D on the FPC side.

The signal line terminal 321D1 of the FPC 32D has a number of poles corresponding to the number of poles of the cable 6 (the number of coaxial cables 60), and is provided with spare terminals as needed, and is arranged side by side in two rows and staggered. do. The signal line 403D is a number of conducting wires corresponding to the number of coaxial cables 60, and is arranged in two rows in a staggered manner corresponding to the signal line terminal 321D1. The GND line 404D is grounded because it is made of a conductor and is electrically connected to the GND section 401D.

When the FPC 32D is inserted into the FPC insertion slot of the FPC connector portion 41D and the flip 402D is folded, the signal line terminal 321D1 and the signal line 403D are pressure-welded and are electrically connected to each other on a one-to-one basis. At the same time, the GND terminal 322D1 and the GND line 404D are pressure-welded and are electrically connected to each other on a one-to-one basis. The terminals on the FPC side of the signal line terminals 321D1 and the signal line 403D may be arranged in a row. The terminals on the coaxial cable side of the signal line 403D are arranged in a row, for example.

The coaxial connector portion 50D includes a base portion 500D, a shield portion, a GND portion 501D as a second shield portion, a connection portion 502D, and a signal line 503D as a first signal line and a third signal line. Be prepared. The base portion 500D, the GND portion 501D, the connection portion 502D, and the signal line 503D have the same configurations as the base portion 500A, the GND portion 501A, the connection portion 502A, and the signal line 503A of the coaxial connector portion 50A of the first embodiment, respectively. Has.

Then, the signal line 61 and the coaxial shielded wire 62 of the coaxial cable 60 are connected to the four sets of signal line terminals 321D1 and GND terminal 322D1 of the FPC 32D of the acoustic sensor unit 30D via the connector unit 40D and the coaxial connector unit 50D, respectively. Will be done. The acoustic sensor portion 30D, the connector portion 40D, and the coaxial connector portion 50D assembled in this way are housed in the housing of the ultrasonic probe main body 3A.

As described above, according to the present embodiment, the FPC 32D includes a GND layer 3222D which has conductivity and has a GND terminal 322D1. The connector CD has a GND line 404D on the FPC side that is electrically connected to the GND unit 401D and electrically connected to the GND terminal 322D1. Therefore, the GND layers 3221D and 3222D of the FPC32D on the acoustic sensor unit 30D side can be reliably grounded, additional measures such as a separate GND plate can be eliminated, and the structure of the ultrasonic probe 2A can be simplified. The ultrasonic probe 2A can be manufactured more easily.

Further, in the FPC 32D, the GND terminal 322D1 and the signal line terminal 321D1 are arranged side by side. Therefore, the structure of the connector CD (connector portion) can be simplified and miniaturized.

(Fourth Embodiment)
A fourth embodiment according to the present invention will be described with reference to FIGS. 16A to 17. FIG. 16A is a top view of the FPC 32E. FIG. 16B is a cross-sectional view of FPC32E. FIG. 16 (c) is a bottom view of the FPC 32E. FIG. 17 is a transparent side view showing the FPC 32E, the connector portion 40E, and the coaxial connector portion 50E after connection.

The apparatus configuration of the present embodiment is such that in the ultrasonic diagnostic apparatus 100 of the first embodiment, the FPC 32E is replaced with the FPC 32A, the connector portion 40A, and the coaxial connector portion 50A of the acoustic sensor portion 30A of the ultrasonic probe 2A. , The connector portion 40E as the first connector portion and the coaxial connector portion 50E as the second connector portion are provided. Therefore, the same components as those of the ultrasonic diagnostic apparatus 100 of the first embodiment are designated by the same reference numerals, and mainly different components will be described.

As shown in FIGS. 16A and 16B, in the FPC32E, the base portion 3262E, the signal line layer 321E, the base portion 3261E, the GND layer 322E, and the coverlay 323E are laminated in this order from the lower surface to the upper surface. There is. The base portion 3262E, the signal line layer 321E, the base portion 3261E, the GND layer 322E, and the coverlay 323E are the base portion 3262A, the signal line layer 321A, the base portion 3261A, and the GND layer 322A of the FPC 32A of the first embodiment, respectively. It has the same configuration as the coverlay 323A, but the shape seen from the top is different.

When viewed from above, the FPC32E has an oscillator bonding portion 325, a coverlay 323E, an exposed portion (GND terminal) of a plurality of GND layers 322E, four signal line terminals 321E1 of the signal line layer 321E, and a GND bending portion 320E1, 320E2. It has 320E3 (not shown) and 320E4 (not shown). The signal line terminal 321E1 is the same as the signal line terminal 321A1 of the FPC 32A of the first embodiment.

The GND bending portions 320E1, 320E2, 320E3, 320E4 are rectangular plate-shaped portions connected in the vicinity of each of the four signal line terminals 321E1. Since the GND bending portions 320E1, 320E2, 320E3, and 320E4 have the same configuration, the GND bending portion 320E1 will be described as a representative.

The GND bending portion 320E1 has a coverlay 323E and a GND terminal 322E1 of the GND layer 322E when viewed from the upper surface. The GND terminal 322E1 is arranged at the end on the opposite side (signal line terminal 321E1 side) from the vibrator bonding portion 325.

As shown in FIGS. 16B and 16C, the GND bent portion 320E1 is bonded to the back surface side of the signal line terminal 321E1 with a bending adhesive. The GND bending portion 320E1 is adhered to the base portion 3262E on the back surface of the signal line terminal 321E1 via the adhesive layer 327.

As shown in FIG. 17, the connector portion 40E includes a base portion 400E, a shield portion, a GND portion 401E as a first shield portion, a flip 402E, a first signal line, and a signal as a second signal line. The line 403E and the GND line 404E are provided. Further, the connector portion 40E has a configuration in which the FPC connector portion 41E to which the FPC 32E is connected and the coaxial connector portion 42E to which the coaxial connector portion 50E is connected are integrated. The connector CE shall have a connector portion 40E and a coaxial connector portion 50E.

The base portion 400E is a base of the connector portion 40E, and is made of, for example, an insulator material. The GND unit 401E is composed of a grounded conductor provided on the base unit 400D, and shields the signal lines 403E, FPC32E, and signal line 503E from noise due to disturbance as a metal cover. The flip 402E is a component that is provided on the base portion 400E of the FPC connector portion 41E and is folded to lower the terminal at the tip of the signal line 403E on the FPC side.

The signal line terminal 321E1 of the FPC 32E has a number of poles corresponding to the number of poles of the cable 6 (the number of coaxial cables 60), and is provided with spare terminals as needed, and is arranged side by side in two rows and staggered. do. The signal line 403E is a number of conducting wires corresponding to the number of coaxial cables 60, and is arranged in two rows in a staggered manner corresponding to the signal line terminal 321E1. Since the GND line 404E is made of a conductor and is electrically connected to the GND section 401E, it is grounded.

The FPC 32E to which the GND bending portion 320E1 is bent and adhered is inserted into the FPC insertion slot of the FPC connector portion 41E, and the flip 402E is folded so that the signal line terminal 321E1 and the signal line 403E are pressure-welded and one-to-one. They face each other and are electrically connected. At the same time, the GND terminal 322E1 and the GND line 404E are pressure-welded and are electrically connected to each other on a one-to-one basis. The terminals on the FPC side of the signal line terminals 321E1 and the signal line 403E may be arranged in a row. The terminals on the coaxial cable side of the signal line 403E are arranged in a row, for example.

The coaxial connector portion 50E includes a base portion 500E, a shield portion, a GND portion 501E as a second shield portion, a connection portion 502E, and a signal line 503E as a first signal line and a third signal line. Be prepared. The base portion 500E, the GND portion 501E, the connection portion 502E, and the signal line 503E have the same configurations as the base portion 500A, the GND portion 501A, the connection portion 502A, and the signal line 503A of the coaxial connector portion 50A of the first embodiment, respectively. Has.

Then, the signal lines of the coaxial cable 60 are connected to the signal line terminals 321E1 and GND terminals 322E1 of the GND bending portions 320E1, 320E2, 320E3, 320E4 of the FPC32E of the acoustic sensor portion 30A via the connector portion 40E and the coaxial connector portion 50E, respectively. 61 and the coaxial shielded wire 62 are connected. The acoustic sensor portion 30A, the connector portion 40E, and the coaxial connector portion 50E having the FPC 32E assembled in this way are housed in the housing of the ultrasonic probe main body 3A.

As described above, according to the present embodiment, the FPC 32E has a signal line terminal 321E1 on one surface (upper surface) and a GND terminal 322E1 on the other surface (lower surface) behind the upper surface. The connector CE has signal lines 403E and 503E electrically connected to the signal line 61 of the cable 6 and electrically connected to the signal line terminal 321E1 of the FPC 32E on the upper surface side, and has a GND portion 401E on the lower surface side. , 501E has a GND wire 404E that is electrically connected to the coaxial shielded wire 62 of the cable 6 and is electrically connected to the GND terminal 322E1 of the FPC 32E. Therefore, the GND layer 322E of the FPC32E on the acoustic sensor unit 30A side can be reliably grounded, additional measures such as a separate GND plate can be eliminated, the structure of the ultrasonic probe 2A can be simplified, and the ultrasonic probe 2A can be simplified. The tentacle 2A can be manufactured more easily.

Further, in the FPC32E, the GND terminal 322E1 of the GND bending portions 320E1, 320E2, 320C, 320D provided on the upper surface is bent, and the GND terminal 322E1 is formed on the lower surface. Therefore, FPC32E can be easily manufactured.

(Fifth Embodiment)
A fifth embodiment according to the present invention will be described with reference to FIGS. 18 (a) to 18 (c). FIG. 18A is a top view of the FPC32F. FIG. 18B is a cross-sectional view of the FPC 32F. FIG. 18C is a bottom view of the FPC 32F.

The device configuration of the present embodiment is such that the ultrasonic diagnostic apparatus 100 of the first embodiment is provided with an FPC 32F instead of the FPC 32A of the acoustic sensor unit 30A of the ultrasonic probe 2A. Therefore, the same components as those of the ultrasonic diagnostic apparatus 100 of the first embodiment are designated by the same reference numerals, and mainly different components will be described.

As shown in FIGS. 18A, 18B, and 18C, the FPC32F has a base portion 3262F, a signal line layer 321F, a base portion 3261F, a GND layer 322F, and a coverlay 323F from the lower surface to the upper surface. However, they are stacked in order. The base portion 3262F, the signal line layer 321F, the base portion 3261F, the GND layer 322F, and the coverlay 323F are the base portion 3262A, the signal line layer 321A, the base portion 3261A, and the GND layer 322A of the FPC 32A of the first embodiment, respectively. It has the same configuration as the coverlay 323A, but the shapes seen from the top and bottom are different.

As shown in FIG. 18A, the FPC 32F has an oscillator bonding portion 325, a coverlay 323F, and an exposed portion (GND terminal) of a plurality of GND layers 322F when viewed from the upper surface. The FPC 32F has four GND terminals 322F1 of the GND layer 322F at the tip in a direction perpendicular to the directional direction of the vibrator bonding portion 325 (piezoelectric vibrator 311) on the upper surface.

As shown in FIG. 18C, the FPC 32F has a base portion 3262F and a signal line terminal 321F1 when viewed from the lower surface. The signal line terminal 321F1 is the same as the signal line terminal 321A1 of the FPC 32A of the first embodiment.

For the connection between the FPC32F and the cable 6, either the connector portion 40E and the coaxial connector portion 50E of the fourth embodiment are used upside down, or the internal GND line is pressed against the GND terminal 322F1 on the surface side, and the internal signal line is used. Uses a connector portion and a coaxial connector portion that are in pressure contact with the signal line terminal 321F1 on the back surface side. The acoustic sensor unit, the connector unit 40E, and the coaxial connector unit 50E having the FPC 32F assembled in this way are housed in the housing of the ultrasonic probe main body 3A.

As described above, according to the present embodiment, the FPC32F can have a GND terminal 322F1 on the surface (upper surface) on the piezoelectric vibrator side and a signal line terminal 321F1 on the lower surface.

(Second modification)
A second modification as a modification of the fifth embodiment according to the present invention will be described with reference to FIGS. 19 (a) to 19 (c). FIG. 19A is a top view of the FPC32G. FIG. 19B is a cross-sectional view of the FPC 32G. FIG. 19 (c) is a bottom view of the FPC 32G.

The device configuration of this modification is such that the ultrasonic diagnostic apparatus 100 of the first embodiment is provided with an FPC 32G instead of the FPC 32A of the acoustic sensor unit 30A of the ultrasonic probe 2A. Therefore, the same components as those of the ultrasonic diagnostic apparatus 100 of the first embodiment are designated by the same reference numerals, and mainly different components will be described.

As shown in FIGS. 19 (a), 19 (b), and 19 (c), the FPC 32G has a coverlay 3232G, a signal line layer 3212G, a base portion 3262G, a signal line layer 3211G, and a base portion from the lower surface to the upper surface. 3261G, the GND layer 322G, and the coverlay 3231G are laminated in this order. The coverlay 3232G, the signal line layer 3212G, the base portion 3262G, the signal line layer 3211G, the base portion 3261G, the GND layer 322G, and the coverlay 3231G are the base portion 3262F and the signal line layer 321F of the FPC 32F of the fifth embodiment, respectively. , Base portion 3262F, signal line layer 321F, base portion 3261F, GND layer 322F, and coverlay 323F.

Further, the signal line layer 3211G and the signal line layer 3212G are electrically connected via the through hole t2.

As shown in FIG. 19A, the FPC 32G has an oscillator bonding portion 325, a coverlay 3231G, and an exposed portion (GND terminal) of a plurality of GND layers 322G when viewed from the upper surface. The FPC 32G has four GND terminals 322G1 of the GND layer 322F at the tip in a direction perpendicular to the directional direction of the vibrator bonding portion 325 (piezoelectric vibrator 311) on the upper surface.

As shown in FIG. 19C, the FPC 32G has a coverlay 3232G and a signal line terminal 321G1 when viewed from the lower surface. The signal line terminal 321G1 is the same as the signal line terminal 321F1 of the FPC 32F of the fifth embodiment.

For the connection between the FPC32G and the cable 6, either the connector portion 40E and the coaxial connector portion 50E of the fourth embodiment are used upside down, or the internal GND line is pressed against the GND terminal 322G1 on the surface side, and the internal signal line is used. Uses a connector portion and a coaxial connector portion that are pressed against the signal line terminal 321G1 on the back surface side. The acoustic sensor unit, the connector unit 40E, and the coaxial connector unit 50E having the FPC 32F assembled in this way are housed in the housing of the ultrasonic probe main body 3A.

As described above, according to this modification, the FPC 32G can have a configuration in which the GND terminal 322G1 is provided on the surface (upper surface) on the piezoelectric vibrator side and the signal line terminal 321G1 is provided on the lower surface.

The description in the above-described embodiment and modification is an example of a suitable ultrasonic probe and ultrasonic diagnostic apparatus according to the present invention, and is not limited thereto. For example, at least two of the above-described embodiments and modifications may be appropriately combined.

Further, the detailed configuration and detailed operation of each part constituting the ultrasonic diagnostic apparatus 100 in the above embodiments and modifications can be appropriately changed without departing from the spirit of the present invention.

100 Ultrasonic diagnostic device 1 Ultrasonic diagnostic device main unit 11 Operation input unit 12 Transmission unit 13 Reception unit 14 Image generation unit 15 Image processing unit 15a Image memory unit 16 Display control unit 17 Display unit 18 Control unit 2A Ultrasonic probe 3A Ultrasonic probe body 30A, 30D Acoustic sensor unit 311 piezoelectric vibrator 312a, 312b Acoustic matching layer 313 Acoustic lens 314 Back load material g1 Dividing groove 32A, 32C, 32D, 32E, 32F, 32G FPC
321A, 321C, 321D, 321E, 321F, 3211G, 3212G Signal line layer 321A1,321C1,321D1,321E1,321F1,321G1 Signal line terminal 322A, 322C, 3221D, 3222D, 322E, 322F, 322G GND , 322D1,322E1,322F1,322G1 GND terminal o1 Opening t1, t2 Through hole 323A, 323C, 323D, 323E, 323F, 3231G, 3232G Coverlay 324 Reinforcing material 325 Coaxial adhesive part 3261A, 3262A, 3261D, 3262D, 3261E , 3262E, 3261F, 3262F, 3261G, 3262G Base part 327 Adhesive layer 320C1, 320C2, 320C3, 320C4 GND coating part 33 GND film 331 Film body 332 GND layer CA, CB, CD, CE connector 40A, 40D, 40E Connector part 41A , 41D, 41E FPC connector part 411A FPC insertion port 42A, 42D, 42E Coaxial connector part 421A Coaxial connector part insertion port 400A, 400D, 400E Base part 401A, 401D, 401E GND part 402A, 504B, 402D, 402E Flip 403A, 403D , 403E Signal line 404D, 404E GND line 50A, 50B, 50D, 50E Coaxial connector part 500A, 500B, 500D, 500E Base part 501A, 501B, 501D, 501E GND part 502A, 502B, 502D, 502E Connection part 503A, 503B, 503D, 503E Signal line s1, s2, s3, s4, s5 Solder connection 301A GND plate 6 Cable 60 Coaxial cable 61 Signal line 62 Coaxial shielded wire 63 Coating layer 7 Detector connector

Claims (17)

An acoustic sensor unit including a plurality of piezoelectric vibrators for transmitting and receiving ultrasonic waves and a flexible substrate having signal line terminals of signal lines electrically connected to the plurality of piezoelectric vibrators.
A cable connected to an ultrasonic diagnostic apparatus main body that generates ultrasonic image data based on a received signal obtained by transmitting a drive signal to the acoustic sensor unit and having a signal line.
A connector for electrically connecting the signal line terminal of the flexible board and the signal line of the cable is provided.
The connector is an ultrasonic probe having a grounded shield portion that covers a connection portion between a signal line terminal of the flexible substrate and a signal line of the cable. The ultrasonic probe according to claim 1, wherein the connector electrically connects a signal line terminal of the flexible board and a signal line of the cable without using a wiring board. The connector has a first signal line for connecting the signal line terminal of the flexible board and the signal line of the cable.
The ultrasonic probe according to claim 1 or 2, wherein the contact on the flexible substrate side and the contact on the cable side of the signal line of the connector have the same number of poles and the same pitch. The ultrasonic probe according to claim 3, wherein the number of poles of the contact on the flexible substrate side of the first signal line of the connector and the number of poles of the contact on the cable side are multiples of 8. The cable has a plurality of coaxial cables having a signal line and a shielded line.
The shield portion has a first shield portion and a second shield portion.
The connector is
The signal line terminal of the flexible substrate is inserted, and the first shield portion and the first connector portion having the second signal line are
The signal line and the shielded wire of the coaxial cable are inserted, and the second shielded portion and the second connector portion having the third signal line are provided.
The second connector portion electrically connects the signal line of the inserted coaxial cable and the third signal line, and connects the shielded wire of the inserted coaxial cable and the second shielded portion. Electrically connected
In the first connector portion, the second connector portion is inserted, and the signal line terminal of the inserted flexible substrate and the third signal line of the inserted second connector portion are inserted into the second signal line. The ultrasonic wave according to claim 1 or 2, which is electrically connected by the signal line of the above and electrically connects the second shield portion of the inserted second connector portion and the first shield portion. Detector. The cable has a plurality of coaxial cables having a signal line and a shielded line.
The connector is
Having a fourth signal line, the signal line terminal of the flexible board and the coaxial cable are inserted, and the signal line terminal of the inserted flexible board and the signal line of the inserted coaxial cable are inserted into the fourth signal line. The ultrasonic probe according to claim 1 or 2, further comprising a third connector portion that is electrically connected by the signal line of the above and electrically connects the shielded wire of the inserted coaxial cable and the shielded portion. .. The flexible substrate has a conductive GND layer and has a conductive substrate.
The ultrasonic probe according to any one of claims 1 to 6, wherein the GND layer and the shield portion are electrically connected to each other, and a GND plate having conductivity is provided. The ultrasonic probe according to claim 7, wherein the GND plate covers the connector. The ultrasonic probe according to claim 7 or 8, wherein the flexible substrate has a GND terminal of the GND layer to which the GND plate is connected. The flexible substrate has a GND layer having conductivity, and includes a GND coating portion having a part of the GND layer.
The ultrasonic probe according to any one of claims 1 to 6, wherein the GND covering portion covers the connector and electrically connects the GND layer and the shield portion. The flexible substrate has a conductive and includes a GND layer having a GND terminal.
The ultrasonic probe according to any one of claims 1 to 6, wherein the connector has a GND wire electrically connected to the shield portion and electrically connected to the GND terminal on the flexible substrate side. Tactile. The ultrasonic probe according to claim 11, wherein the flexible substrate has the GND terminal and the signal line terminal arranged side by side. The flexible substrate has the signal line terminal on one surface and the GND terminal on the other surface behind the one surface.
The connector has a signal line electrically connected to the signal line of the cable and electrically connected to the signal line terminal of the flexible substrate on the one surface side, and has the signal line on the other surface side. The ultrasonic probe according to claim 11, which has a GND line. The ultrasonic probe according to claim 13, wherein in the flexible substrate, the GND terminal provided on one surface is bent and the GND terminal is formed on the other surface. The ultrasonic probe according to claim 13 or 14, wherein the one surface is a surface on the piezoelectric vibrator side or a surface on the back surface of the surface on the piezoelectric vibrator side. The ultrasonic probe according to any one of claims 7 to 15, further comprising a GND film formed on the upper surface of the piezoelectric vibrator and electrically connected to the GND layer. The ultrasonic probe according to any one of claims 1 to 16.
An ultrasonic diagnostic apparatus including the ultrasonic diagnostic apparatus main body.

Images