JP2005110171A - Ultrasonic probe - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make ultrasonic directivity into a desired property in a direction orthogonal with the array direction of piezoelectric devices. <P>SOLUTION: In a configuration wherein piezoelectric devices 1 are arrayed in a direction Y and divided in a direction X orthogonal with the array direction Y, an ultrasonic probe is configured so that the width W of the array direction Y of the piezoelectric devices is narrowest at the central part of the direction X orthogonal with the array direction Y and the width W becomes wider toward both ends, so that the ultrasonic directivity in the direction X demonstrates the desired property. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an ultrasonic probe used in an ultrasonic diagnostic apparatus or the like.

In the conventional ultrasonic probe, as shown in FIG. 11, a plurality of piezoelectric elements 51 are arranged in the Y direction in order to transmit and receive ultrasonic waves. A back load material 52 that attenuates the ultrasonic waves and mechanically holds the piezoelectric element 51 is provided. The thickness of the piezoelectric element 51 in the direction X perpendicular to the arrangement direction Y is thin in the vicinity of the center, and has a non-uniform curved shape so as to increase toward both ends. Thus, by making the thickness of the piezoelectric element 51 non-uniform in the X direction, the focal depth of the ultrasonic beam is lengthened, and a wideband frequency characteristic is obtained to improve the resolution (for example, the following) Patent Document 1).
JP-A-7-107595 (FIGS. 7 and 18)

  However, the configuration of the conventional ultrasonic probe has the following problems. In the vicinity of the center of the piezoelectric element 51 in the X direction, the ultrasonic wave having a high frequency component is transmitted / received because the thickness is thin, and the ultrasonic wave having a low frequency component is transmitted / received because the thickness increases toward both ends. On the other hand, the width in the arrangement direction Y of the piezoelectric elements 51 is the same in the X direction.

  For this reason, in the configuration in which the thickness of the central portion in the X direction of the piezoelectric element 51 is thin and the frequency is high, and the frequency becomes thicker toward the both ends, the ultrasonic directivity of the piezoelectric element 51 is The higher center is higher and the lower ends of the lower frequency are lower. In the arrangement direction Y of the piezoelectric elements 51, the plurality of piezoelectric elements 51 are electronically delayed to control the phase and narrow down or deflect the ultrasonic beam. It is desirable to obtain an ultrasonic image.

  However, in the conventional configuration, the central portion in the X direction of the piezoelectric element 51 has high directivity, so that the range in which phase control can be performed becomes narrow. As a result, it is difficult to obtain a high-resolution ultrasonic image. Further, in order to reduce the directivity in the vicinity of the central portion in the X direction having a high frequency (widening the predetermined sensitivity angle range), the arrangement of the piezoelectric elements 51 can be narrowed in accordance with the high frequency in the central portion. In this configuration, there is a problem that the pillars of the piezoelectric element 51 having both thick end portions are high, making it extremely difficult to manufacture.

  The present invention has been made to solve the above-described conventional problems, and can achieve a desired ultrasonic directivity with respect to a direction orthogonal to the arrangement direction of the piezoelectric elements, thereby reducing the ultrasonic directivity. The phase can be freely controlled using an array of many piezoelectric elements, the ultrasonic beam can be narrowed down, the ultrasonic beam can be deflected, and high-resolution ultrasonic waves An object is to provide an ultrasonic probe capable of obtaining an image.

In order to achieve the above object, the ultrasonic probe of the present invention is an ultrasonic probe in which a plurality of piezoelectric elements that transmit and receive ultrasonic waves are arranged in one direction,
Directivity setting means for setting ultrasonic directivity in a direction orthogonal to the arrangement direction of the piezoelectric elements;
Each of the piezoelectric elements is divided into a plurality of parts and divided grooves for arranging them in a line in the orthogonal direction.
With this configuration, the ultrasonic directivity in the direction orthogonal to the arrangement direction of the piezoelectric elements can be set to a desired characteristic, so that the phase control can be freely performed using many arrangements of the piezoelectric elements. Since the ultrasonic beam can be deflected and the ultrasonic beam can be deflected, an ultrasonic probe providing an ultrasonic image with high resolution can be obtained.

Furthermore, the ultrasonic probe of the present invention is configured such that the directivity setting means has a width in the arrangement direction of the piezoelectric elements that is the narrowest in the central portion in the orthogonal direction and becomes wider toward both ends. It is characterized by that.
With this configuration, the ultrasonic directivity in the direction orthogonal to the direction in which the piezoelectric elements are arranged can be reduced (the predetermined sensitivity angle range is wide), so that the phase can be freely controlled by using many piezoelectric elements. Thus, since the ultrasonic beam can be narrowed down and the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

Furthermore, the ultrasonic probe of the present invention is characterized in that the width of the piezoelectric element is continuously increased from the central part in the orthogonal direction to both end parts.
With this configuration, since the ultrasonic directivity in the direction orthogonal to the direction of arrangement of the piezoelectric elements can be lowered, the phase can be freely controlled using a large number of arrangements of the piezoelectric elements, and the ultrasonic beam is narrowed down. In addition, since the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

Furthermore, the ultrasonic probe of the present invention is characterized in that the width of the piezoelectric element is gradually increased from the central part in the orthogonal direction to both end parts.
With this configuration, since the ultrasonic directivity in the direction orthogonal to the direction of arrangement of the piezoelectric elements can be lowered, the phase can be freely controlled using a large number of arrangements of the piezoelectric elements, and the ultrasonic beam is narrowed down. In addition, since the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

Furthermore, the ultrasonic probe of the present invention has one or more acoustic matching layers formed on the piezoelectric element,
The directivity setting means is configured such that the number of divisions in the arrangement direction is the largest in the central portion in the orthogonal direction of the acoustic matching layer, and the number of divisions in the arrangement direction is reduced toward both ends. Features.
With this configuration, since the ultrasonic directivity in the direction orthogonal to the direction of arrangement of the piezoelectric elements can be lowered, the phase can be freely controlled using a large number of arrangements of the piezoelectric elements, and the ultrasonic beam is narrowed down. In addition, since the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

Furthermore, in the ultrasonic probe of the present invention, the thickness T of the piezoelectric element varies depending on the position in the orthogonal direction,
The directivity setting means is configured such that a ratio W / T of the width W and thickness T of the piezoelectric element becomes a value in a predetermined range from the center in the orthogonal direction toward both ends. To do.
With this configuration, since the ultrasonic directivity in the direction orthogonal to the direction of arrangement of the piezoelectric elements can be lowered, the phase can be freely controlled using a large number of arrangements of the piezoelectric elements, and the ultrasonic beam is narrowed down. In addition, since the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

Further, in the ultrasonic probe of the present invention, the ratio W / T of the width W to the thickness T is set to a value in a predetermined range continuously or stepwise as it goes from the central portion in the orthogonal direction to both ends. It is configured.
With this configuration, it is possible to achieve a wideband frequency characteristic and high sensitivity, and furthermore, the directivity of ultrasonic waves can be lowered, so that phase control can be freely performed using a large number of piezoelectric element arrays. Since the ultrasonic beam can be narrowed down and the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

Furthermore, the ultrasonic probe of the present invention is characterized in that the plurality of piezoelectric elements have the same thickness in the orthogonal direction.
With this configuration, even when a plurality of piezoelectric elements are arranged in one direction and divided in a direction orthogonal to the arrangement direction, and the thickness is formed in the orthogonal direction, the arrangement direction of the piezoelectric elements Since the ultrasonic directivity in the direction perpendicular to the direction can be lowered, it is possible to freely control the phase using an array of many piezoelectric elements, the ultrasonic beam can be narrowed down, and the ultrasonic beam Therefore, it is possible to obtain an ultrasonic probe that provides an ultrasonic image with high resolution.

  Furthermore, the ultrasonic probe of the present invention is configured such that the directivity setting means has the lowest directivity of the ultrasonic probe at the central portion in the orthogonal direction and becomes higher toward both ends. It is characterized by that.

  With this configuration, since the ultrasonic directivity in the direction orthogonal to the direction of arrangement of the piezoelectric elements can be lowered, the phase can be freely controlled using a large number of arrangements of the piezoelectric elements, and the ultrasonic beam is narrowed down. In addition, since the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

  Furthermore, the ultrasonic probe of the present invention is characterized in that the transmission / reception frequency of the piezoelectric element is highest at the center in the orthogonal direction and lowers toward both ends.

  With this configuration, the ultrasonic directivity in the direction orthogonal to the arrangement direction of the piezoelectric elements can be lowered even when the frequency of the central part in the orthogonal direction of the piezoelectric elements is the highest and decreases toward both ends, The phase can be controlled freely using an array of many piezoelectric elements, the ultrasonic beam can be narrowed down and the ultrasonic beam can be deflected, thereby providing a high-resolution ultrasonic image. An ultrasonic probe can be obtained.

  According to the present invention, since the ultrasonic directivity in the direction orthogonal to the arrangement direction of the piezoelectric elements can be set to a desired characteristic, phase control can be freely performed using many arrangements of the piezoelectric elements. Since the acoustic beam can be narrowed down and the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

<First Embodiment>
Hereinafter, an ultrasonic probe according to an embodiment of the present invention will be described with reference to the drawings. 1 and 2 show an ultrasonic probe according to a first embodiment of the present invention. FIG. 1 is a top view, and FIG. 2 is a side sectional view taken along line AA ′ of FIG.

  1 and 2, a plurality of ultrasonic probes are arranged in the Y direction in order to transmit and receive ultrasonic waves in the Z direction, and are arranged in the X direction by dividing grooves 7b substantially parallel to the Y direction. Divided piezoelectric element 1, common ground electrode 2 provided on the upper surface of piezoelectric element 1, a plurality of signal electrodes 3 provided on the back surface of each piezoelectric element 1, and for individual signals A plurality of signal electrical terminals 4 for taking out signals from the electrodes 3 respectively, and a back surface load material 5 having a function of mechanically holding the back surface of the piezoelectric element 1 and attenuating unnecessary ultrasonic signals as necessary. Have. For the piezoelectric element 1, a piezoelectric ceramic such as a PZT system, a single crystal, or the like is used. The ground electrode 2 and the signal electrode 3 are formed on the upper surface and the rear surface of the piezoelectric element 1 by evaporating or sputtering gold or silver, or baking silver, respectively.

  In FIG. 1, the pitch 6 of the piezoelectric elements 1 adjacent in the arrangement direction Y is determined as necessary. For example, in a so-called electronic sector type in which an ultrasonic beam is electronically phase-controlled and deflected, the number of arrangement of the piezoelectric elements 1 is 64 to 128. From the relationship of the grating lobe generation angle, the adjacent piezoelectric elements 1 The pitch 6 is generally a half wavelength, and when the frequency is 2.5 MHz and the sound speed of a medium such as a living body is 1.54 km / s, the pitch is 0.308 mm.

  In addition, the width W in the arrangement direction Y of the individual piezoelectric elements 1 is formed so that the width near the center in the X direction is the narrowest width Wmin and gradually widens toward both ends, and becomes the maximum width Wmax at both ends. Grooves 7 are formed between the piezoelectric elements 1. In this way, by setting the width W in the arrangement direction Y of the piezoelectric elements 1 to be different depending on the position in the X direction (directivity setting means), the directivity can be easily changed.

  For this reason, the width of the groove 7 formed between the adjacent piezoelectric elements 1 is wide in the vicinity of the central portion, contrary to the width W of the piezoelectric elements 1, and is narrowed toward both ends. In order to allow the adjacent piezoelectric elements 1 to vibrate acoustically independently, it is desirable that the groove 7 has a large difference in acoustic impedance with the piezoelectric element 1, and ideally gas (air) is good. However, since the piezoelectric element 1 is stable and holds against mechanical shock, in practice, materials such as silicon rubber and urethane rubber and inorganic or inorganic powders are mixed in these materials. Material is filled. As a method of making the width W of the piezoelectric element 1 different depending on the position in the X direction in this way, a processing method combining laser and chemical etching, or processing with sandblasting or the like with the piezoelectric element 1 in a patterned mask state. It is possible to carry out by the method of doing.

  Further, the piezoelectric element 1 is provided with a plurality of dividing grooves 7b parallel to the arrangement direction Y in a direction X orthogonal to the arrangement direction Y of the piezoelectric elements 1, and the piezoelectric element 1 is also referred to as an orthogonal direction X (hereinafter also referred to as a short axis direction). ). Although FIG. 1 shows a state of being divided into five, the number of divisions may be set according to the purpose. The ground electrode 2 may be provided after the piezoelectric element 1 is provided with the dividing groove 7b and the dividing groove 7b is filled with a filler. Further, the signal electrode 3 is divided by the dividing groove 7b together with the piezoelectric element 1, and is divided to a depth of a part of the back load member 5 as shown in FIG. Are configured to take out the signal electrical terminals 4 respectively. The connection of the terminal after the signal electrical terminal 4 is taken out varies depending on the purpose, but here, the configuration of the connection for the central signal electrical terminal 4 is shown. Such a configuration is a type in which a plurality of piezoelectric elements 1 are two-dimensionally arranged and is called a so-called two-dimensional array.

  FIG. 2 is a diagram showing a cross section taken along the line AA ′ in FIG. 1, and the piezoelectric element 1 is formed so that the thickness T in the Z direction varies depending on the position in the X direction. The thickness T of the element 1 is set to a minimum value (Tmin), and the thickness increases toward both ends, and the curved shape has a maximum value (Tmax) at both ends. Thus, with respect to the short axis direction X of the piezoelectric elements 1 arranged in a plurality in the Y direction, the central part where the thickness T of the piezoelectric element 1 is the thinnest can transmit and receive with a high frequency component, and the piezoelectric element 1 as it goes to both ends. Since the frequency becomes thick, transmission / reception can be performed with a component having a low frequency, so that the focal depth of the ultrasonic beam can be increased and a broadband frequency characteristic can be obtained.

On the other hand, when a plurality of piezoelectric elements 1 arranged in the Y direction are electronically delayed for each piezoelectric element 1 to control the phase and deflect the ultrasonic beam, the directivity of the piezoelectric element 1 is greatly improved. Affect. That is, when phase control is performed, it is desirable that each piezoelectric element 1 has a lower directivity because the degree of freedom of phase control is increased. The directivity coefficient indicating the directivity is calculated by the following equation which is generally well known.
Re (θ) = sin (π ・ a ・ sinθ / λ) / (π ・ a ・ sinθ / λ)
Here, a is the width W of the piezoelectric element 1, and λ is the wavelength (sound speed / frequency of the medium). As can be seen from the above equation, the directivity coefficient Re (θ) tends to decrease as the width a of the piezoelectric element 1 decreases, and also increases as the frequency increases.

  This ultrasonic probe applies an electrical signal from a main body of an ultrasonic diagnostic apparatus or the like via a signal electrical terminal 4 and a ground electrical terminal (not shown) drawn from the ground electrode 2 to thereby provide a piezoelectric element. 1 is an apparatus for transmitting and receiving ultrasonic waves by mechanical vibration, and an ultrasonic probe for an ultrasonic diagnostic apparatus using a living body as a subject is in direct contact with the living body or indirectly through an ultrasonic propagation medium. Sending ultrasonic waves to the living body in contact, receiving the reflected wave reflected from the living body again with the ultrasonic probe, processing the signal with the main body and displaying the diagnostic image on the monitor for diagnosis It is a so-called sensor used.

  As this method, the phase is controlled by delaying the transmission / reception time of each of the plurality of piezoelectric elements 1 arranged in the Y direction so that the ultrasonic beam is narrowed to a desired position for high resolution, or the ultrasonic beam is deflected. For example, a method of scanning in a fan shape has become common. For example, in the configuration shown in FIGS. 1 and 2, a piezoelectric element in which the center frequency of both ends is set to 2.5 MHz and the center is set to 5 MHz using a piezoelectric ceramic equivalent to PZT-5H as the piezoelectric element 1. The thickness T of 1 is Tmin = about 0.3 mm at the center and gradually increases toward both ends, and the thickness at both ends becomes Tmax = about 0.6 mm.

  On the other hand, with respect to the arrangement direction Y, as described above, when the pitch 6 is set based on a half wavelength, the width Wmin of the central portion of the piezoelectric element 1 is 1 wavelength (0.308 mm) because the frequency = 5 MHz. Wmin = 0.154 mm at a half of. The width of the piezoelectric element 1 gradually and continuously widens from the width Wmin toward both ends (curved surface shape), and the frequency W = 2.5 MHz at both ends, so the width Wmax is 0.308 mm. With this configuration, the directivity in the X direction of the piezoelectric element 1 varies depending on the position in the X direction even if the frequency changes from the center to both ends. Therefore, almost the same directivity can be ensured.

  In addition, the directivity characteristics in the X direction can be changed by changing the width W in the arrangement direction Y of the piezoelectric elements 1 in the X direction according to the purpose. Further, the high frequency of the piezoelectric element 1 near the center in the X direction tends to display a close distance (a position where the depth is shallow) in the ultrasonic image, and it is desirable that the directivity is lower. Can be made narrower and the directivity can be made lower than both ends. Therefore, since the directivity can be lowered even in a portion having a high frequency component near the center of the piezoelectric element 1, phase control can be freely performed using the number of arrangements of the piezoelectric elements 1. Since an ultrasonic beam can be narrowed down and an ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

  In the first embodiment, the configuration in which nothing is provided on the ground electrode 2 positioned on the upper surface side of the piezoelectric element 1 has been described. However, one or more acoustic matching layers are provided on the upper surface of the ground electrode 2. The same effect can be obtained even if the configuration of the ultrasonic probe in which is formed. In the first embodiment, a configuration using a piezoelectric ceramic such as PZT or a single crystal as the piezoelectric element 1 has been described. In addition, a so-called composite in which the piezoelectric element 1 is a composite of a piezoelectric ceramic and an organic polymer. The same effect can be obtained even if the configuration of an ultrasonic probe using a piezoelectric body is used.

<Second Embodiment>
Next, an ultrasonic probe according to a second embodiment of the present invention is shown in FIGS. 3 and 4, the ultrasonic probe is arranged in the Y direction in order to transmit and receive ultrasonic waves in the Z direction, and is divided into a plurality of parts in the X direction, and on the upper surface of the piezoelectric element 11. A common ground electrode 12 provided, a plurality of signal electrodes 13 provided on the back surface of each piezoelectric element 11, a plurality of signal electrical terminals 14 for extracting signals from the individual signal electrodes 13, respectively. And a back load material 15 having a function of mechanically holding the back surface of the piezoelectric element 11 and attenuating unnecessary ultrasonic signals as necessary. The piezoelectric element 11 is made of a piezoelectric ceramic such as PZT or a single crystal. The ground electrode 12 and the signal electrode 13 are respectively formed on the upper surface and the back surface of the piezoelectric element 11 by evaporating or sputtering gold or silver or baking silver.

  In FIG. 3, the pitch 16 of the piezoelectric elements 11 adjacent in the Y direction is determined as necessary, as in the first embodiment. For example, in a so-called electronic sector type in which an ultrasonic beam is electronically phase-controlled and deflected, the number of arrangement of the piezoelectric elements 11 is generally 64 to 128, the pitch 16 is a half wavelength, and the frequency is 2 When the sound speed of the medium is 1.54 km / s at .5 MHz, it becomes 0.308 mm. Further, the width W of the piezoelectric element 11 is gradually increased as it goes to both ends as the narrowest width Wmin near the center in the X direction, and the width W at both ends becomes the maximum value Wmax.

  Further, a plurality of dividing grooves 17 b are provided in the minor axis direction X of the piezoelectric element 11, and the individual piezoelectric elements 11 are divided in the minor axis direction X. The width W in the minor axis direction X of the piezoelectric element 11 varies stepwise from the width Wmin to Wmax, and further divided by the dividing groove 17b each time the width W of the piezoelectric element 11 changes. This point is different from the first embodiment. 3 and 4 show a state of 11 divisions, the number of divisions may be set according to the purpose. The ground electrode 12 may be provided after the dividing groove 17b is provided in the piezoelectric element 11 and the dividing groove 17b is filled with a filler. Further, the signal electrode 13 is divided by the dividing groove 17b together with the piezoelectric element 11, and is divided to a depth of a part of the back surface load material 15 as shown in FIG. Are configured to take out the signal electrical terminals 14 respectively. The connection of the terminal after the signal electrical terminal 14 is taken out varies depending on the purpose, but here, the configuration of the connection in which the central signal electrical terminal 14 is symmetric is shown. Such a configuration is a type in which a plurality of piezoelectric elements 11 are two-dimensionally arranged, which is a so-called two-dimensional array.

  4 is a diagram showing a cross section taken along line BB ′ in FIG. 3. The thickness T in the Z direction of the piezoelectric element 11 varies depending on the position in the X direction. In this example, the vicinity of the central portion of the piezoelectric element 11 is shown. The thickness T becomes the minimum value Tmin, and the thickness T increases as it goes to both ends, and the both ends have the maximum value Tmax. The thickness T of the piezoelectric element 11 may be changed continuously or may be changed stepwise. Thus, with respect to the minor axis direction X of the piezoelectric element 11, the central portion where the thickness T of the piezoelectric element 11 is the thinnest can transmit and receive a high frequency component, and the piezoelectric element becomes thicker toward both ends, so the component has a low frequency. The transmission / reception in the area can be performed to increase the focal depth of the ultrasonic beam and to obtain a wide frequency characteristic.

  On the other hand, when the piezoelectric elements 11 arranged in the Y direction are phase-controlled by electronically delaying the individual piezoelectric elements 11 to deflect the ultrasonic beam, the directivity of the piezoelectric elements 11 greatly affects the performance. This is the same as described above in the first embodiment. That is, when phase control is performed, it is desirable that the individual piezoelectric elements 11 have a lower directivity and the degree of freedom for phase control is widened. Since the operations of these ultrasonic probes are the same as those described in the first embodiment, they are omitted here.

  For example, in the configuration shown in FIGS. 3 and 4, the piezoelectric element 11 is made of piezoelectric ceramic equivalent to PZT-5H, the center frequency at both ends is set to 2.5 MHz, and the center is set to 5 MHz. The thickness T of 11 is Tmin = about 0.3 mm at the center and gradually increases toward both ends, and the thickness Tmax at both ends is about 0.6 mm. On the other hand, in the arrangement direction Y, when the arrangement pitch 16 is basically set to a half wavelength as described above, the width Wmin of the narrowest piezoelectric element 11 at the center is 5 MHz, so one wavelength = 0.308 mm. In half, Wmin = 0.154 mm.

  As the width Wmin goes to both ends, for example, the frequency stage is symmetrically divided from the center, and is divided into six parts on one side (11 parts on both sides), so that the width W of the piezoelectric element 11 increases stepwise. Therefore, if the central high frequency is 5 MHz, the next is 4.5 MHz, 4 MHz, 3.5 MHz, 3 MHz, and both ends are set to 2.5 MHz, and the width W is set to a half wavelength. Width W is 0.154mm at 5MHz, 0.171mm at 4.5MHz, 0.193mm at 4MHz, 0.22mm at 3.5MHz, 0.257mm at 3MHz, and both ends are widest at 2.5MHz Wmax = 0.308 mm.

  With such a configuration, the directivity in the arrangement direction Y of the piezoelectric elements 11 changes the width W of the piezoelectric elements 11 even if the frequency changes stepwise from the center in the X direction to both ends. Therefore, almost the same directivity characteristics can be secured. Accordingly, since the directivity can be lowered even in a portion having a high frequency component near the center of the piezoelectric element 11, the phase can be freely controlled using a large number of arrangements of the piezoelectric elements 11, and the ultrasonic beam can be used. Since an ultrasonic beam can be narrowed down and an ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

In the second embodiment, the configuration in which nothing is provided on the upper surface of the ground electrode 12 has been described. However, an ultrasonic probe in which one or more acoustic matching layers are formed on the upper surface of the ground electrode 12 is described. Even when configured, the same effect can be obtained. Further, in the second embodiment, a configuration using a piezoelectric ceramic such as PZT or a single crystal as the piezoelectric element 11 has been described. However, as the piezoelectric element 11, a so-called composite piezoelectric element in which a piezoelectric ceramic and an organic polymer are combined. The same effect can be obtained even if the structure of the ultrasonic probe using the body is used.
Note that changing the width W of the piezoelectric element 11 in stages is more advantageous in terms of processing and cost than changing the width W continuously. Ideally, it is desirable to process this stage more precisely and to make it a continuously changing type with better performance.

<Third Embodiment>
Next, an ultrasonic probe according to a third embodiment of the present invention is shown in FIGS. The ultrasonic probe includes a plurality of piezoelectric elements 21 arranged in the Y direction for transmitting and receiving ultrasonic waves in the Z direction and divided in the X direction, and a common ground electrode provided on the upper surface of the piezoelectric element 21. 22, one or more acoustic matching layers 28 (here, one acoustic matching layer) provided on the upper surface of the ground electrode 22, and a plurality of signal electrodes 23 provided on the back surface of each piezoelectric element 21. A plurality of signal electrical terminals 24 for taking out signals from the individual signal electrodes 23, and a function of mechanically holding the back surface of the piezoelectric element 21 and attenuating unnecessary ultrasonic signals as necessary. And a back load material 25. For the piezoelectric element 21, a piezoelectric ceramic such as PZT, a single crystal, or the like is used. The ground electrode 22 and the signal electrode 23 are respectively formed on the upper surface and the rear surface of the piezoelectric element 21 by evaporating or sputtering gold or silver, or baking silver.

  As shown in FIG. 5, in the minor axis direction X of the piezoelectric element 21 and the acoustic matching layer 28, the width W is not changed unlike the first and second embodiments, but the structure in the minor axis direction X is the first. 1 and different from the second embodiment. That is, the piezoelectric element 21 and the acoustic matching layer 28 are divided by the plurality of dividing grooves 27b in the minor axis direction X. The number of divisions is 11, but the number of divisions is determined as appropriate according to the purpose. The signal electrodes 23 divided in the same manner as the piezoelectric element 21 are respectively taken out by signal electric terminals 24. On the other hand, as shown in FIG. 5, the acoustic matching layer 28 is divided into six central portions in the short axis direction X by grooves 27 in the arrangement direction Y, and the number of divisions is gradually reduced as it goes to both ends. It is configured.

  7 and 8 are cross-sectional views taken along lines C-C 'and D-D' in FIG. 5, respectively, for explaining the configuration of the groove 27 of the acoustic matching layer 28. FIG. FIG. 7 shows a central part of the acoustic matching layer 28 divided into six parts, and FIG. 8 shows a part divided into four parts adjacent to the central part. The inside of the grooves 27 of these acoustic matching layers 28 is most preferably in an air state, but if it is difficult to construct an ultrasonic probe, a soft resin such as silicon rubber, urethane rubber or these resins is used. Alternatively, a powder filled with inorganic powder may be used. Here, the groove 27 provided in the acoustic matching layer 28 may be provided up to a part of the piezoelectric element 21.

  With the above configuration, when the piezoelectric element 21 performs transmission / reception of an ultrasonic wave having a high frequency at the center in the X direction and a low frequency toward both ends, the piezoelectric element 21 in the short axis direction X Although the width is the same, since the number of divisions of the acoustic matching layer 28 is increased as the frequency is higher, the directivity is lower. This utilizes the fact that the directivity can be lowered by dividing the acoustic matching layer 28 without dividing the piezoelectric element 21. Therefore, it is possible to solve the problem that the central portion in the X direction is different in the directivity characteristics at both ends and the central portion becomes high.

  That is, paying attention to the fact that the directivity characteristics of this ultrasonic probe are related to the width of the acoustic matching layer 28 as well as the width of the piezoelectric element 21 or the number of divisions, the number of divisions in the Y direction of the acoustic matching layer 28 is represented by X. By increasing toward the center of the direction, it is closer to a point sound source and the directivity is lowered. In the present embodiment, since the central portion has a high frequency and high directivity, the number of divisions in the central portion in the X direction of the acoustic matching layer 28 is maximized in order to reduce this, and steps are performed as it goes to both ends. If the number of divisions of the acoustic matching layer 28 is reduced, almost the same directivity characteristics can be obtained. Furthermore, since the piezoelectric element 21 and the acoustic matching layer 28 are divided in the minor axis direction X and the signal electrical terminal 24 is taken out from each, the ultrasonic beam can be controlled by electrical switching or phase control. Become.

  Therefore, since the directivity can be lowered even in a portion having a high frequency component near the center in the X direction of the piezoelectric element 21, phase control can be freely performed using a large number of arrangements of the piezoelectric elements 21. Since the acoustic beam can be narrowed down and the ultrasonic beam can be deflected, an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained.

  In the third embodiment, a configuration using a piezoelectric ceramic such as PZT or a single crystal as the piezoelectric element 21 has been described. However, a so-called composite piezoelectric body in which a piezoelectric ceramic and an organic polymer are combined is used as the piezoelectric element 21. The same effect can be obtained even if the configuration of the conventional ultrasonic probe is used. In the third embodiment, the width W in the arrangement direction Y of the piezoelectric elements 21 has been described as being substantially the same in the X direction. However, in addition to this, the center portion in the X direction is narrower and becomes wider toward both ends. However, the same effect can be obtained even when the piezoelectric element 11 is configured as an ultrasonic probe using a so-called composite piezoelectric body in which a piezoelectric ceramic and an organic polymer are combined.

<Fourth embodiment>
Next, an ultrasonic probe according to a fourth embodiment of the present invention will be described with reference to FIGS. Since the configuration of the fourth embodiment is the same as that of the first embodiment, description thereof is omitted, and here, the function and operation of the fourth embodiment will be mainly described. On the other hand, a plurality of dividing grooves 7 b are provided and divided in the minor axis direction X of the piezoelectric element 1. Although FIG. 1 shows a state of being divided into five, the number of divisions may be set according to the purpose. The dividing groove 7b of the piezoelectric element 1 can be easily formed by machining such as a dicing machine. The ground electrode 2 may be provided after the piezoelectric element 1 is provided with the dividing groove 7b and the dividing groove 7b is filled with a filler.

  Further, the signal electrode 3 is divided by the dividing groove 7b together with the piezoelectric element 1, and further divided to a depth of a part of the back surface load material 5 as shown in FIG. The signal electrical terminal 4 is taken out from each of them. The connection of the terminal after the signal electrical terminal 4 is taken out varies depending on the purpose, but here, a configuration of connection in which the central signal electrical terminal 4 is symmetrical is shown. Such a configuration is a type in which a plurality of piezoelectric elements 1 are two-dimensionally arranged and is called a so-called two-dimensional array.

  Further, as shown in FIG. 2, the thickness T of the piezoelectric element 1 varies depending on the position in the X direction, the thickness T of the piezoelectric element 1 near the center is the thinnest Tmin, and the thickness increases toward both ends. The shape is Tmax. Thus, with respect to the short axis direction X of the piezoelectric elements 1 arranged in a plurality, the central portion where the thickness T of the piezoelectric element 1 is the thinnest can transmit and receive a high frequency component, and the piezoelectric element becomes thicker toward both ends. Therefore, transmission / reception with a component having a low frequency can be performed, so that the focal depth of the ultrasonic beam can be increased and a broadband frequency characteristic can be obtained. On the other hand, since the width W of the piezoelectric element 1 varies from Wmin to Wmax in the X direction corresponding to each frequency, the directivity in the X direction can be changed depending on the place, or similar characteristics can be obtained. .

  In the fourth embodiment, the ratio W / T of the width W and the thickness T of the piezoelectric element 1 is changed for the piezoelectric elements 1 having continuously different thicknesses Tmin to Tmax and widths Wmin to Wmax. On the other hand, as the W / T of the piezoelectric element 1 is already known, the higher the electromechanical coupling coefficient k of the piezoelectric element 1, the higher the sensitivity and the wider the frequency ratio band. This is greatly related to W / T, and in the piezoelectric ceramic material corresponding to PZT-5H, the electromechanical coupling coefficient k is highest when W / T is in the vicinity of 0.5 to 0.6.

  Accordingly, since the thickness T is the thinnest in the vicinity of the central portion in the X direction of the piezoelectric element 1, the width W is set so that W / T is 0.5 to 0.6 corresponding to the thickness T, and both end portions Since the thickness T of the piezoelectric element 1 increases as it goes to, W / T gradually changes widely so that the value in a predetermined range becomes a width value of 0.5 to 0.6. Is desirable. As a result, the electromechanical coupling coefficient k is the same in any region, so that good characteristics (frequency characteristic sensitivity) can be obtained. Further, in the case where the frequency is changed by changing the thickness T of the piezoelectric element 1 in the direction X orthogonal to the arrangement direction Y, if the width W of the piezoelectric element 1 is the same from the center to both ends, W / T at the thin center is increased. When W / T exceeds 0.6, vibration occurs in the width direction Y, so if this frequency is close to the vibration frequency in the thickness direction Z, the frequency characteristics are adversely affected. The present embodiment is configured to reduce the adverse effect of the vibration frequency in the width direction Y.

  With the configuration as described above, a portion having a high frequency component near the center of the X direction of the piezoelectric element 1 can also have a low directivity and a high value as the electromechanical coupling coefficient k of the piezoelectric element 1. Since the influence of the frequency of the width vibration can be reduced, it has a wide frequency band with high sensitivity, and furthermore, the ultrasonic beam can be narrowed down, so that an ultrasonic probe that provides an ultrasonic image with high resolution can be obtained. Can do. Furthermore, since the piezoelectric element 1 is divided in the minor axis direction X and the signal electrical terminals 4 are taken out from the respective piezoelectric elements 1, it is possible to change the transmission and reception of ultrasonic waves from the piezoelectric element 1 by electrical switching. In addition, an ultrasonic probe that provides an ultrasonic image with higher resolution can be obtained.

  In the fourth embodiment, the thicknesses Tmin to Tmax and the widths Wmin to Wmax of the piezoelectric element 1 are continuously changed. However, the thicknesses Tmin to Tmax and the width Wmin of the piezoelectric element 1 are also described. The same effect can be obtained by changing both of .about.Wmax stepwise, or changing only the thickness T or only the width W stepwise.

<Fifth embodiment>
An ultrasonic probe according to a fifth embodiment of the present invention is shown in FIGS. 9 and 10, the ultrasonic probe includes a plurality of piezoelectric elements 31 arranged in the Y direction and divided in the X direction to transmit and receive ultrasonic waves in the Z direction, and an upper surface of the piezoelectric element 31. A common ground electrode 32 provided, a plurality of signal electrodes 33 provided on the back surface of each piezoelectric element 31, a plurality of signal electrical terminals 34 for extracting signals from the plurality of signal electrodes 33, And a back load member 35 having a function of mechanically holding the back surface of the piezoelectric element 31 and attenuating unnecessary ultrasonic signals as necessary. The piezoelectric element 31 is made of a piezoelectric ceramic such as PZT or a single crystal. The ground electrode 32 and the signal electrode 33 are respectively formed on the upper surface and the rear surface of the piezoelectric element 31 by evaporating or sputtering gold or silver or baking silver.

  In FIG. 9, the pitch 36 of the piezoelectric elements 31 is determined as necessary, and the grooves 37 of the arranged piezoelectric elements 31 are made of materials such as silicon rubber and urethane rubber and those materials in the same manner as in the first embodiment. Filled with material mixed with inorganic or inorganic powder. The piezoelectric element 31 is divided in the minor axis direction X by the dividing groove 37b (here, divided into five), and the signal electrode 33 is also divided in the X direction in the same manner as the piezoelectric element 31, and the divided signal is divided. Each of the signal electrodes 33 is taken out by a signal electrical terminal 34.

  Further, the difference between the present embodiment and the first embodiment is that the piezoelectric element 31 has a substantially uniform thickness T with respect to the minor axis direction X as shown in FIG. The fact that the thickness T of the piezoelectric element 31 is uniform means that ultrasonic waves having substantially the same frequency are transmitted and received in the minor axis direction X. However, even when the piezoelectric element 31 has the same frequency, the width W of the piezoelectric element 31 is changed. The directivity in the X direction of the piezoelectric element 31 can be changed. In FIG. 10, the width W of the piezoelectric element 31 is set to the minimum width Wmin at the center in the X direction, and the width W is increased toward both ends, and the width W of the piezoelectric element 31 is maximum at both ends. The value is Wmax.

  By adopting such a configuration, the directivity in the short axis direction X of the piezoelectric element 31 has the characteristic that the central portion has the lowest directivity and gradually increases toward both ends. . On the other hand, the ultrasonic beam by the electronic delay control in the arrangement direction Y of the piezoelectric elements 31 can be narrowed down at an arbitrary distance (depth), but is directed so much in a region far (deep) from the piezoelectric element 31. Although the ultrasonic beam can be narrowed even if the directivity is not low, the directivity is greatly affected at a short distance, and the degree of narrowing of the ultrasonic beam changes. In the present embodiment, the directivity is the lowest in the vicinity of the central portion of the piezoelectric element 31 in the short axis direction X, so that the largest contribution is made when the ultrasonic beam is narrowed by electronic control to a short distance. The contribution decreases as you go. Therefore, in the short axis direction X of the piezoelectric element 31, the ultrasonic beam is controlled with a small opening near the central region, so that an ultrasonic image with high resolution can be obtained in the short distance region.

  In the fifth embodiment, the configuration in which nothing is provided on the upper surface of the ground electrode 32 has been described. However, an ultrasonic probe in which one or more acoustic matching layers are formed on the upper surface of the ground electrode 32 is described. Even when configured, the same effect can be obtained. In the fifth embodiment, a configuration using a piezoelectric ceramic such as PZT or a single crystal as the piezoelectric element 31 has been described. In addition, the piezoelectric element 31 is a so-called composite piezoelectric in which a piezoelectric ceramic and an organic polymer are combined. The same effect can be obtained even if the structure of the ultrasonic probe using the body is used.

  Since the ultrasonic probe of the present invention can obtain an ultrasonic image with high resolution, it can be used for ultrasonic diagnosis and examination such as medical treatment.

The top view which shows the outline of the ultrasonic probe in the 1st and 4th embodiment of this invention Side surface sectional view along line A-A 'in FIG. The top view which shows the outline of the ultrasonic probe in the 2nd Embodiment of this invention Side surface sectional drawing along line B-B 'in FIG. The top view which shows the outline of the ultrasonic probe in the 3rd Embodiment of this invention Side sectional view of FIG. Side surface sectional drawing along line C-C 'in FIG. Side surface sectional drawing along line D-D 'in FIG. The top view which shows the outline of the ultrasonic probe in the 5th Embodiment of this invention Side surface sectional drawing along line E-E 'in FIG. The perspective view which shows the outline of the conventional ultrasonic probe

Explanation of symbols

1, 11, 21, 31 Piezoelectric element 2, 12, 22, 32 Ground electrode 3, 13, 23, 33 Signal electrode 4, 14, 24, 34 Signal electrical terminal 5, 15, 25, 35 Back load material 6 16, 26, 36 Pitch 7, 17, 27, 37 Groove 7b, 17b, 27b, 37b Divided groove 28 Acoustic matching layer

Claims (10)

An ultrasonic probe in which a plurality of piezoelectric elements that transmit and receive ultrasonic waves are arranged in one direction,
Directivity setting means for setting ultrasonic directivity in a direction orthogonal to the arrangement direction of the piezoelectric elements;
An ultrasonic probe comprising: a plurality of divided grooves for dividing each of the piezoelectric elements into a plurality and arranging them in a row in the orthogonal direction.   The ultrasonic probe according to claim 1, wherein the directivity setting unit is configured such that the width in the arrangement direction of the piezoelectric elements is the narrowest at the center portion in the orthogonal direction and becomes wider toward both ends.   The ultrasonic probe according to claim 2, wherein the width of the piezoelectric element is configured to continuously increase from the center in the orthogonal direction toward both ends.   The ultrasonic probe according to claim 2, wherein the piezoelectric element is configured so that the width of the piezoelectric element gradually increases from the center in the orthogonal direction toward both ends. Having one or more acoustic matching layers formed on the piezoelectric element;
The directivity setting means is configured such that the number of divisions in the arrangement direction is the largest in the central portion in the orthogonal direction of the acoustic matching layer, and the number of divisions in the arrangement direction is reduced toward both ends. The ultrasonic probe according to any one of 1 to 4. The thickness T of the piezoelectric element varies depending on the position in the orthogonal direction,
2. The directivity setting means is configured such that a ratio W / T of the width W and thickness T of the piezoelectric element becomes a value within a predetermined range from the central portion in the orthogonal direction toward both ends. The described ultrasonic probe.   The ultrasonic wave according to claim 6, wherein the ratio W / T of the width W to the thickness T is configured to be a value in a predetermined range continuously or stepwise from the center in the orthogonal direction toward both ends. Transducer.   The ultrasonic probe according to claim 1, wherein the plurality of piezoelectric elements have the same thickness in the orthogonal direction.   The directivity setting means is configured so that the directivity of the ultrasonic probe is lowest at the central portion in the orthogonal direction and becomes higher toward both ends. Ultrasonic probe. The ultrasonic probe according to any one of claims 1 to 9, wherein a transmission / reception frequency of the piezoelectric element is configured to be highest at a central portion in the orthogonal direction and lower toward both ends.

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