JPH0316974A - Composite piezoelectric ceramic material and production thereof - Google Patents

Abstract

PURPOSE:To enable formation of a complex piezoelectric ceramic material having characteristics of a desired dielectric constant or controlled acoustic impedance by providing holes of the same shape arranged so as to have a homogeneous density distribution in one direction or density distribution tilted in one direction in the interior of piezoelectric ceramics. CONSTITUTION:The above-mentioned piezoelectric ceramic material has holes 4 of the same shape arranged so as to provide a homogeneous density distribution in one direction or holes 4' of the same shape arranged with a density distribution tilted in one direction in the interior of piezoelectric ceramics 3. Characteristics thereof can be also changed by embedding metal units different from the piezoelectric ceramics in part or all of the aforementioned holes or plating the inner walls of the holes with a metal. The above-mentioned composite piezoelectric ceramic material is obtained by the following method. That is a formed body of a piezoelectric ceramic material containing carbon fiber as a hole-forming agent formed into a prescribed intended pattern for forming the holes is formed and then calcined to burn away the aforementioned hole- forming agent.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a composite piezoelectric ceramic material and a method for manufacturing the same, and particularly to a composite piezoelectric ceramic material having a fine structure in which, for example, holes, conductor wires, etc. are distributed in a predetermined size and density. The present invention relates to a composite piezoelectric ceramic material having the following characteristics and a method for manufacturing the same.

[Prior Art] Recently, research and application development using ultrasonic waves have made remarkable progress. For example, ultrasonic transducers have been developed for the purpose of biological observation using ultrasonic waves and detection of various devices that detect underwater sounds. Piezoelectric elements, which have excellent characteristics, are used as transmitters and receivers for each purpose. Among piezoelectric elements, PZT-based piezoelectric ceramics is well known as one of the piezoelectric elements made of inorganic materials, and is widely used, for example, as an ultrasonic transducer for ultrasonic diagnostic equipment.

Initially, for example, in the case of PZT ceramics, piezoelectric ceramics having a uniform composition consisting of Pb(Zr-Tj)03 alone were used. However, achieving this uniform disassembly is quite difficult;
In reality, the distribution of compositions such as Zr and Ti is not uniform, or even if the above-mentioned compositional distribution is uniform, the ceramic itself is not homogeneous and has many irregularly distributed pores inside. There were some cases in which the desired piezoelectric performance could not be obtained due to the existence of Such piezoelectric ceramics are very hard and have a high acoustic impedance, which makes it difficult to connect them to the acoustic impedance of living organisms or water. It was only possible to freely control the value of the characteristic value (characteristic value indicating relative dielectric constant).

Therefore, the following techniques have conventionally been used to counter the above-mentioned inconveniences. First, Wang, T+4 Fee, 37 (1.) (January 1.989 issue) P. I. 0(
7) Applying the technology disclosed in Karen 1.1 Pick column, acrylic resin patterned by photolithography technology is used as a pore forming agent.For example, pressure 7. There is a method of obtaining porous ceramics in which the pore-forming pattern part remains empty by performing a pasting process after receiving the shipment. By applying this technique to create piezoelectric ceramics with holes or microspaces as intended,
Matching of acoustic impedance with biological nato,
Moreover, it is being considered that it may be possible to make piezoelectric ceramics with a large value of ε33.

The above-mentioned literature further develops this treatment technique and successfully produces a metal-ceramic composite in which metal is injected into the pores by the pore injection method.

3 Also, patent application No. 636767 filed by the same applicant as the present applicant.
As shown in No. 1, a laminated piezoelectric body is formed by stacking and firing two or more Green Seas 1 made of materials with different dielectric constants, or electrodes 4ii are formed by embedding metal inside;
Piezoelectric ceramics have been developed for similar purposes, and improvements and developments have been carried out accordingly.

In addition, other conventional examples include, for example, Proceedings of the Numbosium Lecture on the Foundation and Application of Ultrasonic Electronics, c-8 (December 7, 1988), P3, ``Flame Piezoelectric Materials''. There is one disclosed in "Ultrasonic Probe". In this document, the sensitivity of the ultrasonic probe is improved by using a laminated structure of the piezoelectric body of the ultrasonic transmitting/receiving element. The principle is to reduce the impedance of the probe head using a laminated piezoelectric material, thereby reducing the transmission loss of the received signal caused by the capacitance of the cable and the input impedance of the device, thereby improving efficiency.

[Problem to be solved by the invention] In the conventional composite piezoelectric ceramics and manufacturing method thereof as described above, in particular, in the manufacturing method, a pore forming pattern made of a hollow material is formed using photolithography. Not only is it inherently time-consuming and complicated to form, but also the hole formation pattern is
There is a problem that there is no control over the formation of r.

This invention was made to solve the above-mentioned problems, and it is possible to produce a composite piezoelectric ceramic material having a desired size and density distribution including taper (gradient) density using i! l
Furthermore, the apparent ε33 can be increased by embedding a metal conductor in this hole using the partially embedded electrode method, forming electrodes by dividing them in the depth direction, or embedding them using the entire embedded electrode method. Another object of the present invention is to provide a controlled composite piezoelectric ceramic material and a manufacturing method thereof.

[A Thousand Steps to Solve a Drill Problem] The stepped piezoelectric ceramic moon according to the present invention has the same shape or different shapes arranged inside the piezoelectric ceramic in one direction, for example, in the thickness direction, with a uniform or inclined density distribution. It has pores of.

In addition, a composite piezoelectric ceramic material according to another invention is formed by partially or completely filling holes of the same shape arranged with a uniform density distribution in one direction inside with a conductor such as metal. It is something. Further, in the composite piezoelectric ceramic material having holes of the same shape as described above, some or all of the inner walls of the holes are formed to have a metal-plated surface.

Furthermore, the method for manufacturing a composite piezoelectric ceramic shrine according to the present invention is a green seal of a piezoelectric ceramic shrine having carbon fibers formed to have a predetermined pattern of pore formation as a pore forming agent (also referred to as a "cutting mold"). A composite piezoelectric ceramic having pores with a predetermined shape and density distribution is produced by forming a molded body from a slurry and burning off the carbon fiber portion using a die-cutting method of burning this molded body. It is something that has a certain shape. It is also easy to form a composite piezoelectric ceramic structure using a metal-ceramic composite by the hole-forming injection method in which a part or all of the holes in which a conductor such as a metal is formed is pressed.

[Function] In this invention, a carbon fiber or cloth-like molded product is used as a mold to form holes inside the piezoelectric ceramic during firing, so it can be molded with any thickness (diameter) or any shape. By taking advantage of the characteristics of carbon fibers that can be used to form carbon fibers, the arrangement and direction of the pore formation pattern can be freely selected.

In other words, it is easy to form a piezoelectric ceramic molded body by, for example, infiltrating a slurry of a ceramic material after forming a mold into an arbitrary shape. In addition, in the method of laminating thin green sheets, it is easy to insert carbon fibers of any thickness or between each layer of stacked green sheets to form a mold. .

Furthermore, carbon fibers are vaporized as carbon dioxide during burning, and pores are formed in the same shape as after vaporization. Furthermore, it is also possible to fill the holes after firing with a conductor using the melt injection method (hole injection method), and also to plug unnecessary holes in the outer wall7? It is also optional to infiltrate (or inject) and fill only the required holes with the conductor.

In addition, composite piezoelectric ceramics having formed pores or metal wires injected with a conductor in place of the pores change the ceramic properties, especially the apparent dielectric constant. The piezoelectric properties of piezoelectric ceramics can be controlled over a wide range so as to have a desired dielectric constant.

Furthermore, by changing the diameter of the holes or making the hole density distribution in the thickness direction inclined, the acoustic impedance in one direction is not uniform but gradually changes in an arbitrary mode.

[Example] Embodiments of the present invention will be described below with reference to the accompanying drawings.

Example 1; FIG. 8 shows an example of the method for manufacturing a composite piezoelectric ceramic material according to the present invention.
) is a schematic explanatory diagram shown in order of process drawings. In the figures, (a) = (b) 1 (c) in Fig. 1 is a side view thereof, (a2) 8 (b2) . (C2) is a side cross-sectional view of (a); (b) and (c), respectively, in the direction along line A-A shown in (a).

First, as shown in (a) and (a2> in FIG. 8), carbon fibers are used to form a hole forming pattern (cutting die) on a green sheet 1 made of a raw material or powder of piezoelectric ceramics. 2. are placed in a regular array, and Green Sea 1.1 of the same size is placed on this mold.

Then, (t)) in Figure 8. In (t)2),
Green Sea in the state shown in Fig. 8(a). By pressing the sheet 1 with a press or the like, it is embedded into the molded body 1a of the carbon fiber 2 or ceramic disk while maintaining the shape of the mold.

Furthermore, in (e) and (e2) of the 8th song, the molded body 1a is fired at the firing temperature of this piezoelectric ceramic, and the carbon fibers 2 are burned off at the same time as the firing, so that the space occupied by the carbon fibers 2 is hollowed out. As a result, layered pores 4 are formed in the fired piezoelectric ceramic body 3. In this way, a composite piezoelectric ceramic material 5 in which the pores 4 are distributed within the fired piezoelectric ceramic body 3 is manufactured.

The above explanation relates to the basic method of manufacturing a composite piezoelectric ceramic shrine of the present invention, and shows the method of manufacturing the simplest structure. Actually, by applying this method, instead of arranging the carbon fibers 2 in a fence-like manner as described above, the carbon fibers 2 may be arranged in a gauze or mesh-like structure, or in a lattice-like structure. By using materials with different thicknesses, a composite piezoelectric ceramic moon having a complicated hole formation pattern as shown in Example 2 below is formed. Further, instead of using a green sheet as described above, a molded body as described above may be formed by embedding carbon fibers with a hole formation pattern in a piezoelectric ceramic slurry or the like and drying them. Further, in this method, the piezoelectric ceramic may be made of any material, for example, it is not limited to PZT, and the same manufacturing method can be applied.

Furthermore, all or part of the holes 4 formed in the above manner may be filled with a conductor such as a metal and used as an electrode, or the apparent dielectric constant may be changed or the overall acoustic impedance may be changed. Adjustments are made. This is called the hole molding injection method as in the previous example, or in this case, after forming the holes 4, masking the outer edges of the holes in the holes 4 that are inconvenient. The pore-forming piezoelectric ceramic as described above is immersed in a molten metal in a vacuum, and then an argon gas is introduced and pressure is applied at normal pressure or pressurization. In other words, the molten metal flows into the hole due to the pressure difference, and when it is withdrawn and cooled, a metal-ceramic composite is formed, and a composite piezoelectric ceramic of metal and piezoelectric ceramic is formed. Other than this method, a method may be used in which only predetermined holes are selectively injected with molten metal from a minute nozzle to fill them.

Embodiment 2 Figure 1 schematically shows an embodiment of the present invention published by Composite Piezoelectric Ceramics (generally, the following are all C-shaped)
FIG. By the manufacturing method of Example 1, piezoelectric ceramics were fired with 4 holes (cylindrical cavities) of the same shape spaced at equal intervals from the bottom surface of the body 3. .

Therefore, the pores 4 are formed with a uniform distribution in the thickness direction.

The configuration of the embodiment shown in FIG. 1 can be used, for example, as a prototype for a three-layer piezoelectric material. That is, as shown in Example 5 described below, for example, all of these holes 4 are filled with a conductor such as metal to form a two-layer electrode inside,
A so-called three-layer piezoelectric material having four layers of electrodes, one layer each of which is formed with electrodes (not shown) on the outer, ie, two lower surfaces, is formed based on the structure of the embodiment shown in FIG.

Embodiment 3 FIG. 2 is a side view showing another embodiment of the present invention. As shown in the figure, holes 4 of the same shape with a predetermined regularity are formed in the fired body 3 in the same manner as in Example 2. A predetermined part of the holes 4 of the composite piezoelectric ceramic material is made of a conductor such as metal. The electrode is made of a metal wire 6 which is filled by pressing the metal wire. This configuration has the advantage that the electrodes made of metal wires 6 can be bundled one by one or several adjacent electrodes can be used as an array piezoelectric element.

Embodiment 4: FIG. 3 is a side view of a composite piezoelectric ceramic material showing another embodiment of the present invention. In this case as well, the manufacturing method shown in Embodiment 1 is applied to form the same as in the embodiment shown in FIG.

As seen in the figure, the pores 4 having the same shape are uniformly formed by increasing the distribution density. In this way, when the space factor of the pores 4, i.e., the density and collapse of the pores 4, is decreased by -L, the overall acoustic impedance becomes much smaller than that of a single, uniform and dense material, such as PZT. I can do it. For example, it is preferable that the holes 4 are arranged in an orderly manner alternately in one direction, but it is preferable that the holes 4 are arranged in an orderly manner, for example, but they may be arranged somewhat sloppily and irregularly.
Moreover, even if the walls of some layers collapse, it can still be used with the same performance without any major damage. Furthermore, the piezoelectric elements in this state can be diced and assembled into an array to provide an array of piezoelectric elements.

Combined pressure consisting of the above configuration? Li ceramics may be used with the stress polarized in the vertical or horizontal direction of the figure, that is, in the direction perpendicular to the hole, but the so-called 1
- By forming an array of pillars or walls of 3 connections, or by increasing the density of holes 4 and forming holes close to each other to form a "honeycomb" shape, the paper surface of the figure It is also easy to use it by polarizing it in the direction of , that is, the thickness direction (stress and hole are parallel).

Embodiment 5; FIG. 4 is a side view showing another embodiment of the present invention. The manufacturing method of Example 1 was applied to the composite piezoelectric ceramic material having the structure of Example 4 shown in FIG. It is something. In this way, when the space factor of the conductor 6 is uniformly increased by replacing the conductor 6 in the hole 4, when it is used as a piezoelectric element, the electric displacement (also called electric density) is inside the conductor 6. does not enter, but concentrates in the surrounding piezoelectric ceramic 3, so that the apparent ε33 (permittivity) increases and the piezoelectric properties improve. However, it is unavoidable that the acoustic impedance becomes larger as it approaches metal, corresponding to the space factor.

Embodiment 6: FIG. 5 is a side view showing an embodiment for a case where it is desired to avoid a phenomenon in which the acoustic impedance increases as it approaches metal in the embodiment of FIG. 4. That is, instead of the conductor 6, the inner wall surface of the hole 4 is plated with metal 7. That is, in this case, the metal plating 7 is formed by electroless plating with all the holes left as holes. In this structure, the acoustic impedance maintains the value of Example 4 and retains the effect explained in Example 5, and only the apparent ε33 can be increased, and the composite piezoelectric ceramic according to the present invention From the material standpoint, the effect is close to ideal.

Embodiment 7 FIGS. 6 and 7 are side views showing another embodiment according to the present invention. Figure 6 shows a case in which the thickness of the carbon fibers forming the mold is the same, and the gap between the layers of the hole formation pattern is gradually increased in the thickness direction to form 1 5 ] 6 holes 4 in the same way. It is something. In addition, FIG. 7 shows holes 4, 4a, 4b (in this case, the diameter is 4a) by changing the thickness of carbon fibers and arranging them at equal intervals in the thickness direction in order of diameter size.
<4<4b). Note that in both the embodiments shown in FIGS. 6 and 7, the number of hole layers is not limited to three.

As shown in the embodiments shown in FIGS. 6 and 7, the present invention can also form an acoustic impedance distribution in the thickness direction (Taber in the thickness direction) by changing the density and size of the holes. The manufacturing method is extremely easy.

In this configuration, the acoustic impedance gradually changes in the thickness direction as described above. For example, when this is applied to a piezoelectric transducer in an ultrasound diagnostic device, it is possible to
This has the effect of making matching to the side and matching to the sound absorbing material (back side) easier. Note that if the composite piezoelectric ceramic material of Example 7 is used with metal plating on the inner wall of the hole as in Example 6, the apparent value of ε33 may be increased. can.

[Effects of the Invention] As described above, according to the present invention, a piezoelectric ceramic material is fired using carbon fiber as a mold, and a composite piezoelectric material having holes formed in a continuous duct shape controlled by a burn-out method is produced. Since we have established a manufacturing method for forming a ceramic system, we can easily obtain composite piezoelectric ceramic shrines with different pore densities, diameters, and their distributions. Therefore, the composite piezoelectric ceramic material obtained by this manufacturing method is
For example, it is easy to replace the hole with a conductor or to apply metal plating to the inner wall of the hole, and it is possible to obtain properties with desired dielectric constant and acoustic impedance control. In this way, composite piezoelectric ceramic materials with a wide variety of internal structures greatly contribute to the diversity and usefulness of applications brought about by flexibility in manufacturing.

[Brief explanation of drawings]

FIGS. 1 to 7 are schematic side views for explaining examples of composite piezoelectric ceramic materials according to the present invention, and FIG. This is a manufacturing flow diagram. In the figure, 1 is Green Sea 1, 1a is a molded product, and 2
3 is a fired piezoelectric ceramic body, 4.4a and 4b are holes, 5 is a composite piezoelectric ceramic material, 6 is a metal wire, and 7 is a metal plating.

Claims (6)

[Claims] (1) A composite piezoelectric ceramic material characterized by having pores of the same shape arranged in one direction with uniform density distribution inside the piezoelectric ceramic material. (2) A composite piezoelectric ceramic material characterized by having pores of the same shape arranged with a density distribution inclined in one direction inside the piezoelectric ceramic material. (3) The composite piezoelectric ceramic material according to claim 2, characterized in that it has pores of different shapes instead of pores of the same shape. (4) A composite piezoelectric device characterized in that some or all of the holes of the same shape arranged with a uniform density distribution in one direction inside the piezoelectric ceramic are embedded with a metal body different from the piezoelectric ceramic. ceramic material. (5) The composite piezoelectric ceramic material according to claim 1 or 2, wherein the inner walls of the holes having the same shape have a metal-plated surface. (6) A molded body of a piezoelectric ceramic material having carbon fibers formed in a predetermined pore formation pattern as a pore forming agent is formed, and this molded body is fired to burn off the carbon fibers, thereby forming the pores. A method for producing a composite piezoelectric ceramic material, comprising forming a composite piezoelectric ceramic material having pores with a predetermined shape and density distribution formed by a molding agent.