WO1995021463A1 - Piezoelectric transformer - Google Patents

Abstract

A piezoelectric transformer which can produce a high-voltage and large-current and has a low output impedance. Deterioration of the characteristics and breakage due to heat do not easily occur even when its thickness is an thin as 2.5 mm. The transformer is a rectangular plate having a thickness of 0.5-2.5 mm and made of a piezoelectric ceramic provided with a thickness-direction polarized section which is formed by polarizing part of the rectangular plate in the thickness direction and functions as an input section and a length-direction polarized section which is formed by polarizing the other part of the rectangular plate in the length direction and functions as an output section. The ratio of the length to the width of the rectangular plate is 0.2-0.6 so that the secondary resonance frequency generated when the transformer oscillates in the length direction while the output section is open is almost equal to the primary resonance frequency generated when the transformer oscillates in the width direction.

Description

 Specification

Title of invention

 Piezoelectric transformer

Technical field

 The present invention relates generally to a piezoelectric transformer composed of piezoelectric ceramics, and more particularly to a lighting device for a discharge lamp such as a cold cathode discharge lamp. The present invention relates to a piezoelectric transformer suitable for use, which can convert an electric signal into a mechanical displacement, and can convert a mechanical displacement into an electric signal.

Background art

 Recently, so-called laptops and computers, such as small portable personal computers and word processors. — Electronic devices of the top-to-bottom type are rapidly becoming widespread. On the other hand, in these electronic devices, a liquid crystal display device is used as a display unit, and a light source for the illumination is used. To drive a cold-cathode lamp, an electric signal consisting of piezoelectric ceramics can be converted into a mechanical displacement, and a mechanical displacement can be converted into an electric signal. It is also well known that lighting circuits containing piezoelectric transformers can be used.

 Conventionally known piezoelectric transformers, as mentioned above, aim to obtain a high voltage at the output side, and excite the resonant mode to be driven simply. For this reason, the ratio of the length to the width in a shape usually formed into a rectangular flat plate is set to 0.2 or less. This was to prevent unnecessary resonance from occurring when other resonance modes were coupled, thereby reducing the efficiency of electro-mechanical conversion.

On the other hand, when turning on a cold cathode discharge lamp or a light source for a strobe, As the output, a high voltage and at least an output current of about 1 to 1 OmA are required.

 However, in the conventional piezoelectric transformer, when the output current value is increased, the output voltage value is reduced, and the light source for a cold cathode discharge lamp is used. It was not possible to emit light with low brightness, and was unsuitable for practical use. In order to illuminate a cold-cathode discharge lamp or the like with sufficiently high luminance, the output of the compression transformer must be increased in power, that is, a high voltage and a large voltage must be applied between its output terminals. It would be nice to input a large amount of electric power to the piezoelectric transformer so that current could be obtained at the same time. What has not been done is the current situation.

 In addition, when the conventional piezoelectric transformer has a thickness of 2.5 mm or less, it is structurally weak, has defects and deteriorates characteristics, cannot withstand high-power driving, and generates heat. As a result, there was a danger of destruction, and for this reason, those smaller than 2.5 mm were not practically used.

 Furthermore, in a conventional piezoelectric transformer, the output impedance is used as a high impedance, and the output impedance between the subsequent actual load and the output impedance is high. Impedance matching has not been considered at all. O

In other words, conventional piezoelectric transformers have been developed mainly as fly-through transformers for cathode ray tubes (CRTs) such as televisions. The equivalent impedance of these actual loads is about 10 to 70 ΜΩ, and the output impedance of the piezoelectric transformer is about several hundred kΩ. Even if it is high, it will be almost one or two orders of magnitude lower than the actual load, and it is practically necessary to match both impedances. Na- In fact, no consideration has been given to the impedance matching between the piezoelectric transformer and the actual load. On the other hand, the input impedance presumed to be used for lighting devices such as cold-cathode discharge lamp light sources is extremely high, and it is difficult to say that the input impedance is extremely high. Assuming that the load is driven, if the output impedance of the piezoelectric transformer is higher than the input impedance of the actual load to be driven, the load It is considered that the characteristics of the piezoelectric transformer are affected by the influence of the piezoelectric transformer, the characteristics are degraded, the original characteristics are not exhibited, and it is impossible to drive the load. Ching can no longer be ignored.

Disclosure of invention

 The present invention is composed of a piezoelectric ceramic having a lengthwise polarization part and a thickness direction polarization part, and has a resonance frequency in a longitudinal vibration mode and a resonance frequency in a width vibration mode. By matching, a piezoelectric transformer that can output both a high voltage and a large output current by supplying a driving energy having the resonance frequency is provided. In order to obtain a rectangular flat plate having a thickness of 0.5 mm to 2.5 mm, a part of the rectangular flat plate has a thickness of 0.5 mm to 2.5 mm. It functions as an input part formed by polarizing in the direction, and an output part formed by polarizing the other part of the above-mentioned rectangular flat plate in the longitudinal direction. It consists of a piezoelectric ceramic with a longitudinal polarization section, By setting the dimension ratio between the length direction and the width direction of the shape to 0.2 to 0.6, the secondary resonance frequency and width of the longitudinal vibration mode when the output unit is open It is intended to provide a piezoelectric trans- lator in which the primary resonance frequency of the directional vibration form is substantially matched.

Further, the present invention provides a cold cathode discharge lamp strobe light source for improving the efficiency. Either the input section or the output section, taking into account the electrical impedance matching between the piezoelectric transformer and the actual load in order to emit light The object is to reduce the output impedance of the piezoelectric trans- former by controlling the resonance characteristics of the piezoelectric transducer. It is formed into a rectangular flat plate having a thickness of up to 2.5 mm, and at the same time, it functions as an input part formed by polarizing a part of the rectangular flat plate in the thickness direction. A piezoelectric ceramic comprising: a thickness direction polarizing portion; and a length direction polarizing portion that functions as an output portion formed by polarizing the other portion of the rectangular flat plate in the length direction. The dimensional ratio of the rectangular plate in the length direction and the width direction is set to 0.2 to 0.6. The resonance frequency of the secondary resonance mode in the longitudinal vibration mode in the open state of the output section is set to the resonance frequency of the appropriate resonance mode in the appropriate vibration mode in the open state of the input section. This is to provide a piezoelectric transformer which approximately matches the above.

Further, the present invention is composed of a piezoelectric ceramic having a lengthwise polarization part and a thickness direction polarization part, and has a resonance frequency of a longitudinal vibration mode and a resonance frequency of a width vibration mode. Another object of the present invention is to obtain a piezoelectric transformer capable of outputting a higher voltage and a larger output current by superposing a plurality of piezoelectric transformers having substantially the same frequency. So 0.5 mn! Not only is it formed into a rectangular flat plate having a thickness of about 2.5 mm, it also functions as an input part formed by polarizing a part of the rectangular flat plate in the thickness direction. Piezoelectric ceramic having a thickness direction polarizing portion and a length direction polarizing portion that functions as an output portion formed by polarizing the other portion of the rectangular flat plate in the length direction. The dimension ratio of the rectangular flat plate in the length direction and the width direction is set to 0.2 to 0.6. A plurality of piezoelectric transformers in which the secondary resonance frequency in the longitudinal vibration mode and the primary resonance frequency in the width direction vibration mode in the open state of the output section are approximately the same in the thickness direction It is intended to provide a piezoelectric trans- formed by superposing the same polarities of the polarization parts so as to face each other.

 Further, the present invention further comprises a plurality of pairs of piezoelectric transformers which are superposed such that the same poles of the thickness direction polarized portions are opposed to each other, and are further superposed. This is to provide a piezoelectric transformer that can obtain both voltage and large current outputs at the same time.

BRIEF DESCRIPTION OF THE FIGURES

 FIG. 1 is a perspective view showing one embodiment of a piezoelectric transformer according to the present invention.

 FIG. 2 is a resonance characteristic diagram of the embodiment of the piezoelectric transformer according to the present invention shown in FIG. 1 when the output section is open.

 FIG. 3 is a resonance characteristic diagram of the embodiment of the piezoelectric transformer according to the present invention shown in FIG. 1 when the input section is open.

 FIG. 4 is a perspective view showing another embodiment of the piezoelectric transformer according to the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

 FIG. 1 is a perspective view showing one embodiment of a piezoelectric transformer according to the present invention.

The piezoelectric transformer 1 of the present invention is composed of a piezoelectric ceramic having a thickness-polarized portion and a length-polarized portion. Is a lower electrode. Polarization is performed by applying a high voltage in the thickness direction of the piezoelectric ceramic between both electrodes 1a and 1b. . 1c is a strip-shaped electrode serving as the earth side, for example, of the longitudinally polarized portion, and Id is an electrode provided on the end face of the piezoelectric ceramics. Polarization is performed by applying a high voltage between both electrodes 1c and 1d.

 Describing the operation of this piezoelectric transformer, a drive voltage from a drive unit (not shown) is applied between a pair of thickness direction electrodes la and lb, and the output is applied. The cold cathode discharge lamp and the like are turned on by the output taken out between the force electrodes 1c and 1d. Since this is well known, detailed description is omitted.

 As shown in FIG. 1, the piezoelectric transformer 1 according to the present invention is formed in a rectangular plate shape, and has a thickness of 0.5 to 2.5 mm. The ratio WZL of the widthwise dimension W to the lengthwise dimension L is in the range of 0.2 to 0.6, and the ratio of the lengthwise dimension L to the thickness is large. The ratio LZT of T is configured to be 10 to 100, and more preferably, the ratio WZL is approximately 0.5. The ratio LZT is configured to be approximately 35.

Next, various characteristics including the resonance characteristics of the piezoelectric transformer 1 according to the present invention will be described. FIG. 2 is a resonance characteristic diagram of the embodiment of the piezoelectric transformer according to the present invention shown in FIG. 1 when the output section is open. That is, when driving voltages of various frequencies are applied between both electrodes la and lb of the thickness direction polarized portion of the piezoelectric transformer 1 with the output portion opened. This is an example of such resonance characteristics. In Fig. 2, A1 is the resonance point in the primary resonance mode in the longitudinal vibration mode, and A2 is the resonance point in the secondary resonance mode. And A5 indicate the resonance points in the same tertiary resonance mode. The resonance point A 2 in the secondary resonance mode will be described in more detail. Thus, A 4 is the anti-resonance point of the secondary resonance mode, and between the resonance point A 2 and the anti-resonance point A 4, the widthwise vibration of the piezoelectric transformer 1 shown in FIG. The resonance point in the first-order resonance mode appears as the sub-resonance point A3. This is because the width of the piezoelectric transformer 1 shown in Fig. 1 is configured to be approximately half the length in the longitudinal direction, and the vicinity of the resonance point A2 is obtained. This appears as the sub-resonance point A 3 in FIG.

 Further, when the width is adjusted to an optimum length within the range described above, the sub-resonance point A 3 approaches the resonance point A 2 in the secondary resonance mode. Eventually, they become almost one and one resonance system. At this time, the dynamic range of the resonance characteristics is increased to about 1.5 to 2 times, and the input impedance at the resonance point A2 is increased. Also has a low impedance, so that a large current can be input.

 As a result, the driving energy at the frequency that forms the one resonance system is provided, and the piezoelectric transformer 1 according to the present invention has an output voltage of, for example, one. For example, even at a high voltage of 1 to 10 kV, a large current of 1 to 1 OmA can be output as an output current, and the output power can be increased. This will be.

 As for the input, conventional piezotransformers can only input tens or hundreds of milliamps with an input voltage of 12 V. However, it has been confirmed that the piezoelectric transformer 1 according to the present invention can input a large current of several amperes.

As described above, when the node of the piezoelectric trans- former 1 according to the present invention, which was able to increase the output voltage, was examined. The resonance frequency of the secondary resonance mode in the longitudinal vibration mode and the resonance frequency of the primary resonance mode in the width vibration mode are approximately the same. Since the vibration mode is formed in an inclined manner, it is confirmed that an elliptical node that is elongated in the length direction is formed at the center of the vibration mode. It has been recognized.

 In addition, although this is probably due to the above-mentioned long elliptical node, even in the relatively thin thickness range as described above, the thickness direction polarization section and the length direction polarization section may be used. The mechanical strength in the region showing the maximum stress near the boundary of the part is improved, and the fracture is not easily generated in such a region, and the characteristics are not deteriorated and heat is not generated. Everything has been confirmed

 FIG. 3 is a resonance characteristic diagram of the embodiment of the piezoelectric transformer according to the present invention shown in FIG. 1 when the input section is open. That is, when voltages of various frequencies are applied between the two electrodes 1c and Id of the longitudinally polarized portion of the piezoelectric transformer 1 with the input portion opened. This is an example of the resonance characteristics.

 In Fig. 3, B1 is the resonance point in the primary resonance mode in the longitudinal direction, and B2 is the resonance point in the secondary resonance mode. The output impedance at the resonance point B 2 was about 3 kQ. B 3 indicates a characteristic point when a voltage having a frequency that generates the resonance point A 2 of the secondary resonance mode described with reference to FIG. 2 is applied, and this characteristic point B The output impedance at 3 showed about 300 kΩ. B5 indicates the resonance point in the third resonance mode in the longitudinal vibration mode, and B4 indicates the resonance point in the primary resonance mode in the width vibration mode. The output impedance at the resonance point B4 was about 20 kΩ.

The piezoelectric trans- former according to the present invention is, as described above, a cold cathode discharger. Lighting devices such as electric lamps, that is, driving a real load with low input impedance is assumed. In this case, the output impedance of the piezoelectric transformer is assumed. Is a problem, and specifically, it is hoped that the output impedance will be reduced.

 For example, the resonance frequency at which the characteristic point B 3 in the resonance characteristics shown in FIG. 3, that is, the resonance frequency at which the resonance point A 2 described in FIG. Fig. 3 showing the output impedance of about 20 with the length dimension of the lance adjusted in the decreasing direction within the range described above. Approaching the resonance point B4 or further reducing the output impedance, the dimensions in the longitudinal direction of the piezoelectric Adjusting in the direction of increasing the value within the range, the output impedance of about 3 kΩ is approached, and the resonance point B 2 in FIG. 3 is approached. As a result, the output impedance of the piezoelectric transformer can be sufficiently reduced. In other words, the piezoelectric transformer is driven by a driving energy having a frequency capable of obtaining the above resonance point B4 or B2. As a result, it is possible to obtain a piezoelectric transducer having a sufficiently reduced output impedance. The input section may be adjusted in the same way.

 If the output impedance can be reduced as described above, the input impedance of the actual load and the output impedance of the piezoelectric transformer will be practically reduced. It is possible to supply a large amount of electric power, and to generate less heat, and to prolong the service life. In addition, the drive circuit configuration can be simplified.

FIG. 4 is a perspective view showing another embodiment of the piezoelectric transformer according to the present invention. The piezoelectric transformer 10 in this embodiment is for parallel driving. FIG. 4 shows an example of the configuration of the piezoelectric transformer. As is apparent from FIG. 4, a plurality of piezoelectric transformers 1 according to the present invention shown in FIG. In this case, two new piezoelectric transformers 10 are constructed by electrically connecting them in parallel. That is, this is an example in which the piezoelectric transformer 1 described above is used as a piezoelectric transformer element that forms a part of the piezoelectric transformer 10.

 The piezoelectric transformer 10 uses a thickness-polarized portion provided with the upper and lower electrodes 10a, 10b and 10a ', 10b' as an input portion, and uses a strip-shaped electrode. Adjacent longitudinally polarized sections provided with 10c, 10c 'and electrodes 10d, 10d' are used as output sections.

 As shown in FIG. 4, a plurality of piezoelectric transducers 1 according to the present invention are used as piezoelectric transducer elements, for example, two piezoelectric transducers. If a single piezoelectric transformer 10 is formed by sticking them so as to face each other, they become structurally strong, which has conventionally occurred during driving with high power. It was confirmed that the squealing phenomenon was alleviated and eliminated, and that the input current and the output voltage were both increased by two to three times compared to the previous piezoelectric transformer 1. is made of .

In addition, when two pairs of the piezoelectric transformers 10 for parallel driving shown in Fig. 4 are superimposed, the input current and the output voltage are 4 to 4 compared to the previous piezoelectric transformer 1. It can be confirmed that the input current and the output voltage are increased by 6 to 9 times as compared with the previous piezoelectric transformer 1 when superimposed. ing . That is, the piezoelectric transformer 10 for parallel driving shown in FIG. 4 is laminated to form a part of a piezoelectric transformer formed by superimposing the piezoelectric transformers. By controlling the number of superimposed piezoelectric transducers 10 Output can be obtained.

 Industrial applicability

 The present invention comprises an input section polarized in the thickness direction and an output section polarized in the length direction, and the 0.5 mn! Secondary resonance in the open-ended longitudinal vibration mode of the above output section in a piezoelectric ceramics formed into a rectangular flat plate shape with a thickness of ~ 2.5 mm The resonance frequency of the mode and the resonance frequency of the primary resonance mode in the vibration mode in the width direction are set such that the dimensional ratio between the length direction and the width direction of the rectangular plate shape is 0.2 to 0.6. Thus, the piezoelectric transformer is configured so as to substantially match.

 With the above configuration, the piezoelectric transformer is driven by the driving energy having the resonance frequency substantially matched to the above, so that the piezoelectric transformer is driven. A high voltage of 1 to 10 1 ^ ¥ and a large current of 1 to 10 mA can be output simultaneously from the lance.

As described above, the piezoelectric transformer according to the present invention is driven by a driving energy having a resonance frequency substantially matched as described above. A long elliptical node can be formed at the center of the piezo, and as a result, the polarization in the thickness direction and the polarization in the length direction are the same as in a conventional piezoelectric transformer. It is not easily broken in the area where the stress is near the boundary and shows the maximum value. That is, the elongated elliptical node is formed at the center of the piezoelectric transformer, which is usually near the boundary between the thickness direction polarization portion and the length direction polarization portion. Therefore, the strength against vibration near the boundary is improved, so that even if the thickness of the piezoelectric transformer is 2.5 mm or less, it is still the same as the conventional piezoelectric transformer. In addition, it is not easily broken near the above boundary, It doesn't heat up and cause destruction. It has been confirmed that the stiffness is strong up to a thickness of about 0.5 mm, and that it is possible to continuously drive an actual load.

 In addition, by adjusting the resonance characteristics of either the input section or the output section in consideration of various resonance points, the output impedance of the piezoelectric transformer is adjusted. The load impedance, which effectively reduces the input impedance of the actual load and the output impedance of the voltage transformer. Matching can be realized, and as a result, the characteristics of the piezoelectric transformer are not degraded due to the effect of the input impedance of the actual load. However, it has the effect that the energy transmission efficiency can be greatly improved.

 In addition, a plurality of piezoelectric transformers are bonded together with the same polarity of the thickness-polarized portion facing each other, and a plurality of the bonded bodies are further stacked. As a result, the bending vibration component can be suppressed, which has the effect of realizing high power. In addition, one piezoelectric transformer can increase the insufficient mechanical strength and suppress unnecessary vibration, thereby minimizing heat generation, and consequently increasing power consumption. It also has the effect of eliminating the noise that has been generated as it becomes more sophisticated.

Claims

• The scope of the claims

 1.0.5 πιπ! The thickness is formed into a rectangular flat plate having a thickness of about 2.5 mm, and also functions as an input unit formed by polarizing a part of the rectangular flat plate in the thickness direction. Directional polarization part and before

5 From the piezoelectric ceramics provided with a longitudinally polarized portion that functions as an output portion formed by polarizing the other portion of the rectangular flat plate in the longitudinal direction. In other words, by setting the dimensional ratio of the rectangular flat plate in the length direction and the width direction to be 0.2 to 0.6, the lengthwise vibration mode in the open state of the output section can be achieved. Piezoelectric transformer whose primary resonance frequency and primary resonance frequency of the zero-width vibration mode are almost matched.

 Once

 The input portion is formed into a rectangular plate shape having a thickness of 2.0 mm to 2.5 mm, and is formed by polarizing a part of the rectangular plate shape in the thickness direction. The thickness-polarized portion that functions as an output portion formed by polarizing the other portion of the rectangular plate shape in the length direction, and a length-polarized portion that functions as an output portion formed by polarizing the other portion of the rectangular plate shape in the length direction. The output unit is constituted by a piezoelectric ceramic provided with a dimensional ratio of 0.2 to 0.6 in the length direction and the width direction of the rectangular flat plate. The secondary resonance frequency 0 of the length direction vibration mode in the open state of the input section is approximately equal to the resonance frequency of the appropriate resonance mode of the appropriate vibration mode in the open state of the input section. Piezotransform.

3. The claim 2 wherein the resonant frequency of the resonant mode of the vibration mode is the secondary resonant frequency of the longitudinal vibration mode or the primary resonant frequency of the width vibration mode. The voltage transformer described in 5. •

4.0.5 mn! It is formed into a rectangular flat plate having a thickness of up to 2.5 ram, and also functions as an input unit formed by polarizing a part of the rectangular flat plate in the thickness direction. A piezoelectric element having a thickness-polarized part and a length-polarized part that functions as an output part formed by polarizing the other part of the rectangular flat plate in the longitudinal direction. When the output section is open, the rectangular flat plate has a length-to-width dimension ratio of 0.2 to 0.6. A plurality of piezoelectric transducer elements in which the secondary resonance frequency of the longitudinal vibration mode and the primary resonance frequency of the width vibration mode substantially match each other are connected to the same pole of the thickness-polarized portion. Piezoelectric transducers that are bonded so that they face each other.

 An input part formed by forming a rectangular plate having a thickness of 5.5 ram to 2.5 mm and polarizing a part of the rectangular plate in the thickness direction. The thickness direction polarizing portion that functions as a vertical polarization portion that functions as an output portion formed by polarizing the other portion of the rectangular plate shape in the length direction. The output portion is opened by setting the dimensional ratio of the rectangular flat plate in the length direction and the width direction to 0.2 to 0.6. A piezoelectric transformer in which the secondary resonance frequency of the longitudinal vibration mode in the prone state and the primary resonance frequency of the width 0 direction vibration mode are approximately the same.

 A piezoelectric transducer is formed by laminating a plurality of bonded elements such that a plurality of sensing elements are bonded so that the same polarities of the above-mentioned polarized portions in the thickness direction face each other. . Five