This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2014-23741, filed Feb. 10, 2014, the entire contents of which are incorporated herein by reference.
The present embodiments relate to an ultrasound probe for transmitting and receiving ultrasound waves toward a body of a test subject.
An ultrasound scanner plays an important role in medical-diagnosis, because of benefits of an ultrasound scanner such as being smaller than other medical scanners such as an X-ray scanner, an X-ray computed tomography scanner, and a magnetic resonance image scanner. An operator of the ultrasound scanner can also get real-time images from the test-subject such as a beating heart and a moving infant inside a mother's belly, by a simple operation of touching the test subject with the ultrasound probe. Due to the compactness of the ultrasound scanner, it is popular to use at a patient's home. Moreover, the ultrasound scanner can generate medical images without X-ray radiations, and thus can be applied to an obstetric test.
An ultrasound scanner includes an ultrasound probe which transmits and receives ultrasound waves toward the test-subject. When the ultrasound probe transmits the ultrasound waves, the ultrasound waves reflect at a border between two tissues that have different acoustic impedance parameters. The ultrasound probe receives the reflected ultrasound waves from the test-subject, and generates received signals. To transmit and receive the ultrasound waves, electric vibrators are implemented in the ultrasound probe, and the electric vibrators are arranged in a scan-direction. The ultrasound probe also includes a matching layer and an acoustic lens, on a side of the test subject of the electric vibrators. The matching layer averages differences of the acoustic impedance between the electric vibrators and the tissue of the test-subject. The acoustic lens focuses the ultrasound waves from the electric vibrators.
The ultrasound probe further includes a circuit-board and a backing layer, on the other side of the test subject of the electric vibrators. The circuit-board transmits electric signals to the electric vibrators for transmitting the ultrasound waves, and receives electric signals from the electric vibrators. The backing layer absorbs the ultrasound waves transmitted by the electric vibrators in an opposite direction of the test-subject. According to the general ultrasound probe, the electric vibrators and the circuit-board are bonded with adhesive, and electrically connected. The present inventors have recognized in the general ultrasound probe strength of bonding between the electric vibrators and the circuit-board may not be enough.
The present embodiments have been made in consideration of the above situation, and provide an ultrasound probe that can bond the electric vibrator with the circuit-board more strongly.
An ultrasound transducer includes an electric vibrator including a vibrator contact layer, to transmit and receive ultrasound wave, and a circuit-board including a circuit contact layer connected to the vibrator contact layer, to transmit and receive ultrasound signals via the vibrator contact layer. A maximum width which width is an extent of a shorter side of the circuit contact layer, is same to a width of the electric vibrator. The circuit contact layer includes a bonding area that extends to a surface of a circuit-board and a surface of the vibrator contact layer. An adhesive is provided in the bonding area to adhere the electric vibrator and the circuit-board to each other.
A first embodiment of the present invention will be described below with reference to
The body 200 sends command-signals to the ultrasound probe 100, for transmitting ultrasound waves to a test-subject from the ultrasound probe 100. The body 200 receives image-signals from the ultrasound probe 100, and generates ultrasound images based on the image-signals. The body 200 includes a display-monitor and an input device. The body 200 displays information and the ultrasound images based on inputs from an operator.
The input device can include various devices such as a track-ball, a dip-switch, input buttons, a mouse, and a keyboard. The operator operates the input device, to send scan-parameters to the body 200.
The display-monitor shows a GUI (Graphical User Interface) for setting the scan-parameters. The display-monitor displays the ultrasound images generated by the body 200.
As shown in
The connector 20 connects the contact-terminal 10 and the cable 40. The connector 20 includes the joint mechanism 30 to fix the connector 20 to the body 200. When the connector 20 is fixed to the body 200 by the joint mechanism 30, the contact-terminal 10 connects with the body 200 electrically. The joint mechanism 30 includes a rotating pad and a handle. The rotating pad rotates when the handle is operated. When the rotating pad is inserted to the body 200, the rotating pad can switch a lock-condition in which the connector 20 is fixed to the body 200, and an unlock-condition in which the connector 20 can be removed from the body 200, by its rotation.
The cable 40 connects the connector 20 and the transducer-head 50 electrically. The cable 40 includes a plurality of signal-lines, and the signal-lines connect the transducer-head 50 and the body 200 via the contact-terminal 10. A number of signal-lines corresponds to a number of electric vibrators inside the transducer-head 50.
The transducer-head 50 transmits ultrasound waves based on transmitting signals from the body 200. The transducer-head 50 generates received signals based on the received ultrasound waves from the test-subject, and sends the received signals to the body 200.
As shown in
The acoustic lens 1 focus the ultrasound waves from the electric vibrator 3. The matching layers 2 average differences of acoustic impedance between the electric vibrator 3 and the acoustic lens 1. The circuit-board 4 transmits transmitting signals to the electric vibrator 3, and receives received signals from the electric vibrator 3. The circuit-board 4 connects to the signal-lines of the cable 40.
The electric vibrator 3 vibrates and transmits the ultrasound waves based on the transmitting signals from the body 200 via the circuit-board 4. The electric vibrator 3 vibrates when it receives the ultrasound waves, and generates the received signals. Then the electric vibrator 3 sends the received signals to the body 200 via the circuit-board 4. The electric vibrator 3 includes a plurality of vibrator-cells (not illustrated), each of the vibrator-cells transmitting and receiving the ultrasound signals. The backing layer 5 absorbs the ultrasound waves transmitted by the electric vibrators 3 in an opposite direction of the test-subject. A middle layer (not illustrated) could also be implemented between the electric vibrators 3 and the circuit-board 4, that middle layer absorbing scattered ultrasound from the electric vibrator 3.
When the electric vibrator 3 transmits the ultrasound waves to the test-subject, the ultrasound waves reflect at a border between two tissues that have different acoustic impedance parameters. The reflected ultrasound waves are received by the electric vibrator 3, and the electric vibrator 3 converts the received ultrasound waves into the received signals. An amplitude of the reflected ultrasound waves are related to differences of the acoustic impedance parameters. When the ultrasound waves are reflected at a moving target such as blood vessels and beating heart-tissues, a frequency of the reflected ultrasound waves is shifted by the Doppler effect.
The embodiments can be applied to a 1-D ultrasound probe that has the vibrator cells arranged in one direction, and can be applied to a mechanical 1-D ultrasound probe that has the vibrator cells arranged in one direction, and the vibrator cells are swung by an attached motor. Also, the embodiments can be applied to a 2-D ultrasound probe that has the vibrator cells arranged in two directions.
As described above, the electric vibrator 3 transmits and receives electric signals to/from the circuit-board 4. In the first embodiment, the strength of bonding of the electric vibrator 3 with the circuit-board 4 is improved.
As shown in
The circuit-board 4 includes a circuit contact layer 401 and a base layer 400. The base layer 400 supports a structure of the circuit contact layer 401, and can be made of a polyimide resin. The circuit contact layer 401 can be made of copper or gold.
According to the ultrasound probe shown in
As shown in
As shown in
After placing the electric vibrator 3 on the circuit contact layer 401, a die cutting procedure is applied to the electric vibrator 3. The bulk electric vibrator 3 is divided into vibrator cells. In this case, the adhesive flows into an area between the vibrator contact layer 301 and the base layer 400, and the vibrator contact layer 301 and the base layer 400 are bonded in this area.
As described above, in the background art, when the electric vibrator 3 is fixed to the circuit-board 4, the vibrator contact layer 301 and the circuit contact layer 401 are bonded with an adhesive. Both of the layers 301, 401 can be made of gold mainly, and gold has an advantage that is hard to have a chemical reaction and hard to change its character. But gold does not have strong bonding with an epoxy adhesive. If the strength of bonding between the electric vibrator 3 and the circuit-board 4 is not strong, the electric vibrator 3 may peel off from the circuit-board 4 during the die cutting procedure. Also, a characteristic of the electric vibrator 3 may be degraded when the electric vibrator 3 transmits and receives the ultrasound waves by a weak bonding.
According to the background ultrasound probe in
Also, to realize fine ultrasound images, the vibrator cells should have a small width to thereby have a great density of the vibrator cells. For example, when a width of the vibrator cells is shortened, as a result a width of the circuit contact layer 401 may be 50 micrometers. Thereby a width of the circuit contact layer 401 is shortened, and the circuit contact layer 401 may lose an electric connection to the vibrator contact layer 301. If an amount of the adhesive is increased on the electric vibrator 3 and the circuit-board 4, a layer of the increased adhesive may cause degraded characteristics of the transmitted/received ultrasound waves.
As described above, according to the background ultrasound probe, it is hard to stably keep the electric vibrator 3 on the circuit-board 4.
According to the present embodiments, the ultrasound probe 100 has an area where the vibrator contact layer 301 is bonded with a material other than the gold, to adhere the electric vibrator 3 tightly. According to the first embodiment, adhesive is provided at a first bonding area that is between the surface of the vibrator contact layer 301 and the surface of the circuit contact layer 401. And the circuit contact layer 401 has a second bonding area that reaches a surface of the vibrator contact layer 301 and a surface of the base layer 400. For example, the circuit contact layer 401 has a through-hole that reaches a surface of the vibrator contact layer 301 and a surface of the base layer 400, and the through-hole acts as a second bonding area. In this embodiment, the second bonding area added to the first bonding area where the vibrator contact layer 301 is bonded with a material other than the gold is referred to as the second bonding area. For example, the second bonding area might reach a surface of the vibrator contact layer 301 and a surface of the base layer 400, and might reach a surface of the vibrator contact layer 301 and a surface of the backing layer 5.
As shown in
As shown in
Also, in the structure of the first embodiment of
The shape of the through-hole 402 can be varied. The shape of through-hole 402 can for example have a polygonal shape, a rectangle shape, a circle shape, and an ellipsoidal shape. Also, the patterned shape of the circuit contact layer 401 can have a plurality of the through-holes 402. For example, two or three through-holes 401 can be implemented in one patterned shape.
The shape of the second bonding area also can be varied. Instead of implementing the through-hole 402 as the second bonding area, a cleavage implemented at an edge of the circuit contact layer 401 can act as the second bonding area.
As shown in
Also, as shown in
As described above, regarding to the first embodiment, the circuit contact layer 401 includes the second bonding area that reaches the surface of the base layer 400 and the surface of the vibrator contact layer 301. Thus, the adhesive can be provided into not only the first bonding are but also the second bonding area, and can more surely adhere the circuit-board 4 and the electric vibrator 3.
As described above, the second bonding area can be implemented as a through-hole that reaches surface of the base layer 400 and the surface of the vibrator contact layer 301. Thus, the adhesive can flow into the second bonding area, and can more surely adhere the circuit-board 4 and the electric vibrator 3.
As described above, the second bonding area can also be implemented as cleavages that reach the surface of the base layer 400 and the surface of the vibrator contact layer 301. Thus the adhesive can be provided into the second bonding area, and can more surely adhere the circuit-board 4 and the electric vibrator 3. That structure of the cleavages can be varied. For example, the cleavages can be implemented at an upper-edge and bottom-edge of the circuit contact layer 401 (the cleavages can be implemented at opposite short sides of the circuit contact layer 401). The cleavages could also have a rectangular shape or other polygonal shape.
As described in the first embodiment, the second bonding area is implemented at the circuit contact layer 401. In a second embodiment, the second bonding area is implemented at the circuit contact layer 401 and also the base layer 400. In this case, the through-hole or the cleavages that reaches surfaces of the backing layer 5 and the vibrator contact layer 301 act as the second bonding area.
As shown in
As shown in
As shown in
As described above, in the second embodiment, the circuit contact layer 401 and the base layer 400 include the second bonding area that reaches the surface of the backing layer 5 and the surface of the vibrator contact layer 301. Thus, the adhesive can be provided into the second bonding area, and can more surely adhere the electric vibrator 3, the circuit-board 4, and the backing layer 5.
Also, when the second bonding area at the circuit contact layer 401 and the base layer 400 is placed at the same position, the adhesive can adhere the electric vibrator 3, the circuit-board 4, and the backing layer 5 at one time. Thereby the ultrasound probe 100 can be built-up much easier.
In a third embodiment as shown in
As shown in
The structure shown in
As described above, in the third embodiment, the circuit contact layer 401, the middle layer 6, and the base layer 400 include the second bonding area that reaches the surface of the backing layer 5 and the surface of the vibrator contact layer 301. Thus, the adhesive can be provided into the further bonding area, and can more surely adhere the electric vibrator 3, the circuit-board 4, the backing layer 5, and the middle layer 6.
Also, when the second bonding area at the circuit contact layer 401, the base layer 400, and the middle layer 6 is placed at the same position, the adhesive can adhere the electric vibrator 3, the circuit-board 4, the backing layer 5, and the middle layer 6 at one time. Thereby the ultrasound probe 100 can be built-up much easier.
As described in the first to third embodiments above, further the second bonding area is implemented to at least the circuit contact layer 401. The position of the second bonding area, however, can be varied.
For example, the second bonding area can be placed at the base layer 400, not at the contact layer 401. In this case, the through-hole acts as the second bonding area that reaches the surface of the backing layer 5 and the surface of the electric vibrator 3.
As shown in
After injecting the adhesive and placing the electric vibrator 3 on the circuit-board 4, the die cutting procedure is applied to the electric vibrator 3, and thereby the bulk electric vibrator 3 is divided into the vibrator cells. Strips made by the die cutting procedure reach the bottom surface of the electric vibrator 3. That is, the adhesive that flows around the circuit board 4 is not removed by the die cutting procedure, and can keep a secure bonding.
The structure of the first and second bonding area in the fourth embodiment can be applied to a laminated circuit contact layer 401. In this case, the through-hole 403 is implemented not only in the base layer 400, but also in the circuit contact layer 401. After implementing the through-hole 403, injecting the adhesive, and placing the electric vibrator 3 on the circuit-board 4, the die cutting procedure is applied to the electric vibrator 3. Strips made by the die cutting procedure reach the upper surface of the base layer 400. If the through-hole 403 is too big, the through-hole 403 can cause a loss of electric connection of the circuit contact layer 401. But a shape of the through-hole 403 and a number of the through-hole 403 can be varied, for example the through-hole 403 can have a circular shape, a rectangular shape, a polygonal shape, an elliptical shape, etc.
As described in the first to fourth embodiments, one separated vibrator cell has one patterned circuit contact layer 401. But the number of the patterned circuit contact layers 401 per one vibrator cell can be increased. A plurality of the patterned circuit contact layers 401 that are separated electrically can be attached to one separated vibrator cell.
As described in the fifth embodiment, three circuit contact layers 401 connect to one vibrator cell. In this case, any area of transmitting and receiving can be varied by controlling an electric connection with the three circuit contact layers 401. For example, when the transmitting signals from the body 200 are provided to all three circuit contact layers 401, the vibrator cell transmits the ultrasound wave from the whole surface of the vibrator cell. On the other hand, when the transmitting signals from the body 200 are provided to the central circuit contact layer 401 only, the vibrator cell transmits the ultrasound wave from the center surface of the vibrator cell. In the same manner to transmit, when the body 200 receives the receiving signals from all of three circuit contact layer 401, the vibrator cell can receive the ultrasound waves from the whole surface of the vibrator cell. On the other hand, when the body 200 receives the ultrasound wave from the central circuit contact layer 401 only, the vibrator cell can receive the ultrasound waves from central surface of the vibrator cell only.
The above embodiments can be applied to a 1-D ultrasound probe. The above embodiments can be also applied to a mechanical 1-D ultrasound probe and a 2-D ultrasound probe.
As described above, with the described embodiments, the ultrasound probe 100 can stably maintain the electric vibrator 3 and the circuit-board 4 by using second the bonding area.
The present invention is not limited to the above embodiments, and constituent elements can be variously modified and embodied at the execution stage within the spirit and scope of the invention. In addition, various inventions can be formed by proper combinations of a plurality of constituent elements disclosed in the above embodiments. For example, several constituent elements may be omitted from all the constituent elements disclosed in the above embodiments. Furthermore, constituent elements in the different embodiments may be properly combined.
Number | Date | Country | Kind |
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2014-023741 | Feb 2014 | JP | national |
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