JPH02113799A - Piezoelectric loudspeaker - Google Patents

Abstract

PURPOSE:To contrive low cost, miniaturization, light weight and low energy consumption of a system by directly inputting a digitized sound signal and reproducing an original sound. CONSTITUTION:First to fourth piezoelectric vibrating parts 21-24 are composed so as to be individually driven by respective bit signals of PCM signals. Further, the polarizing degrees of piezoelectric ceramic layers to intervene between divided electrodes 15-18 in rexpective piezoelectric vibrating parts 21-24 and a common electrode 14 are made different, piezoelectric constants are made different, the weighting is executed so as to generate sound pressures corresponding to the weights of respective bit digits, and therefore, by directly inputting respective bit signals to the piezoelectric vibrating parts 21-24, the voice can be reproduced. Thus, the price of a digital audio system can be reduced, and simultaneously, the miniaturization, light weight and low energy consumption of the system can be contrived.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a piezoelectric speaker, and particularly to a digital speaker that can be directly driven by a digitized audio signal such as PCM18.

[Conventional technology]

As shown in FIG. 2, in a digital audio system, an audio signal in the form of an analog signal is modulated into a digital signal by a PCM modulator 1, which is then passed through a transmission, recording, and playback system, and then re-transmitted to a PCM demodulator 2. It was converted into an analog signal and fed into speaker 3. As the speaker 3, various electro-acoustic conversion types such as an electromagnetic type, an electrostatic type, or a piezoelectric type are used.

Digital audio systems convert analog audio signals into digital signals for transmission, recording, and playback, making it possible to achieve extremely high S/N ratios and large Guinamin ranges. .

(Technical Problem to be Solved by the Invention) In conventional digital audio systems, the original sound could not be reproduced unless an analog audio signal was input to the speaker 3.

Therefore, it was necessary to connect a demodulator such as the PCM demodulator 2 having an A/A conversion capability between the transmission/recording/reproduction system and the speaker 3. As a result, very expensive PCM
Since a demodulator is required, the cost of the entire system becomes quite high, and this is a factor that prevents the system from being made smaller, lighter, and less power consuming.

An object of the present invention is to provide a digital speaker that can directly input a digitized audio signal and reproduce the original sound.

[Means for Solving Technical Problems] The present invention is a speaker that utilizes bending vibration due to piezoelectric effect, and allows direct driving by digitized audio signals. In the speaker of the present invention,
A piezoelectric vibrating element is attached to an elastic diaphragm. This piezoelectric vibrating element is made of piezoelectric ceramics with electrodes formed on both main surfaces, and has a plurality of piezoelectric vibrating parts that are driven for each bit signal of a digital input signal. Further, the plural piezoelectric vibrating parts are characterized in that the piezoelectric constants d of the plurality of piezoelectric vibrating parts are made to be different from each other so that the plurality of piezoelectric vibrating parts generate sound pressure corresponding to the weight of each bit digit of the digital input signal. .

[Effect]

The digitized audio signal is in the form of a binary code, and in the present invention, each time each bit signal of this binary code is input to each piezoelectric vibrating unit, a plurality of piezoelectric vibrating units are activated for each bit code. Driven. The piezoelectric constants d of the piezoelectric vibrating parts are made to be different from each other, so that the piezoelectric vibrating parts generate a sound pressure corresponding to the weight of each bit.

Therefore, the plurality of piezoelectric vibrating parts are directly driven by the digital input signal, and as a result, the PAM wave and, in turn, the waveform of the original sound are reproduced.

[Explanation of Examples]

1 and 3 are a plan view and a sectional view taken along line III-I [I] of a piezoelectric speaker according to an embodiment of the present invention.

This embodiment is applied to a digital speaker that is directly driven by a 5-bit PCM signal.

A disk-shaped piezoelectric vibrating element 12 is pasted onto a disk-shaped elastic diaphragm 1=41 made of a metal material such as brass using a conductive adhesive (not shown). This piezoelectric vibrating element 12 is made of disk-shaped piezoelectric ceramic, has a common electrode 14 on the lower surface of the plate 13, and has sector-shaped first to fourth divided electrodes 15 to 13 on the upper surface.
It has a structure in which 18 is formed. In the region where the first to fourth divided electrodes 15 to 18 are formed, the common electrode 14 and the piezoelectric ceramic layer interposed between each of the divided electrodes 15 to 18 and the common electrode 14 First to fourth piezoelectric vibrating parts 21 to 24 are configured.

The first to fourth piezoelectric vibrating parts 21 to 24 are as described below.
It is configured to be driven individually by each focus signal of the PCM signal.

Furthermore, the divided electrodes 15 in each piezoelectric vibrating section 21 to 24
, 16, 17 or 18 and the common electrode 14, the polarization levels of the piezoelectric ceramic layers are made different, and the piezoelectric constant d is made different.

The reason why the piezoelectric constant d is different is that, as described later,
Each piezoelectric vibrating part 21~ for each focus digit of the digital input signal
This is because when 24 is driven, it is possible to generate a sound pressure corresponding to the weight of the bit digit. That is, the piezoelectric constants d of the plurality of piezoelectric vibrating parts 21 to 24 are made different to the extent that it is possible to generate sound pressure according to the weight of the bit digit.

In this example, specifically, the polarization of the piezoelectric ceramic layer in each of the piezoelectric vibrating parts 21 to 24 is performed under the following conditions.

However, the polarization described in item 1 was carried out by treatment at a temperature of 60° C. for 30 minutes.

As described above, in this embodiment, the ratio of the piezoelectric constants d31 of the first to fourth piezoelectric vibrating parts 21 to 24 is 38:75.
:150 :300=2° +2' +22 :2
It is said to be 3.

When driving, as shown in FIG.
A lead wire 31 is connected to. The lead wire 31 is electrically connected to the common electrode 14 via the elastic diaphragm 11 and a conductive adhesive (not shown). Further, the lead wires 32 to 35 are connected to the first to fourth piezoelectric vibrating parts 21, respectively.
-24 are electrically connected to the electrodes 15-18 on the upper surface.

Note that the elastic diaphragm 11 may be made of an insulating material,
Alternatively, the piezoelectric vibrating element 12 may be attached to the elastic diaphragm 11 using an insulating adhesive such as epoxy resin, and in that case, electrical extraction may be performed directly from the common electrode 14.

Next, the operation of the above embodiment will be explained. As shown in FIG. 4, of the 5-hint PCM input signal, the MSB (sign focus) of the most significant bit digit is inverted by the inhark 36 and inputted to the common electrode 14 from the lead wire 31. On the other hand, the electrode 1 on the second side of each piezoelectric vibrating section 21 to 24
5 to 18, bit signals of each bit digit (in order from the lower bit digit, each focus signal of LSB, bit 2, bit 3, and bit 4) are inputted from lead wires 32 to 35.

The first to fourth piezoelectric vibrating parts 21 to 24 have different piezoelectric constants (131) so that the sound pressure ratio when driven alone is 2° +2':22:2'. By inputting each focus signal, the piezoelectric vibrating sections 21 to 24 generate a sound pressure corresponding to the weight of the bit digit.

Therefore, by combining the sound pressures generated by the first to fourth piezoelectric vibrating sections 21 to 24, a digitized audio signal is converted into a sound wave.

However, as it is, the waveform of the reproduced sound is P A
This becomes an M wave. Therefore, in order to bring the sound closer to the original sound, it is preferable to combine a low-pass filter that passes a band of 1/2 or less of the summing frequency, or to place an acoustic low-pass filter in front of the speaker. That is, by combining such low-pass filters or acoustic low-pass filters, the PAM wave can be made into a continuous sound pressure waveform.

FIGS. 5(a) to 5(d) are plan views showing modified examples of the divided electrodes. As shown in FIG. 5(a), divided electrodes 15a to 18a having different shapes and sizes may be formed to form first to fourth piezoelectric vibrating parts having different areas.

Further, as shown in FIG. 5(b), a rectangular plate-shaped elastic diaphragm 11. The first to fourth piezoelectric vibrating parts may be configured by forming rectangular divided electrodes 15b to 18b on a.

Furthermore, as shown in FIG.
．． The first to fourth piezoelectric vibrating parts may be formed by forming 5c to 18c. That is, the piezoelectric vibrating element of the present invention does not necessarily have to be constructed integrally as in the embodiment shown in FIG. 1, but may be constructed by individually attaching a plurality of piezoelectric vibrating elements to an elastic diaphragm.

Further, as shown in FIG. 5(d), a disc-shaped divided electrode 1.56 is formed at the center of the disc-shaped piezoelectric ceramic plate attached to the elastic diaphragm 11, and a circular ring-shaped electrode is formed concentrically around the disc-shaped divided electrode 1.56. By forming the divided electrodes 16d to 18d, the first
- It is good also as a structure which arrange|positions the 4th piezoelectric vibrating part.

FIG. 6 is a sectional view showing a modification of the embodiment of FIG. 1.

Here, a piezoelectric vibrating element 12 having the same structure as the piezoelectric vibrating element (2) of the embodiment in FIG. 1 is also attached to the lower surface side of the elastic diaphragm 11. That is, it has a bimorph structure in which piezoelectric vibrating elements are attached to both sides of an elastic diaphragm. In this structure, the corresponding divided electrodes on the upper and lower surfaces are connected to each other and the corresponding bit signals are input to each piezoelectric vibrating section as shown in FIG. 4, thereby allowing the piezoelectric vibrating section to operate in the same manner.

Furthermore, in the above embodiment, the 5-bit PCM signal is
Although the case of acoustic conversion has been described, the present invention can also be applied to the case of reproducing digital signals of other bit numbers such as 8 bits and 16 bits. In that case, just by changing the number and weighting of piezoelectric vibrating parts according to the number of bits, the digitized audio signal can be
Can be converted directly to audio.

Note that the present invention can also be applied when converting a digital signal using a modulation method other than PCM modulation into audio.

〔Effect of the invention〕

As shown in FIG. 17.4=J so as to generate the sound, the sound can be reproduced by directly inputting each via signal to the plurality of piezoelectric vibrating parts. Therefore, high-quality reproduced sound can be obtained by simply connecting directly to an amplifier that outputs a digital signal, and an expensive PCM demodulator can be omitted. Therefore, the price of the digital audio system can be effectively reduced, and the system can be made smaller, lighter, and less consuming.

Furthermore, since it has a relatively simple structure in which multiple piezoelectric vibrating parts are arranged on an elastic diaphragm and the piezoelectric constants of the parts are different from each other, it is excellent in mass production, therefore, it is low cost and reliable. This makes it possible to realize digital speakers with excellent performance.

[Brief explanation of drawings]

FIG. 1 is a plan view of an embodiment of the present invention, FIG. 2 is a block diagram schematically showing the J digital audio system, FIG. 3 is a sectional view taken along line II-III in FIG. 1, and FIG. is a block diagram for explaining the method of driving the embodiment shown in FIG. 1, FIGS. 5(a) to 5(d) are plan views showing modified examples of the divided electrode, and FIG. It is a sectional view for explaining an example. In the figure, 1] is an elastic diaphragm, 12 is a piezoelectric vibrating element,
14 is a common electrode, 15 to 18 are divided electrodes, and 21 to 24 are first to fourth piezoelectric vibrating parts.

Claims (1)

[Claims] A speaker that utilizes bending vibration caused by piezoelectric effect, comprising an elastic diaphragm and piezoelectric ceramics with electrodes formed on both principal surfaces,
It has a plurality of piezoelectric vibrating parts that are driven for each bit signal of the digital input signal, and a piezoelectric vibrating element pasted on the elastic diaphragm, and each of the piezoelectric vibrating parts drives each bit of the digital input signal. A piezoelectric speaker, characterized in that the piezoelectric constants d of the plurality of piezoelectric vibrating parts are made different from each other so as to generate sound pressure corresponding to the weight of the digit.