JPS6113800A - Piezoelectric buzzer - Google Patents

Abstract

PURPOSE:To obtain a small-sized and high sound pressure under low frequency by setting cavity frequency in the vicinity of higher order oscillation frequency of a composite material and either of higher harmonic frequencies of a pulse. CONSTITUTION:A piezoelectric buzzer 11 includes a composite body 13, which includes a diaphragm 15. Its basic oscillation frequency is selected to a using frequency, for instance, 1kHz. A cavity 31 of the buzzer 11 is formed so as to resonate an oscillation sound of the diaphragm 15, and its cavity frequency is set to 3kHz which is a higher harmonic component of 1kHz drive pulse of a drive circuit 33. As a result, the magnitude of the cavity 31 is smaller, compared with an object for resonating at 1kHz frequency, which causes the buzzer 11 to be smaller. Furthermore, in respect of frequency of audible sounds, not only a sound of fundamental tone of 1kHz but also a sound at 3kHz ring simultaneously, and sound pressure can be higher accordingly.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) This invention relates to piezoelectric buzzers, and more particularly to piezoelectric buzzers used, for example, at relatively low frequencies.

(Description of Prior Art) ゛Conventionally, this type of piezoelectric buzzer
As shown in Publication No. 719, it includes a composite of a vibrating body and a piezoelectric element, and resonates with the □ vibration of this composite,
A cavity is formed in the outer case. In order to increase the sound pressure of such a piezoelectric buzzer, it is possible to set the fundamental vibration frequency of the complex to the operating frequency, or to set the cavity frequency of the cavity to the operating frequency. was set to the frequency used. However, the cavity frequency is contrary to the size of the cavity, and for example, in order to suppress the cavity frequency, it is necessary to make the cavity large. Therefore, when used at a relatively low frequency such as 1k11z, the cavity becomes large, making it difficult to downsize the piezoelectric buzzer itself.

(Object of the Invention) Therefore, an object of the present invention is to provide a piezoelectric buzzer that is small and can generate high sound pressure even at a relatively low frequency.

(Summary of the Invention) To put it simply, the present invention sets the fundamental vibration frequency of the composite body near the frequency used, drives the composite body with pulses at a high frequency, and further increases the cavity frequency of the composite body. This is a piezoelectric buzzer with a frequency door set near either the frequency of the next vibration or the frequency of the harmonics of the pulse.

The above objects and other objects and features of the invention will become more apparent from the following detailed description with reference to the drawings.

(Description of Embodiments) Fig. 1 is a sectional view showing an example of a piezoelectric buzzer in which the present invention can be implemented.The piezoelectric buzzer 11 includes a composite body 13.The composite body 13 is made of metal such as brass. The diaphragm 15 includes a diaphragm 5 formed by punching out a material into a circular shape.The diaphragm 15 has its outer circumferential portion clamped and fixed between the end faces of the first exterior case 21 and the second exterior case 23, and
．． It is provided inside 23. A disk-shaped piezoelectric element 17 made of, for example, ceramic is adhered to one main surface of the diaphragm 15 using, for example, an adhesive or the like. This piezoelectric element 1
Reference numeral 7 has a disk shape smaller than the diameter of the diaphragm 15, and is formed concentrically with the diaphragm 15. Further, on the other main surface of the piezoelectric element 17, an electrode film 19 made of, for example, nickel or silver is formed. In this embodiment, the basic vibration frequency of the J diaphragm 15, that is, the composite body 13, is selected to be a working frequency of, for example, 1kllz. Further, a lead wire 15a and a lead wire 19a are connected to the diaphragm 15 and the electrode film 19, respectively.

And lead wires 15a and 19a of piezoelectric buzzer 11
A drive circuit 33 is connected to. The drive circuit 33 generates a pulse, such as a rectangular wave, containing a harmonic component as a drive signal, and drives the piezoelectric buzzer 11 . In this embodiment, the drive signal is a rectangular wave with a repetition frequency (used frequency) of 1 kHz and a duty ratio of 1:1. Therefore, the drive signal includes a third high open wave, that is, 3k
Contains llz components.

The complex 13 may be, for example, another bimorph or unimorph other than the one described above, as long as its fundamental vibration frequency is set near the number of parts used, for example, Ikl(z).

A sound emitting hole 27 is formed in the upper part 25 of the first exterior case 21 of the first exterior case 21 and the second exterior case 23 that support the diaphragm 15 on the outer periphery as described above. This sound emitting hole 27 transmits the sound caused by the vibration of the diaphragm 15 to the outer case 2.
1.23 is for radiating to the outside, and the upper part 25
It is shaped like a cow in the center. The cavity 31 is formed so as to resonate with the sound generated by the vibration of the diaphragm 15. That is, this cavity 31 is formed by a space surrounded by the diaphragm 15 and the first exterior case 21, and
The cavity frequency is set to be a harmonic component of the driving pulse, that is, 3 kHz.

As mentioned above, the cavity 31 of the piezoelectric buzzer 11 is designed to resonate with the third harmonic component of the drive pulse, that is, the frequency of 3kHz. The piezoelectric buzzer 1 is smaller than the resonant conventional one, thereby making the piezoelectric buzzer 1
1 can be made smaller than before.

FIG. 2 is a graph showing sound pressure versus driving frequency in an embodiment of the present invention. In Figure 2, the dotted line is 1kHz.
The dashed line shows the case when driven by a 3kHz sine wave, and the solid line shows the case when the duty ratio is 1:
The case of driving with a 1kHz square wave of 1 is shown. This second
As can be seen from the figure, when driven with a 1 kHz sine wave, sound pressure is obtained only in the frequency band around 1 kHz, and when driven with a 3 kHz sine wave, sound pressure is obtained only in the frequency band around 3 kHz. Sound pressure cannot be obtained. However, when driving with a rectangular wave with a repetition frequency of 1 kHz and a duty ratio of 1:1, high sound pressure can be obtained in the frequency band around 1 kHz, as shown by the solid line in FIG. This is because the sound generated by the piezoelectric buzzer 11 is a complex sound including a sound of the fundamental wave frequency of the rectangular wave, ie, 1 kHz, and a sound of the third harmonic frequency of the rectangular wave, ie, 3 kHz. This is because the complex 13 is driven simultaneously at 1 kHz and 3 kHz, and the fundamental vibration frequency of the complex 13 is set to 1 kHz, and the cavity frequency is set to 3 kHz. The frequency of the sound that can be heard is not only the fundamental frequency, that is, the sound of 1kFiz, but also 1kHz and 3kt (z
The two sounds will sound at the same time, and the sound pressure will become higher.

In the embodiment described above, the piezoelectric buzzer (FIG. 1) has its cavity frequency set to 3kHz and the drive pulses to 1.
It was explained as a rectangular wave with a duty ratio of l:1 at kl(z. However, if the cavity frequency is 2 k llz
, and the repetition frequency of the driving pulse is 1k.
It is also possible to use a rectangular wave with a duty ratio of 1:2 at llz.

In this case, the drive pulse includes a second harmonic component.

Therefore, from the piezoelectric buzzer, the fundamental tone of 1kllz and the
A complex sound containing a kHz upper tone is generated. This is because the complex 13 is driven simultaneously at 1 kHz and 2 kHz, and the fundamental vibration frequency of the complex 130 is set to 1 kHz, and the cavity frequency is set to 2 kHz. This complex sound also has a frequency of the fundamental sound, that is, 1
Since not only the kHz sound but also the 1kl (z and 2k)lzO sound is sounded at the same time, the sound pressure becomes high. In this case too,
The cavity frequency is set to a higher frequency than before, i.e. 2k.
Since it is set to Hz, the cavity can be made smaller than before, and the piezoelectric buzzer can also be made smaller.

FIG. 3 is a graph showing the relationship between driving frequency and sound pressure in another embodiment of the present invention. In this embodiment, the fundamental vibration frequency of the composite body 13 of the piezoelectric buzzer 11 (FIG. 1) is set to a working frequency of, for example, 1 kllz. Further, the frequency of the secondary vibration of the composite body 13 is, for example, 3 to 3.5 times the fundamental vibration frequency, and in this embodiment, 3.5k)lz is selected. - Therefore, this complex 13, when driven with a drive pulse containing its fundamental vibrational frequency, i.e. 1kHz, 1kHz and the second or third harmonic of the drive pulse, described below, 2kll.
Sounds at frequencies including z or 3kHz. Furthermore, the cavity frequency of the cavity 31 (FIG. 1) is set to 3.5 kHz, which is the frequency of secondary vibration of the composite. Note that the cavity frequency may be set to another higher-order vibration frequency. On the other hand, the driving pulse has a repetition frequency of 1 kl (duty ratio of 1:1 in z), for example.
Let it be a square wave. Therefore, each drive pulse in this case is
Contains third harmonic. Therefore, the complex 13 generates sound at a frequency including 1 kHz and 3 kHz, as shown by the dotted line in FIG. Moreover, since the cavity frequency is set to the frequency of the secondary vibration of the complex, 3.5kHz,
The 3.5kHzO sound pressure level increases, and even
k 117. Nearby sound pressure increases. This complex sound is then heard as its fundamental tone, that is, a sound with a frequency around 1 kHz. Therefore, the sound that can be heard is a broadband sound around the fundamental frequency, that is, l k'Hz, and the sound pressure is the sum of the sound energy of 1 kHz, the energy of 3 kHz, and the energy of 3.5 kHz. It becomes taller as shown by the solid line in Figure 3.

Furthermore, in the above embodiments, the cavity frequency was set to the same frequency as the harmonic frequency of the drive pulse or the frequency of the higher-order vibration of the complex, but the cavity frequency was set to a frequency slightly shifted from those frequencies. It's okay. FIG. 4 is a graph showing the relationship between the frequency and sound pressure of the piezoelectric buzzer according to the embodiment in which the piezoelectric buzzers are shifted in this way. In the embodiment shown in FIG. 4, in the piezoelectric buzzer 11 (FIG. 1), the fundamental vibration frequency of the complex is set to a working frequency of, for example, 1 kHz, and the cavity frequency is set to the second order frequency of the complex. The frequency is set to be slightly different from the vibration frequency. For example, the frequency of the secondary vibration of the complex is 3.5k
Hz, and the cavity frequency is set to 3.6 kFIz. Such a cavity resonates at a frequency near the frequency of the second-order vibration of the composite. The driving pulse has a repetition frequency of Ik)Iz and a duty ratio of 1:1.

In this way, as shown in FIG. 4, the piezoelectric buzzer produces a sound pressure with a wide band around 1 kHz.

In addition, in this example, the cavity frequency is 3.6kHz.
z, and the frequency of the fundamental tone of the sound that resonates most with it is 1.2 kHz, so the band is wider than in the previous embodiment.

Further, in all of the above-described embodiments, the fundamental vibration frequency of the composite body is set as the working frequency, but this may be set to a frequency slightly deviated from the working frequency.

(Effects of the Invention) As described above, according to the present invention, the cavity frequency is set to a frequency close to either the frequency of the higher-order vibration of the complex or the frequency of the harmonics of the pulse. , the cavity can be made smaller than before, and the piezoelectric buzzer can also be made smaller. Furthermore, since the fundamental vibration frequency of the complex is set near the operating frequency, the sound heard from the piezoelectric buzzer is in that operating frequency range, and the sound is small even at a relatively low operating frequency.
A piezoelectric buzzer with a high sound pressure can be obtained in a compact size.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an example of a piezoelectric buzzer in which the present invention can be implemented. FIG. 2 is a graph showing the relationship between frequency and sound pressure in one embodiment of the present invention. FIG. 3 is a graph showing the relationship between frequency and sound pressure in another embodiment of the invention. FIG. 4 is a graph showing the relationship between frequency and sound pressure in yet another embodiment of the present invention. In the figure, 11 is a piezoelectric buzzer, 13 is a composite body, 15 is a diaphragm, 17 is a piezoelectric element, 21 is a first exterior case, 2
3 is a second exterior case, 31 is a cavity, and 33 is a drive circuit. Patent applicant Murata Manufacturing Co., Ltd. Representative Patent attorney Oka 1) Kei Zen (and 1 other person) Figure 4 - 10, Immediate S wave number output 21

Claims (1)

[Scope of Claims] A piezoelectric buzzer comprising a composite body that vibrates by being driven by a pulse of a used frequency containing a harmonic component, and a cavity formed to resonate with the vibrations of the composite body, the piezoelectric buzzer comprising: The fundamental vibration frequency is set to a frequency near the use frequency, and the cavity frequency of the cavity is set to a frequency near either one of the frequency of higher-order vibration of the complex and the frequency of harmonics of the pulse. characterized by
piezoelectric buzzer.