KR20070031700A - Multilayer Type 1-3 Piezo-Composite Ultrasonic Transducer Using Transverse Mode - Google Patents

Abstract

The present invention provides a piezoelectric multilayer block and a ceramic-polymer 1-3 piezoelectric composite formed by regularly arranging the piezoelectric multilayer blocks in a polymer matrix. The piezoelectric multilayer block of the present invention is particularly manufactured by low temperature co-sintering and co-extrusion, and has a plurality of piezoelectric layers containing piezoelectric material and one less than the number of piezoelectric layers interposed therebetween. A multilayer block constructed and contacting the internal electrode layers on the side of the multilayer block to form a voltage on each piezoelectric layer through the internal electrode layers or by itself being laminated or coated on the upper or lower surface of the multilayer block. It has a unique arrangement and structure including a pair of external electrode layers. Due to this arrangement and structure, the piezoelectric multilayer block of the present invention amplifies the imaginary longitudinal vibration mode in which the lateral vibration mode actually occurring in the longitudinal direction of the piezoelectric layer not only generates high displacement at low voltage but also high foot at low frequency. Have strength. Therefore, the piezoelectric multilayer block and ceramic-polymer 1-3 piezoelectric composite of the present invention can be suitably used as an ultrasonic oscillator.

Piezoelectric Multilayer Block, Piezoelectric Composite, Piezoelectric, Transverse Vibration Mode, Ultrasonic Oscillator, Internal Electrode, Ceramic Polymer Composite

Description

Multilayer Type 1-3 Piezo-Composite Ultrasonic Transducer Using Transverse Mode}

1 shows a piezoelectric multilayer block according to an embodiment of the present invention, (a) shows a piezoelectric layer, an internal electrode layer, and an external electrode layer in a piezoelectric multilayer block for making a virtual d ₃₃ mode using a lateral vibration mode. (B) is a photograph of the piezoelectric multilayer block actually manufactured by the arrangement of (a), and (c) is another arrangement model of the piezoelectric multilayer block.

Figure 2 shows a ceramic-polymer 1-3 piezoelectric composite according to an embodiment of the present invention, (a) is a conceptual diagram of the piezoelectric composite of the present invention, (b) is a photograph of the piezoelectric composite actually manufactured.

3 is a displacement graph according to the voltage of the piezoelectric multilayer block and the piezoelectric composite manufactured according to the embodiment of the present invention, (a) is a displacement graph of the piezoelectric multilayer block of the present invention, (b) is a conductive plate is formed It is a displacement graph of the ceramic-polymer 1-3 piezoelectric composite of the present invention, and (c) is a displacement graph of the ceramic-polymer 1-3 piezoelectric composite of the present invention in which no conductive plate is formed.

Figure 4 is a graph showing the piezoelectric characteristics according to the frequency of the piezoelectric multilayer block according to the present invention, (a) is an impedance characteristic graph, (b) is a displacement graph.

5 is a graph showing piezoelectric characteristics according to the frequency of the piezoelectric composite of the present invention, (a) is an impedance characteristic graph, and (b) is a displacement graph.

6 is a displacement graph in the x, y, z directions when a voltage of 200 Hz and 100 V is applied to the piezoelectric composite of the present invention.

The present invention relates to a piezoelectric multilayer block and ceramic-polymer 1-3 piezoelectric composites in which the blocks are arranged in a polymer resin matrix. More specifically, the plurality of piezoelectric layers, inner electrode layers, and outer electrode layers are arranged in a special arrangement and structure. By forming a piezoelectric multilayer block, it actually uses the lateral vibration mode, but it is converted into a virtual (apparent) longitudinal vibration mode with respect to the external electrode to which the power is supplied, so that a very large displacement can be obtained at low voltage. The present invention relates to a piezoelectric multilayer block suitable for use as an ultrasonic oscillator having a large oscillation force and a ceramic-polymer 1-3 piezoelectric composite including the same.

Current ultrasonic transceivers use ceramic and polymer composites. The piezoelectric material using PZT shows excellent piezoelectric properties in each of the excellent vibration modes (d ₃₃ to 510 pC / N, d ₃₁ to -230 pC / N), but the hydrostatic piezoelectric property (d _h ) has a small disadvantage. Generally hydrostatic piezoelectric properties of the _{PZT (d h = d 33 +} 2 d 31) is substantially 50 pC / N out andoegi because large a d ₃₃ vibration mode in the thickness direction while maintaining a constant by reducing the lateral vibration mode of d ₃₁ An ultrasonic oscillator with d _h is used. In addition, pure PZT ceramics have a very high density of themselves, which causes problems in transmission and reception because the underwater impedance is very different from water. That is, when sound waves reach a medium of low density such as water and a medium of high density, such as ceramics, the absorption rate decreases due to the lack of absorption of the wave in the dense medium. As a result, ceramic-polymer piezoelectric composites have come out to reduce the density of piezoelectric materials to help absorb sound waves and to transmit and receive sound waves with directivity. According to the form, there are 10 types such as 1-3, 2-2, 0-3, 3-3, and the first number is ceramic and the second number is epoxy. For example, in the case of 1-3, a linear piezoelectric fiber of 1 is planted in a polymer matrix of 3, and in the case of 2-2, a plate-like piezoelectric plate is placed in a polymer plate. The most representative of such a ceramic-polymer composite is a piezoelectric ceramic-polymer composite using 1-3 modes. In this case, the piezoelectric elements are arranged in one direction so that d ₃₃ remains constant while d ₃₃ is kept constant, and d ₃₁ mode is suppressed to increase d _h . In addition, due to the low polymer density, the overall impedance was drastically lowered to achieve impedance matching between water and the piezoelectric body to maximize the efficiency of transmission and reception.

However, in the case of the conventional simple piezoelectric polymer composite having no internal electrode, the displacement of the piezoelectric body is limited to the value of the longitudinal piezoelectric constant (d ₃₃ ) or less, so that it is difficult to obtain a large displacement and the driving voltage (> 1000 V) of the piezoelectric body is high. There is this. In addition, because amplification is used at the resonant frequency to obtain a large displacement, the operating frequency is limited to the resonant frequency, so that ultrasonic waves having various frequencies cannot be generated.

Accordingly, the present invention has been made to solve the above problems of the prior art. Accordingly, it is an object of the present invention to overcome the problem that the displacement of the piezoelectric body is limited by the longitudinal piezoelectric constant (d ₃₃ ). The present invention provides a piezoelectric multilayer block having a special arrangement and structure for switching to a longitudinal vibration mode and ceramic-polymer 1-3 piezoelectric composites arranged in a polymer resin matrix. Such piezoelectric composites not only generate very large displacements at low voltages, but can also be ultrasonically oscillated at low frequencies, so that they can be used in ultrasonic oscillators.

It is also an object of the present invention to provide a ceramic-polymer 1-3 piezoelectric composite suitable for mass production because the piezoelectric multilayer block can be efficiently arranged in a polymer resin matrix by forming a rod rather than a plate. .

Other objects and advantages of the present invention will be more clearly understood by the following detailed description of the invention.

The present invention provides a piezoelectric multilayer block. The piezoelectric multilayer block according to the present invention is a multilayer block composed of a plurality of piezoelectric layers including a piezoelectric material and internal electrode layer (s) less than the number of piezoelectric layers interposed therebetween, and in terms of the multilayer block And a pair of external electrode layers in contact with the internal electrode layers to form a voltage on each of the piezoelectric layers through the internal electrode layers or by itself being laminated or coated on the upper or lower surface of the multilayer block. The internal electrode layers formed on the multilayer block may be exposed on the left side of the multilayer block to be in contact with the one external electrode layer but not exposed on the right side of the multilayer block so as not to be in contact with the other external electrode layer. 1 An internal electrode layer and, on the contrary, a second electrode which is exposed at the right side of the multilayer block and is in contact with the external electrode layer formed at the right side but is not exposed at the left side of the multilayer block so as not to be in contact with the external electrode layer formed at the left side. Internal electrode layers are alternately formed, and the external electrode layers are formed to contact the internal electrode layers on one side of the multilayer block such that a voltage is formed between the neighboring internal electrode layers (first and second internal electrode layers). And also the side of the multilayer block Extending from it such that the voltage is formed between them of the extension layer and the internal electrode layer formed on the upper surface or the lower surface.

The present invention also provides a ceramic-polymer 1-3 piezoelectric composite. The piezoelectric composite according to the present invention comprises a plurality of the piezoelectric multilayer blocks (arranged upright in the longitudinal direction of the inner electrode) arranged at predetermined intervals and a polymer resin matrix filled to surround the outside and between the piezoelectric multilayer blocks ( External electrodes on the side surfaces of the piezoelectric multilayer blocks are filled to expose or extension lines from the external electrodes are exposed.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 shows a piezoelectric multilayer block according to an embodiment of the present invention, (a) shows a piezoelectric layer, an internal electrode layer, and an external electrode layer in a piezoelectric multilayer block for making a virtual d ₃₃ mode using a lateral vibration mode. (B) is a photograph of the piezoelectric multilayer block actually manufactured by the arrangement of (a), and (c) is another arrangement model of the piezoelectric multilayer block. Hereinafter, a block in which piezoelectric layers and internal electrode layers are formed in multiple layers will be referred to as a multilayer block for convenience. In addition, a block including external electrode layers will be referred to as a piezoelectric multilayer block for convenience.

1A shows a piezoelectric multilayer block according to one embodiment of the present invention. This piezoelectric multilayer block includes five piezoelectric layers containing a piezoelectric material. Four piezoelectric layers are interposed between the piezoelectric layers, that is, one less than the number of piezoelectric layers. Since the multilayer block can be generally manufactured by successive stacking of the piezoelectric plate and the internal electrode plate by the co-extrusion method, the direction is defined based on the stacking of the plates, although shown in the figure in the upright shape. Explain. That is, the left side of the drawing is defined as the lower surface, and the upper surface of the drawing is defined as the left side. These inner electrode layers contact the outer electrode layers at the sides.

In the present invention, the internal electrode layers are divided into two types. In other words, the first internal electrode layer formed on the left side of the multilayer block (upper surface of the drawing) is in contact with one external electrode layer but is not exposed on the right side of the multilayer block so as not to contact the other external electrode layer. The second internal electrode layer is formed. As shown in FIG. 1A, the two first inner electrode layers are exposed on the left side of the multilayer block (upper surface of the figure) and directly contact one outer electrode layer, but not on the right side of the multilayer block (lower side of the figure). Buried in the piezoelectric layers by a distance, they are not in direct contact with other external electrode layers nor are they electrically connected. The two second inner electrode layers correspond to the outer electrode layer to which the first inner electrode layers do not contact, in a form opposite to that of the first inner electrode layers. These first and second internal electrode layers are alternately arranged in the piezoelectric layers. Thus, as shown in the figure, when power is supplied from the outside to the external electrode layers, a voltage is generated between the neighboring first and second internal electrode layers to form an electric field.

On the other hand, in the piezoelectric multilayer block of the present invention, the outer electrode layers not only directly contact the inner electrode layers on the side of the multilayer block but also have their extension layers extending from the side and formed on the upper or lower surface of the multilayer block. These extension layers are arranged to form a voltage between the internal electrode layers. In FIG. 1A, two first inner electrode layers and two second inner electrode layers are formed, and the outer electrode layers formed on the left side side of the extension layers of the outer electrode layers to form a voltage with the inner electrode layers are extended to the upper surface. The external electrode layer formed on the right side with the extension layer extends to the lower surface and has an extension layer on the lower surface. On the contrary, when the extension layer is formed, it is obvious that a voltage cannot be formed between the internal electrode layers. Meanwhile, as shown in FIG. 1C, in the piezoelectric multilayer block (second of FIG. 1C) having one first internal electrode layer and one second internal electrode layer, the external electrode layer formed on the left side thereof extends to extend the extension layer formed on the lower surface thereof. Have. In the piezoelectric multilayer blocks (first and third in FIG. 1C), in which the number of first internal electrode layers is one larger than the number of second internal electrode layers, the external electrode layers formed on the left side of the first internal electrode layer do not substantially extend to the upper and lower surfaces of the piezoelectric multilayer block. The external electrode layer formed on the side has an extension layer extending to both the upper and lower surfaces. (When the number of the first internal electrode layers is less than the number of the first internal electrode layers, the shape becomes symmetrical to the above. However, this arrangement is consistent with the above. The internal electrode layer and the second internal electrode layer are relative concepts.)

Since the piezoelectric multilayer block of the present invention as described above has not only a piezoelectric layer but also an internal electrode layer, it is preferably manufactured by co-sintering, more preferably in order to use a conductive metal having a low melting point such as silver (Ag). It is prepared by low temperature co-sintering. In addition, the piezoelectric multilayer block of the present invention is preferably manufactured by a co-extrusion method. To this end, it is preferable to use a PZN-PZT composite in which PZN and PZT are complex as the piezoelectric material used in the present invention. In addition, in order to simultaneously form the internal electrode by co-extrusion, it is preferable to form the internal electrode with a mixture of the same material and metal as the components of the piezoelectric material, wherein silver (Ag) is used as the metal at low temperature after co-extrusion. Simultaneous firing is possible.

Prior patent application 2003-0089272 (filed date: December 10, 2003, publication number: 2005-0056331, published date: June 16, 2005) of the main inventors of the present invention is less than 1000 ℃, preferably 900 A PZN-PZT composite with a special composition capable of low temperature co-firing with silver (Ag) at or below C is disclosed. The special composition of such a PZN-PZT composite is that in the composition of the xPZN- (1-x) PZT composite, x is in the range of 0.1 to 0.6, preferably in the range of 0.3 to 0.5, and Pb (Zr _y , In the Ti _1-y ) O ₃ composition, y is in the range of 0.35 to 0.55 or xPb (Zn _1/3 Nb _2/3 ) O _3- (1-x) Pb (Zr _y , Ti of the PZN-PZT composite _{In the 1-y} ) O ₃ composition, x and y are chosen to be the composition of the Morphotropic Phase Boundary (MPB) region of the resulting PZN-PZT complex. Such a special composition of PZN-PZT is preferably required for carrying out co-firing with silver (Ag) in the method of the present invention, and the reason is well described in the above patent publication. Therefore, the patent document is incorporated in the specification of the present invention.

The content of silver in the mixture of PZN-PZT composite and silver (Ag) used as the internal electrode in the present invention is preferably 30 to 80% by weight. When the content of silver is in the above range, there is no big difference from the electrical conductivity of pure silver, and thus it can sufficiently serve as an internal electrode. In the present invention, using the mixture as described above without using pure metal, in particular silver, as an internal electrode, which uses a high residual stress on the surface of the piezoelectric layer due to the large difference in thermal expansion coefficient between the piezoelectric layer and the conductive layer. This is to obtain excellent displacement characteristics and driving force. In addition, it is possible to obtain excellent durability by improving the interlayer adhesion between the piezoelectric layer and the internal electrode by co-extrusion.

Previous patent application No. 2003-0093527 (filed date: December 19, 2003, publication number: 2005-0061910, published date: June 23, 2005) of the main inventor of the present invention is a piezoelectric layer of PZN-PZT composite And an actuator comprising a conductive layer of a PZN-PZT / Ag mixture. Such actuators are manufactured by conventional extrusion and low temperature co-firing as conventional monolithic structures. This application proposes a special composition of piezoelectric materials for low temperature co-firing, complex construction of conductive layers for high residual stresses, and improvement of interlayer adhesion by co-extrusion. Therefore, the said patent document is integrated in the specification of this invention.

The piezoelectric multilayer block of the present invention is preferably manufactured by co-extrusion, first preparing a mixture of a piezoelectric material and a thermoplastic resin for the piezoelectric layer and a mixture of a piezoelectric material / metal mixture and a thermoplastic resin for the internal electrode layer, the mixture The molds are used to make plates of a predetermined thickness. Multilayer blocks are formed by coextruding these plates after the initial feedrods are placed in the desired structure and arrangement. Thereafter, the extruded body is heat-treated to burn off the thermoplastic resin contained in the extruded body and to sinter the piezoelectric material. At this time, the heat treatment process may be carried out in one step, but is usually performed in a first step of slowly heating to about 650 ℃ and a second process of slowly heating to a temperature of about 900 ℃ or less than 1000 ℃. The thermoplastic resin is removed in the first step, and the piezoelectric material is sintered in a PbO atmosphere in the second step.

The piezoelectric multilayer block of the present invention is obtained by forming an external electrode layer on the side and top and bottom surfaces of the sintered multilayer block so as to form a voltage and an electric field required according to the structure and arrangement by power supply from the outside as described above. In this case, as the method of forming the external electrode layer, various methods such as lamination and coating may be used, but most simply, the electrode material is directly applied. Silver (Ag) may be used as a material of the external electrode layer.

When an external power source is connected to the external electrode layers of the piezoelectric multilayer block of the present invention manufactured as described above, voltage is generated between the internal electrode layers and between the internal electrode layers and the external electrode layers to form an electric field in the thickness direction of each piezoelectric layer. This electric field causes lateral vibration in the longitudinal direction of the piezoelectric layers. The present invention uses the displacement by the lateral vibration mode (d ₃₁ ), the lateral vibration in the piezoelectric multilayer block of the present invention is the length of each piezoelectric layer by the voltage between the electrode layers formed opposite to the upper and lower surfaces of each piezoelectric layer As it occurs in the direction, the length of the piezoelectric layer is significantly longer than its thickness and formed in multiple layers to amplify the virtual (apparent) longitudinal vibration mode d ₃₃ . Here, the reason for the virtual longitudinal vibration mode is actually a lateral vibration, but it occurs in the longitudinal direction of the piezoelectric layer, and it is also possible that longitudinal vibration occurs to external electrodes formed on the side of the piezoelectric multilayer block of the present invention. Because it shows the same effect.

The present invention also provides a ceramic-polymer 1-3 piezoelectric composite. Figure 2 shows a ceramic-polymer 1-3 piezoelectric composite according to an embodiment of the present invention, (a) is a conceptual diagram of the piezoelectric composite of the present invention, (b) is a photograph of the piezoelectric composite actually manufactured.

The present invention in which the piezoelectric multilayer blocks obtained as described above are vertically arranged at regular intervals in a frame by standing in the longitudinal direction, and the piezoelectric multilayer blocks vertically arranged in the epoxy resin matrix by filling a polymer resin, for example, an epoxy resin, are regularly arranged. Ceramic-polymer 1-3 of the piezoelectric composite can be obtained. At this time, the external electrodes on the sides of the piezoelectric multilayer blocks are filled to expose or the extension lines from the external electrodes are exposed. It is desirable to form a conductive plate to contact the external electrodes exposed on the surfaces of the exposed external electrodes, that is, the upper and lower surfaces of the 1-3 piezoelectric composite. Such a conductive plate may be formed of TiC-Ni.

The piezoelectric multilayer blocks are formed in the longitudinal direction of the piezoelectric layer to form a thickness of the matrix, so that the exposed external electrodes or conductive plates using the lateral vibration mode generated in the longitudinal direction of the piezoelectric layer as described above are virtual. The amplified displacement due to the longitudinal vibration mode of can be obtained. The principle of amplification is explained below. In addition, in the present invention, the piezoelectric multilayer blocks may be formed in a rod or fiber shape instead of in a plate shape, thereby facilitating the arrangement of the piezoelectric multilayer blocks in manufacturing 1-3 piezoelectric composites, thereby making them suitable for mass production.

Hereinafter, embodiments according to the present invention are presented. Since these embodiments are only intended to present specific examples of the present invention, it should not be understood that the scope of the present invention is limited thereto, and that various other variations and modifications may be possible.

Example

Specimen Manufacturing Method

Piezoelectric multilayer blocks are made using PZN-PZT, PZN-PZT / Ag composite (internal electrode), and Ag (external electrode). PZN-PZT is a material capable of low temperature sintering (<900 ^° C) while having excellent piezoelectric properties. The PZN-PZT / Ag composite is used as a conductive electrode layer. PZN-PZT had a composition of Pb ((Zn _1/3 , Nb _2/3 ) _0.2 (Zr _0.5 , Ti _0.5 ) _0.8 ) O ₃ , and the amount of Ag in the PZN-PZT / Ag composite was 50 wt%.

PZN-PZT composites were prepared by a solid-phase method using a ball mill using high purity PbO, ZrO ₂ , TiO ₂ , Nb ₂ O ₅ , and ZnO as starting materials. The mixture was initially mixed for 12 hours for mixing and the dry powder was calcined at 850 ° C. for 4 hours. The milled powder was again ball milled for 24 hours to grind. Pure PZN-PZT powder was used to prepare the piezoelectric layer of the piezoelectric multilayer block, and 50% PZN-PZT / 50% Ag powder was used to prepare the internal electrode layer. Ethylene ethyl acrylate (EEA 6182; Union Carbide, Danbury, CT) and Acryloid B67 (Rohm and Haas, Philadelphia, PA) were used. The mixture was mixed at 110 ° C. for 2 hours using an internal mixer. Heavy mineral oil (Aldrich Chemical Co. Inc.), stearic acid (Junsei Chemical, Japan) and polyethylene glycol (PEG1000, Acros Organics, NJ, USA) were added to maintain the same viscosity in both layers. The PZN-PZT and PZN-PZT / Ag mixtures were heated at 130 degrees using a 24mm * 24mm square mold to form blocks by applying pressure and making them into 4 mm plates and 1 mm sheets, respectively, and then processing them to arrange the arrangement of FIG. 1A. The initial feedrods were made by joining them and co-extruded back into plates of 2 mm thickness (total height of the layers). The green sheet having such a multilayer structure is regularly cut at 2 mm intervals in the longitudinal direction of the piezoelectric layer by using CNC machining equipment, and 2 mm x 2 mm x 24 mm ( Length) of the multilayer block. If the sheet materials are inflexible when coextrusion, there will be a step between the ends and the center due to the difference in the length of the piezoelectric layer and the inner electrode layer, but in practice both ends are coextruded under high pressure and heated conditions. At this stage, the flexibility of the piezoelectric layer material is generated so that a distribution is made to fill the voids, so that there is no substantial step difference. In order to remove the binder in the PZT block having such a multilayer structure it was heated while slowly raising the temperature to 600 ℃. At the time of sintering, sintering was carried out in a PbO atmosphere in a well covered alumina crucible to prevent PbO volatilization. The sintered specimens were arranged on a regular basis after applying silver electrodes to apply electric fields to the multilayer structure without being energized at the top, bottom and sides, and then filled with epoxy. A silver electrode was applied to the upper and lower portions, respectively, and an electric field of 3 kV / mm was applied in a silicone oil heated to 70 degrees to measure electrical characteristics. Piezoelectric properties were measured with a piezoelectric d33 meter (model ZJ-3D, Institute of Acoustics, Beijing, China). In addition, displacement characteristics according to voltage were measured using a displacement sensor.

Experiment result

A piezoceramic-polymer composite ultrasonic oscillator having a multilayer structure using transverse vibration mode was made. 0.2 (PbZn _1/3 Nb _2/3 ) -0.8 (PbZr _0.5 Ti _0.5 ), which can be sintered at low temperature and show excellent piezoelectric properties, and these piezoelectric materials (d ₃₃ ~ 510 pC / N, d ₃₁ ~ 230 pC / N, KP) 0.5PZN-PZT / 0.5Ag composite, which is capable of co-sintering with ~ 0.65, and KT ~ 1700), was used to make a piezoelectric PZT block having a multilayer structure. 1A shows an arrangement of electrodes for erecting such a PZT block and converting the transverse mode into a longitudinal mode. 1A, the inner electrode of one layer touches the left end and the inner electrode of the immediately lower layer touches the right side so that the anode and the cathode are alternately connected to each layer. When the voltage is applied after the polling by extending the electrodes above and below, the actual lateral vibration occurs, but when it is used upright, the electrodes are virtually applied to both ends, thus becoming the longitudinal mode. 1B is actually manufactured by measuring a PZT block having such a structure.

In the case of the PZT block using the lateral mode, the form is shown in Equation (1).

Apparent d33 ~ d31 x L / d ------ Formula (1)

Where L is the length of the specimen and d is the thickness of each layer. D ₃₃ is amplified by L / d magnification to generate large displacement even at low voltage. In this experiment, the specimens used were arranged at regular intervals using a 5-layer 1.6 mm x 1.6 mm x 16 mm PZT (13 mm with electrode) block, and then filled with epoxy and replaced with L = 13 mm, d ₃₁ = 230 pC / N, d = 0.30 mm, the actual measurement with a value of about 10000 pC / N shows that d ₃₃ is measured at 7000 pC / N for the PZT block. It is thought to be the influence of the inactive part and the internal electrodes on both sides.

Using this PZT block, the model is created regularly and filled with epoxy is shown in Figure 2A. In the figure, hardened TiC-Ni plates were attached to both sides. A photograph of the prepared specimen is shown in FIG. 2B. In case of filling with epoxy, the value of about 4700 pC / N (6010 pC / N when TiC plate is attached on both sides) is measured. This result is more than 10 times larger than the conventional vibrator using the d ₃₃ mode (d ₃₃ ~ 510).

In addition, Figure 3 shows the displacement characteristics with respect to the voltage of the ultrasonic oscillator having this type. Referring to FIG. 3, the displacement of the PZT block having a multilayer structure (FIG. 3A) shows a displacement of about 6 μm at a voltage of 800 V. In the case of the slope d ₃₃ , about 7500 pC / N was measured and the upper and lower plates were attached. In the case of the ceramic-polymer composite (FIG. 3B), a displacement of about 4.5 μm was obtained at 800 V, resulting in a result of d ₃₃ of 5600 pC / N, which is almost identical to the value measured in d ₃₃ meters. In the case of the upper and lower plated ceramic-polymer composites (FIG. 3C), a displacement of about 3.5 μm was generated at 800 V, and d ₃₃ was measured as 4300 pC / N. From these results, it was observed that 1-3 piezoceramic-polymer composites showed smaller displacements than PZT blocks having a multi-layered structure and larger displacements when the upper and lower plates were attached. The reason why the 1-3 composite has a smaller displacement than the PZT block is because the epoxy, which is an inactive part, interferes with the movement of the PZT, resulting in a damping effect. In addition, conductive contact plates make the displacement of epoxy and PZT blocks more efficient, resulting in greater displacement. In order to observe the frequency characteristics of the piezoelectric ceramic-polymer composite, impedance and displacement characteristics were measured with frequency.

4A shows impedance characteristics according to the frequency of the PZT block, which has a minimum value at 92 kHz and a maximum value at 98 kHz. 4B shows a piezoelectric characteristic of 50000 pC / N with a displacement of 500 nm when a voltage of 10 V is applied at a resonant frequency of 92 kHz.

In the case of FIG. 5A, resonance frequencies were observed at 59 kHz and 62 kHz as impedance characteristics of the 1-3 piezoelectric composite. This resonance characteristic is actually using the resonance characteristic of d ₃₁ of the PZT block, and shows the vibration of d ₃₃ when the composite is manufactured. 5B shows the displacement characteristic according to the frequency in the thickness direction. Resonance characteristics are shown at various frequencies, and the main resonance point is observed at 60 kHz. These results are in close agreement with the impedance characteristics. At a frequency of 10 V at this frequency, the displacement is about 270 nm, which is very good with d ₃₃ ~ 27000 pC / N. The displacement is reduced compared to the PZT block, which is also expected to be the damping effect of epoxy. It should be noted that the displacement characteristic according to the frequency shows a displacement of more than 30 nm in almost all regions, and thus it can be used for an ultrasonic oscillator requiring a wide frequency.

For a 1-3 mm piezoelectric composite of 16 mm (thickness) x 16 mm (width) x 16 mm (length), the displacement graph is shown when a voltage of 100 V at 200 Hz is applied. Displacement of about 0.6 um occurred in the Z direction, which corresponds to d ₃₃ ~ 6000 pC / N, which is almost consistent with the previous static method. As a result of the displacements in the X and y directions, the displacements were -0.35 μm and 0.16 μm, respectively, and were measured to have values of d ₃₁ to -3500 pC / N and d ₃₂ to 1600 pC / N. The reason why the displacements in the X and y directions are different is related to the arrangement direction of the PZT blocks. Finally, the hydrostatic piezoelectric constant was measured to have a value of about 4100 pC / N with d _h = d ₃₃ + d ₃₁ + d ₃₂ .

In the case of such a piezoelectric composite, the piezoelectric constant is very large, so that it can be used at a low voltage, and thus there is no frequency limit, thereby generating low frequency ultrasonic waves. It is expected to be a very useful piezoelectric ultrasonic oscillator because it can obtain a lot of information when ultrasonic waves are reflected by using these various frequencies and have excellent clarity that conventional ultrasonic oscillators could not have.

The present invention provides a piezoelectric multilayer block and a ceramic-polymer 1-3 piezoelectric composite formed by regularly arranging the piezoelectric multilayer blocks in a polymer matrix. The piezoelectric multilayer block of the present invention has internal electrodes, in particular manufactured by low temperature co-sintering and co-extrusion, and sandwiched in a unique arrangement and structure between the piezoelectric layers. Due to this arrangement and structure, the piezoelectric multilayer block of the present invention amplifies the imaginary longitudinal vibration mode in which the lateral vibration mode actually occurring in the longitudinal direction of the piezoelectric layer not only generates high displacement at low voltage but also high foot at low frequency. Have strength. Therefore, the piezoelectric multilayer block and ceramic-polymer 1-3 piezoelectric composite of the present invention can be suitably used as an ultrasonic oscillator.

Claims (24)

A multilayer block comprising a plurality of piezoelectric layers including a piezoelectric material and an internal electrode layer (s) one less than the number of piezoelectric layers interposed therebetween, and in contact with the internal electrode layers on the side of the multilayer block A pair of external electrode layers for forming a voltage on each of the piezoelectric layers through electrode layers or by itself being laminated or coated on the upper or lower surface of the multilayer block, The internal electrode layers formed on the multilayer block may be exposed on the left side of the multilayer block to be in contact with the one external electrode layer but not exposed on the right side of the multilayer block so as not to be in contact with the other external electrode layer. 1 An internal electrode layer and, on the contrary, a second electrode which is exposed at the right side of the multilayer block and is in contact with the external electrode layer formed at the right side but is not exposed at the left side of the multilayer block so as not to be in contact with the external electrode layer formed at the left side. Internal electrode layers are alternately formed, and the external electrode layers are formed to contact the internal electrode layers on one side of the multilayer block such that a voltage is formed between the neighboring internal electrode layers (first and second internal electrode layers). And also the side of the multilayer block Extending from, characterized in that such that a voltage is formed between them of the extension layer and the internal electrode layer formed on the upper surface or the lower surface Piezoelectric multilayer block. The method of claim 1, The number of the first internal electrode layers is one greater than the number of the second internal electrode layers, and the external electrode layers contacting the first internal electrode layers are formed on the left side of the multilayer block and contact the second internal electrode layers. The external electrode layer (the external electrode layer opposite to the external electrode layer in contact with the first internal electrode layer when the second internal electrode layer is absent (the number is zero)) is formed on the right side of the multilayer block. The piezoelectric multilayer block which extends from this and is formed also on the upper surface and lower surface of the said multilayer block. The method of claim 1, The number of the first inner electrode layers and the second inner electrode layers are the same, and the outer electrode layers contacting the inner electrode layers are formed on one side of the multilayer block, and extend from the upper surface of the multilayer block. A piezoelectric multilayer block formed on any one of the lower surfaces. The method of claim 1, The piezoelectric material of the piezoelectric layer is a piezoelectric multilayer block, characterized in that the PZN-PZT composite complex PZN and PZT. The method of claim 4, wherein The internal electrode layer is a piezoelectric multilayer block, characterized in that formed of PZN-PZT / Ag, which is a mixture of PZN-PZT composite and Ag. The method of claim 5, The content of Ag in the PZN-PZT / Ag is a piezoelectric multilayer block, characterized in that 30 to 80% by weight. The method of claim 6, The composition of the xPZN- (1-x) PZT composite used for the PZN-PZT / Ag internal electrode layer and / or the PZN-PZT piezoelectric layer, wherein x is in the range of 0.1 to 0.6. The method of claim 7, wherein In the Pb (Zr _y , Ti _1-y ) O ₃ composition of the PZN-PZT composite used for the PZN-PZT / Ag internal electrode layer and / or the PZN-PZT piezoelectric layer, y is in the range of 0.35 to 0.55 A piezoelectric multilayer block characterized by the above-mentioned. The method of claim 6, XPb (Zn _1/3 Nb _2/3 ) O ₃ − (1-x) Pb (Zr _y , Ti of the PZN-PZT composite used for the PZN-PZT / Ag internal electrode layer and / or the PZN-PZT piezoelectric layer _The piezoelectric multilayer block of _1-y ) O ₃ , wherein x and y are selected to be the composition of the Morphotropic Phase Boundary (MPB) region of the resulting PZN-PZT composite. The method of claim 1, The external electrode layer is a piezoelectric multilayer block, characterized in that formed by coating Ag paste. The method of claim 1, The piezoelectric multilayer block is a piezoelectric multilayer block, characterized in that the longitudinal direction of the internal electrode is a rod or fiber shape much longer than the direction perpendicular to it. A plurality of piezoelectric multilayer blocks of claim 1 arranged at a predetermined interval (arranged in the longitudinal direction of the internal electrode) and a polymer resin matrix filled to surround the outside and between the piezoelectric multilayer blocks (sides of the piezoelectric multilayer blocks And filled to expose the external electrodes of the phase or exposed to the extension lines from the external electrodes. The method of claim 12, And a conductive plate formed on the upper and lower surfaces of the piezoelectric composite (ie, the surfaces formed by the external electrodes on the sides of the piezoelectric multilayer blocks) to be in contact with the external electrodes on the sides of the piezoelectric multilayer blocks. Polymer 1-3 piezoelectric composite. The method of claim 13, Ceramic-polymer 1-3 piezoelectric composite, characterized in that the conductive plate is made of TiC-Ni. The method of claim 12, Ceramic-polymer 1-3 piezoelectric composite, characterized in that the polymer resin matrix is made of an epoxy resin. 13. The ceramic-polymer 1-3 piezoelectric composite according to claim 12, wherein the piezoelectric composite is applied to an ultrasonic oscillator. The method of claim 12, The piezoelectric multilayer block is a ceramic-polymer 1-3 piezoelectric composite, characterized in that the longitudinal direction of the inner electrode is a rod (rod) or fiber shape much longer than the direction perpendicular to it. The method of claim 12, The piezoelectric material of the piezoelectric layer of the piezoelectric multilayer block is a ceramic-polymer 1-3 piezoelectric composite, characterized in that the PZN-PZT composite complexed with PZN and PZT. The method of claim 18, And the inner electrode layer of the piezoelectric multilayer block is formed of PZN-PZT / Ag, which is a mixture of PZN-PZT composite and Ag. The method of claim 19, The content of Ag in the PZN-PZT / Ag is 30 to 80% by weight of ceramic-polymer 1-3 piezoelectric composite. The method of claim 20, In the composition of the xPZN- (1-x) PZT composite used in the PZN-PZT / Ag internal electrode layer and / or the PZN-PZT piezoelectric layer, x is in the range of 0.1 to 0.6, wherein the ceramic-polymer 1 -3 piezoelectric composite. The method of claim 21, In the Pb (Zr _y , Ti _{1 -y} ) O ₃ composition of the PZN-PZT composite used for the PZN-PZT / Ag internal electrode layer and / or the PZN-PZT piezoelectric layer, y is in the range of 0.35 to 0.55 Ceramic-polymer 1-3 piezoelectric composite characterized by. The method of claim 20, XPb (Zn _1/3 Nb _2/3 ) O ₃ − (1-x) Pb (Zr _y , Ti of the PZN-PZT composite used for the PZN-PZT / Ag internal electrode layer and / or the PZN-PZT piezoelectric layer _The ceramic-polymer 1-3 piezoelectric composite of _1-y ) O ₃ , wherein x and y are selected to be the composition of the Morphotropic Phase Boundary (MPB) region of the resulting PZN-PZT composite. The method of claim 12, The external electrode layer of the piezoelectric multilayer block is a ceramic-polymer 1-3 piezoelectric composite, characterized in that formed by coating Ag paste.

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