JPWO2018056358A1 - Pronunciation device, alarm device, and sensor - Google Patents

Abstract

Provided are a sounding device, an alarm device, and a sensor capable of sharing a configuration with sounds of a plurality of patterns having different tones. The sound generation device (1) includes a sound generation unit (4) and a signal generation unit (2). The sound generation unit (4) can generate sounds of a plurality of patterns having different tones. The signal generator (2) outputs a signal corresponding to any one of the plurality of patterns to the sound generator (4). The sound generation unit (4) generates a sound having a pattern corresponding to the signal from the signal generation unit (2).

Description

  The present invention relates generally to sounding devices, alarm devices, and sensors, and more particularly to a sounding device, alarm device, and sensor that generate sounds of multiple frequencies.

  BACKGROUND Conventionally, a home alarm (sensor) that detects and warns of an abnormality such as a fire or a gas leak in a home has been disclosed (see, for example, Patent Document 1). The alarm device for houses of patent document 1 is provided with the sound emission apparatus which outputs the sweep sound (alarm sound) which frequency changes linearly with progress of time, when abnormality is detected.

  In the conventional sound producing apparatus, the same tone or tone change can generate only a certain pattern of sound.

JP, 2010-49604, A

  The present invention has been made in view of the above, and an object thereof is to provide a sound producing device, an alarm device, and a sensor capable of achieving commonality of configurations with a plurality of patterns of tones having different tones. .

  A sound generation device according to an aspect of the present invention includes a signal generation unit and a sound generation unit. The sound generator can generate sounds of a plurality of patterns having different tones. The signal generation unit outputs a signal corresponding to any one of the plurality of patterns to the sound generation unit. The sound generator generates a sound having a pattern according to the signal from the signal generator.

  An alarm device according to an aspect of the present invention is the above-described sound generation device, wherein the sound generation unit generates an alarm sound.

  A sensor according to an aspect of the present invention includes the alarm device described above and a detection unit that detects a specific event. The alarm device generates an alarm sound when the detection unit detects the specific event.

FIG. 1 is a block diagram of a sensor including a sound generation device according to Embodiment 1 of the present invention. FIG. 2 is a perspective view of the above-described sound generation device. FIG. 3 is a time chart of a PWM signal generated by the signal generation unit of the above-described sound generation device. FIG. 4 is a time chart of the frequency and duty of a PWM signal generated by the signal generation unit of the above-described sound generation device. FIG. 5 is a graph of the frequency characteristic of the casing of the above-described sound producing device. FIG. 6 is a time chart of the frequency and the duty of the PWM signal generated by the signal generation unit of the sound generation device according to the modification of the first embodiment of the present invention. FIG. 7 is a time chart of frequency and duty of a PWM signal generated by a signal generation unit of a sound generation device according to another modification of the first embodiment of the present invention. FIG. 8 is a block diagram of a sensor including a sound generation device according to Embodiment 2 of the present invention. FIG. 9 is a block diagram of a sensor including a sound generation device according to a modification of Embodiment 2 of the present invention.

  Hereinafter, embodiments of the present invention will be described based on the drawings. However, the embodiment described below is only one of various embodiments of the present invention. The following embodiments can be variously modified according to the design and the like as long as the object of the present invention can be achieved.

(1) Embodiment 1
(1.1) Configuration FIG. 1 shows a block diagram of a sensor 100 including the sound producing device 1 of the present embodiment. FIG. 2 shows an external view of a sensor 100 including the sound producing device 1 of the present embodiment. The sound generation device 1 of the present embodiment is a device capable of generating sounds of a plurality of frequencies included in the human audible range (for example, 20 Hz to 20 kHz). The sound generation device 1 is an alarm device 10 that generates a sound whose frequency changes as time passes as an alarm sound. The sensor 100 of the present embodiment is a smoke sensor, and includes an alarm device 10. The sensor 100 generates an alarm sound from the alarm device 10 when it detects the generation of smoke.

  Hereinafter, the details of the sound generation device 1 of the present embodiment will be described.

  The sound generation device 1 includes a signal generation unit 2, a sound generation unit 4, an acoustic circuit 3, and a housing 11 (see FIG. 2). The housing 11 accommodates the signal generation unit 2, the sound generation unit 4, and the acoustic circuit 3, and is attached to, for example, the ceiling of a building. Further, the case 11 is provided with a power supply 5 which functions as an operation power supply of the sound generation device 1. The power source 5 is composed of a battery. The power source 5 is not limited to the battery. The sound generation device 1 may be configured to use, for example, a commercial power supply as an operating power supply.

  The signal generation unit 2 is, for example, a microcomputer (microcomputer), and generates a PWM signal (PWM: Pulse Width Modulation). The signal generation unit 2 is configured to be able to change the frequency of the PWM signal. That is, the signal generation unit 2 is configured to generate a signal (PWM signal) whose frequency and duty are variable. The signal generator 2 outputs the PWM signal to the acoustic circuit 3.

  The acoustic circuit 3 includes an inductor 31 and a switching element 32. The inductor 31 and the switching element 32 are connected in series between the output ends of the power supply 5.

  The inductor 31 functions as a boost coil. The sound generator 4 is connected between both ends of the inductor 31. The sound generation unit 4 is configured of a separately excited piezoelectric buzzer, and the voltage across the inductor 31 is input. The sound generator 4 generates a sound of the frequency of the input voltage. The case 11 is formed with a hole through which the sound generated by the sound generation unit 4 is transmitted, and the sound generated by the sound generation unit 4 reaches the outside of the case 11 through the hole. Further, the magnitude of the instantaneous sound pressure of the sound generated by the sound generation unit 4 changes according to the magnitude of the amplitude of the voltage input to the sound generation unit 4. The sound generation unit 4 is not limited to the piezoelectric buzzer, and may be a speaker.

  The switching element 32 is an npn transistor, a booster coil is connected to the collector, an output terminal on the negative electrode side of the power supply 5 is connected to the emitter, and the signal generation unit 2 is connected to the base. The switching element 32 is turned on when the signal level of the PWM signal is at the Hi level, and turned off when the signal level is at the Low level. Therefore, the switching element 32 is turned on / off by inputting the PWM signal to the base.

  When the switching element 32 is in the on state, energy is stored in the inductor 31 by the current supplied from the power supply 5 to the inductor 31. Then, at the timing when the switching element 32 is turned off, the energy stored in the inductor 31 is released, and a voltage obtained by boosting the output voltage of the power supply 5 is applied to the sound generation unit 4. Therefore, the frequency of the sound generated by the sound generator 4 is the same as the frequency of the PWM signal. Further, as the duty of the switching element 32 is larger, the energy stored in the inductor 31 is larger, and the voltage applied to the sound generator 4 is larger. Therefore, when the frequency of the PWM signal is constant, the power consumption of the sound generator 4 increases as the duty of the PWM signal increases, but the instantaneous sound pressure of the sound generated by the sound generator 4 also increases.

  Although the details will be described in “(1.2) Operation example” described later, the signal generation unit 2 changes the frequency of the PWM signal as time passes. As a result, a sound whose frequency changes as time passes is generated from the sound generation unit 4 as an alarm sound.

  The switching element 32 may be a pnp transistor, an IGBT (Insulated Gate Bipolar Transistor), a MOSFET (Metal Oxide Semiconductor Field Effect Transistor), or the like.

  The sensor 100 of the present embodiment includes an alarm device 10 (sound generation device 1) and a detection unit 6.

  The detection unit 6 detects a specific event. The detection unit 6 of the present embodiment is configured to detect the generation of smoke as a specific event. The detection unit 6 includes a light emitting unit 61 such as a light emitting diode and a light receiving unit 62 such as a photodiode. The light emitting unit 61 and the light receiving unit 62 are disposed such that the light receiving surface of the light receiving unit 62 is out of the optical axis of the light emitted from the light emitting unit 61. The housing 11 is formed with a hole through which smoke can be introduced into the housing 11. When smoke does not exist in the housing 11, the irradiation light of the light emitting unit 61 hardly reaches the light receiving surface of the light receiving unit 62. When smoke is present in the housing 11, the irradiation light of the light emitting unit 61 is scattered by the smoke, and a part of the scattered light reaches the light receiving surface of the light receiving unit 62. That is, the detection unit 6 detects the generation of smoke by receiving the irradiation light of the light emitting unit 61 scattered by the smoke by the light receiving unit 62.

  The detection unit 6 transmits a detection signal to the signal generation unit 2 when it detects the generation of smoke which is a specific event. The signal generation unit 2 generates a PWM signal using the detection signal from the detection unit 6 as a trigger. That is, when the detection unit 6 detects the generation of smoke, the signal generation unit 2 outputs a PWM signal to the acoustic circuit 3 so that the sound generation unit 4 generates a sound (alarm sound).

  In addition, an alarm system including a plurality of sensors 100 and a master unit may be configured. In this case, the sensor 100 further includes a communication unit and is configured to be communicable with the parent device. When the detection unit 6 detects the generation of smoke, the sensor 100 transmits a notification signal from the communication unit to the master unit. When the base unit receives the notification signal, it generates an alarm sound from another sensor 100 different from the sensor 100 that has transmitted the notification signal. That is, when one sensor 100 detects the generation of smoke, the master unit interlocks with the other sensors 100 to generate an alarm sound.

  In addition, the specific event which the detection part 6 detects is not restricted to generation | occurrence | production of smoke. For example, the detection unit 6 may be configured to detect the generation of heat. That is, the sensor 100 may be a heat sensor.

(1.2) Operation Example Next, an operation example of the sound producing device 1 (the alarm device 10, the sensor 100) of the present embodiment will be described with reference to FIGS. 3 and 4. FIG.

  The signal generation unit 2 generates a PWM signal using a detection signal input when the detection unit 6 detects the generation of smoke as a trigger. The signal generation unit 2 changes the frequency of the PWM signal as time passes. The signal generation unit 2 of the present embodiment alternately changes the frequency of the PWM signal to a first frequency f1 (for example, 1000 Hz) and a second frequency f2 (for example, 500 Hz). The first frequency f1 and the second frequency f2 change at a cycle T100. In the cycle T100, a period in which the frequency of the PWM signal is the first frequency f1 is a first period T10 (for example, 250 ms, 500 ms or the like) and a period in which the frequency is a second frequency f2 is a second period T20 (for example, 250 ms) , 500 ms etc.).

  FIG. 5 shows a graph of the frequency characteristic of the housing 11. The first frequency f1 and the second frequency f2 are different from each other in the resonance frequency f0 of the housing 11. The resonance frequency f0 is also called a natural frequency, and is a frequency at which the housing 11 easily vibrates. The resonance frequency f0 is determined by the material and shape of the housing 11, the size of the hole through which sound passes, the resonance frequency of the sounding body of the sounding unit 4, and the like. The resonant frequency can be measured by, for example, a hammering test. The hammering test is a method of measuring the resonance frequency of an object by striking an object attached with an acceleration pickup with an impulse hammer and analyzing the measurement result of the acceleration pickup with an FFT analyzer (FFT: Fast Fourier Transform).

  In the present embodiment, the relationship between the first frequency f1, the second frequency f2, and the resonance frequency f0 is the resonance frequency f0, the first frequency f1, and the second frequency f2 in descending order of frequency value (f0> f1> f2 ). That is, the difference between the first frequency f1 and the resonant frequency f0 is smaller than the difference between the second frequency f2 and the resonant frequency f0. In other words, the first frequency f1 is a value closer to the resonance frequency f0 than the second frequency f2.

  Further, the signal generation unit 2 changes the duty of the PWM signal according to the frequency of the PWM signal. In this embodiment, the duty when the frequency of the PWM signal is the first frequency f1 is the first duty D1, and the duty when the frequency of the PWM signal is the second frequency f2 is the second duty D2. The duty of the PWM signal is a ratio of the on time (the time when the signal level is Hi level) in one cycle of the PWM signal. Assuming that the cycle (= 1 / f1) when the frequency of the PWM signal is the first frequency f1 is the first cycle T1 and the on-time is the first on-time Ton1, the first duty D1 is D1 = Ton1 / T1 Become. Assuming that the cycle (= 1 / f2) when the frequency of the PWM signal is the second frequency f2 is the second cycle T2 and the on-time is the second on-time Ton2, the second duty D2 is D2 = Ton2 / T2 Become. The signal generator 2 changes the duty by adjusting the on-time according to the frequency of the PWM signal.

  In the present embodiment, the relationship between the first duty D1 and the second duty D2 is such that the first duty D1 is larger than the second duty D2 (D1> D2). That is, when the frequency of the PWM signal is the first frequency f1 of the first frequency f1 and the second frequency f2 that is closer to the resonance frequency f0, the first duty D1 has the frequency of the PWM signal of the second frequency f2. The second duty D2 is larger than the second duty D2.

  As described above, the signal generation unit 2 alternately changes the frequency of the PWM signal to the first frequency f1 and the second frequency f2 as time passes, and the duty of the PWM signal is changed to the first duty D1 and the second duty D1. The duty D2 is alternately changed. The first frequency f1 is a value closer to the resonance frequency of the housing 11 than the second frequency f2. Therefore, the housing 11 is more likely to resonate with the sound of the first frequency f1 than the sound of the second frequency f2.

  Further, the signal generation unit 2 is configured such that the first duty D1 when the frequency of the PWM signal is the first frequency f1 is higher than the second duty D2 when the frequency of the PWM signal is the second frequency f2. The duty of the PWM signal is changed. That is, in the signal generation unit 2, the first duty D1 when the frequency of the PWM signal is the first frequency f1 at which the casing 11 resonates more easily than the second frequency f2 is larger than the second duty D2 The duty of the PWM signal is changed. In other words, the signal generation unit 2 sets the duty of the PWM signal so that the second duty D2 is smaller when the frequency of the PWM signal is the second frequency f2 at which the casing 11 is less likely to resonate than the first frequency f1. Is changing.

  By making the first duty D1 larger than the second duty D2, the signal generation unit 2 increases the instantaneous sound pressure of the sound of the first frequency f1 compared to the sound of the second frequency f2. Furthermore, since the housing 11 is likely to resonate with the sound of the first frequency f1, the instantaneous sound pressure of the sound of the first frequency f1 is further increased. Further, the signal generation unit 2 makes the second duty D2 smaller than the first duty D1. Thereby, power consumption of the sound generator 4 at the time of generation of the sound of the second frequency f2 is reduced as compared with generation of the sound of the first frequency f1.

  The relationship between the first frequency f1, the second frequency f2 and the resonance frequency f0 described above is an example, and is not limited to the above. The first frequency f1 and the second frequency f2 may be higher than the resonance frequency f0, or the resonance frequency f0 may be a value between the first frequency f1 and the second frequency f2.

(1.3) Modified Example Next, a modified example of the sound producing device 1 of the present embodiment will be described.

  The signal generation unit 2 may set the first period T10 in which the frequency of the PWM signal is the first frequency f1 and the period in which the second frequency f2 is longer than the second period T20 in the cycle T100. As a result, the generation period of the sound of the first frequency f1 in which the housing 11 easily resonates is extended, and the sound pressure of the sound generated by the sound generator 4 is further increased.

  In the example described above, the signal generation unit 2 alternately changes the frequency of the PWM signal to two frequencies (the first frequency f1 and the second frequency f2) as time passes, but the present invention is not limited to this. It may be changed to three or more frequencies.

  In addition, the signal generation unit 2 may gradually change (sweep) the frequency of the PWM signal as time passes. In the present modification, the signal generation unit 2 changes the frequency of the PWM signal from the second frequency f2 to the first frequency f1 in a cycle T200 (for example, 1 second, 2 seconds, etc.) (see FIG. 6). A frequency between the first frequency f1 (for example, 1000 Hz) and the second frequency f2 (for example, 500 Hz) is set as a third frequency f3 (for example, 900 Hz). A band from the third frequency f3 to the first frequency f1 is referred to as a first band B1, and a band from the second frequency f2 to the third frequency f3 is referred to as a second band B2. That is, the signal generation unit 2 gradually changes the frequency of the PWM signal over a plurality of bands (the first band B1 and the second band B2) as time passes. Further, the signal generation unit 2 changes the duty of the PWM signal for each of a plurality of bands. In the present variation, when the frequency of the PWM signal is included in the first band B1, the signal generation unit 2 changes the duty of the PWM signal to the first duty D1, and the frequency of the PWM signal is included in the second band B2. In this case, the duty of the PWM signal is changed to the second duty D2.

  Thus, when gradually changing the frequency of the PWM signal, the signal generation unit 2 of the present variation changes the duty of the PWM signal for each of a plurality of bands. Therefore, compared with the case where both the frequency and the duty of the PWM signal are gradually changed, the process for the signal generator 2 to generate the PWM signal is facilitated.

  Further, the amount of change in the frequency of the PWM signal per unit time (the sweep speed of the frequency of the PWM signal) may not be constant. The amount of change in frequency per unit time when the frequency of the PWM signal changes in the first band B1 including the first frequency f1 is taken as a first amount of change Δ1. The amount of change in frequency per unit time when the frequency of the PWM signal changes in the second band B2 including the second frequency f2 is taken as a second change amount Δ2. The signal generation unit 2 changes the frequency of the PWM signal so that the first change amount Δ1 becomes smaller than the second change amount Δ2. That is, the signal generation unit 2 slows the sweep speed when the frequency of the PWM signal is in the first band B1 including the first frequency f1. As a result, the generation period of the sound in the first band B1 including the first frequency f1 is extended, and the sound pressure of the sound generated by the sound generator 4 is further increased.

  In the above-described example, the signal generation unit 2 changes the frequency of the PWM signal over two bands, but may change it over three or more bands.

  Further, in the above-described example, the signal generation unit 2 changes the duty of the PWM signal for each frequency band of the PWM signal, but the present invention is not limited to this. The signal generation unit 2 may gradually change the frequency of the PWM signal as time passes, and may change the duty of the PWM signal to a duty corresponding to the frequency of the PWM signal. That is, the signal generation unit 2 gradually changes the duty of the PWM signal from the second duty D2 to the first duty D1 in accordance with the change of the frequency of the PWM signal from the second frequency f2 to the first frequency f1 (see FIG. 7). As a result, the sound pressure of the sound generated by the sound generator 4 gradually changes.

  Preferably, the signal generation unit 2 changes the duty of the PWM signal so that the change width of the duty of the PWM signal falls within a predetermined range. Thereby, it is suppressed that the difference of the instantaneous sound pressure by the change of a frequency becomes large too much.

  In addition, the signal generation unit 2 may be configured to set the duty such that the change width of the duty of the PWM signal falls within a predetermined range based on a plurality of frequencies arbitrarily input by the user. As a result, the sound generation device 1 can reduce power consumption even when generating sounds of a plurality of frequencies input by the user. Further, it is preferable that the signal generation unit 2 set the duty so that the duty of the PWM signal is equal to or more than the lower limit value. As a result, the sound pressure of the sound generated when the duty of the PWM signal is small is suppressed from becoming too small.

  Further, in the above-described example, the signal generation unit 2 changes the duty of the PWM signal based on the resonance frequency f0 of the housing 11, but the present invention is not limited thereto. The signal generation unit 2 may change the duty of the PWM signal based on the radiation characteristic of the sound radiated from the sound generation unit 4 to the outside of the housing 11. The radiation characteristic in the present embodiment is a characteristic that indicates the sound pressure level of the sound emitted from the housing 11 with respect to the frequency of the sound when the sound generation unit 4 generates a sound with a predetermined sound pressure level. The radiation characteristic is determined by the resonance frequency f0 of the case 11, the resonance frequency of the sound generation unit 4, the position of the sound generation unit 4 in the case 11, and the like. The signal generation unit 2 changes the duty of the PWM signal with reference to the frequency (peak frequency f10) at which the sound pressure level in the radiation characteristic reaches a peak value. For example, it is assumed that the relationship among the first frequency f1, the second frequency f2, and the peak frequency f10 is the peak frequency f10, the first frequency f1, and the second frequency f2 in descending order of frequency value (f10> f1> f2). In this case, the signal generation unit 2 generates the first duty D1 when the frequency of the PWM signal is the first frequency f1 closer to the peak frequency f10 among the first frequency f1 and the second frequency f2 as the PWM signal The second frequency D2 is larger than the second duty D2 at the second frequency f2.

  In addition, the signal generation unit 2 determines the difference between the first on-time Ton1 when the frequency of the PWM signal is the first frequency f1 and the second on-time Ton2 when the frequency of the PWM signal is the second frequency f2. The duty of the PWM signal may be corrected to reduce it. For example, when the first frequency f1 of the PWM signal is higher than the first threshold, the signal generation unit 2 multiplies the first coefficient by the duty corresponding to the preset first frequency f1 as the first duty D1. I assume. Further, when the second frequency f2 of the PWM signal is lower than the second threshold, the signal generation unit 2 multiplies the second coefficient by the duty corresponding to the second frequency f2 set in advance as the second duty D2. I assume. The first coefficient is a larger value than the second coefficient. The first threshold and the second threshold may be the same value as each other, or may be different values from each other.

  As described above, the signal generation unit 2 corrects the duty with a coefficient based on the frequency of the PWM signal, so that the difference in on-time can be reduced before and after the frequency of the PWM signal is changed.

  The correction of the duty of the PWM signal using a coefficient based on the frequency of the PWM signal is not limited to the above.

  For example, the duty of the PWM signal may be corrected using a coefficient based on the radiation characteristic of the sound radiated from the sound producing unit 4 to the outside of the housing 11. In this case, the coefficient is set to be larger as the frequency of the PWM signal is closer to the peak frequency f10. As a result, the sound pressure of the sound generated by the sound generator 4 is further increased.

  Also, the duty of the PWM signal may be corrected using a coefficient based on a frequency at which human ear sensitivity is high. In this case, the coefficient is set such that the frequency of the PWM signal becomes higher as the sensitivity of the human ear is higher. As a result, for the human being, the sound generated by the sound generator 4 can be louder.

  Also, the coefficient may be set to increase as the frequency of the PWM signal increases.

  Also, the coefficient may be set based on the change period of the frequency in the PWM signal. In this case, the coefficient is set such that the longer the period in which the frequency of the PWM signal is kept constant, the longer the change period of the frequency of the PWM signal. For example, in a change period T100 of the frequency of the PWM signal, a first period T10 in which the frequency of the PWM signal is maintained at the first frequency f1 and a second period T20 in which the frequency of the PWM signal is maintained at the second frequency f2. And the factor is set (see FIG. 3). In this case, the coefficient (first coefficient) by which the duty corresponding to the first frequency f1 is multiplied is the ratio of the first period T10 in the cycle T100 (duty of the first period T10) or the time length of the first period T10 Is set to be larger as The coefficient (second coefficient) by which the duty corresponding to the second frequency f2 is multiplied is the ratio of the second frequency T20 in the cycle T100 (duty of the second period T20), or the time length of the second period T20 is The larger the value, the larger the value. As a result, in the sound generated by the sound generator 4, the duty of the dominant frequency is increased, and the sound pressure can be increased.

  The above-described coefficient may be one or more values, or may be a value less than one.

(2) Embodiment 2
(2.1) Configuration FIG. 8 shows a block diagram of a sensor 100 including the sound producing device 1 of the present embodiment. In the sound generation device 1 of the present embodiment, sounds of plural patterns having different tones can be generated from the sound generation unit 4. In addition, about the structure similar to Embodiment 1 mentioned above, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  In the present embodiment, an alarm system is configured by a plurality (three in FIG. 8) of sensors 100 and a master unit 9 (see FIG. 8). In other words, the alarm system includes the plurality of sensors 100 and the master unit 9.

  The sensor 100 of the present embodiment includes the sound generation device 1 and the communication unit 8. The communication unit 8 is configured to be capable of wireless communication with the parent device 9. The sensor 100 transmits a notification signal from the communication unit 8 to the parent device 9 when the detection unit 6 detects the generation of smoke. When the notification signal is received, master device 9 transmits an alarm signal to another sensor 100 different from the sensor 100 that transmitted the notification signal, and generates an alarm sound from the other sensor 100. That is, when one sensor 100 detects the generation of smoke, the master 9 controls the other sensors 100 to interlock and generate an alarm sound. The communication unit 8 may be configured to perform wired communication with the parent device 9.

  Further, the sound generation device 1 of the present embodiment includes a sound generation unit 4, a signal generation unit 2, and a setting unit 7. The sound generator 4 can generate a plurality of patterns of different tones. Specifically, the signal generation unit 2 is configured to be able to change the period and frequency (tone) of the PWM signal transmitted to the sound generation unit 4 into a plurality of patterns. As a result, the sound generator 4 can generate a plurality of patterns of sounds. The plural patterns of sound include, for example, international standard "ISO 8201", German "DIN 33404-3", English "BS 5389-1", France "NF S32-001", Netherlands "NEN 2575" It is a sound of a pattern conforming to a standard such as Data (period, frequency, duty, etc.) of the PWM signal corresponding to a plurality of sound patterns are stored in a storage unit 70 such as a ROM (Read Only Memory), for example.

  Further, as in the first embodiment, the signal generation unit 2 changes the duty of the PWM signal based on the resonance frequency f0 (or the peak frequency f10) of the housing 11. The signal generation unit 2 sets the duty when the frequency of the PWM signal is closer to the resonance frequency f0 (peak frequency f10) to the duty when the frequency of the PWM signal is farther to the resonance frequency f0 (peak frequency f10). Make it larger than the duty at that time.

  The setting unit 7 sets, in the signal generation unit 2, a sound pattern corresponding to the PWM signal that the signal generation unit 2 transmits to the sound generation unit 4. In other words, the setting unit 7 determines a sound pattern corresponding to the PWM signal that the signal generation unit 2 transmits to the sound generation unit 4. The signal generation unit 2 transmits the PWM signal corresponding to the pattern set (determined) by the setting unit 7 among the plurality of patterns to the sound generation unit 4.

  The parent device 9 is configured to transmit a setting signal to the sensor 100 (communication unit 8) in response to an operation from the user. The setting signal includes data indicating a pattern of sound generated from the sound generation device 1 (sound generation unit 4) of the sensor 100. The setting unit 7 determines a pattern to be set in the signal generation unit 2 from a plurality of patterns based on the setting signal received by the communication unit 8 from the parent device 9. Transmission of the setting signal from the parent device 9 to the sensor 100 is performed, for example, at the time of initialization after installation of the parent device 9 and the sensor 100.

  As described above, the sound generation device 1 of the present embodiment is configured to be able to generate sounds of a plurality of patterns. Then, when the detection unit 6 detects the generation of smoke, the sound generation device 1 generates, as an alarm sound, the sound of the pattern set by the parent device 9 among the plurality of patterns. Therefore, even if, for example, the pattern of the sound to be generated as the alarm sound differs depending on the country, the sound of the pattern corresponding to each country can be generated as the alarm sound by one kind of the sound producing device 1 (sensor 100). . That is, the sounding device 1 (sensor 100) can be made common in each country.

(2.2) Modified Example FIG. 9 shows a modified example of the sound producing device 1 of the present embodiment.

  In the sound generation device 1 of the present modification, the setting unit 7 includes the operation unit 71, and when the user operates the operation unit 71, it is possible to switch the pattern of the sound to be generated as the alarm sound.

  The operation unit 71 is configured by, for example, a dip switch, and receives an operation from the user. In the operation unit 71, sounds of a plurality of patterns are associated with the states of the plurality of slide switches. The setting unit 7 determines a pattern to be set in the signal generation unit 2 from a plurality of patterns based on the operation signal output from the operation unit 71. The operation signal indicates the state of the plurality of slide switches that the operation unit 71 has. That is, the operation signal indicates the sound of the pattern selected by the user from the sounds of the plurality of patterns. The signal generation unit 2 transmits the PWM signal corresponding to the pattern set (determined) by the setting unit 7 among the plurality of patterns to the sound generation unit 4.

  As described above, when the detection unit 6 detects the generation of smoke, the sound generation device 1 of the present modification generates, as a warning sound, a sound of a pattern set by the user in the operation unit 71 among a plurality of patterns.

  In the example described above, the signal generation unit 2 changes the pattern of the sound generated from the sound generation unit 4 by changing the period and frequency of the PWM signal into a plurality of patterns, but the present invention is not limited to this configuration. For example, the signal generation unit 2 may cause the sound generation unit 4 to generate sound by reproducing a WAV file (RIFF waveform Audio Format, RIFF: Resource Interchange File Format). Here, “playing a WAV file” means that the sound generator 4 transmits a signal for generating a sound. The WAV file is stored in the storage unit 70 provided in the sound producing device 1. The storage unit 70 stores a plurality of WAV files corresponding to sounds of a plurality of patterns. The signal generation unit 2 extracts the WAV file corresponding to the pattern set by the setting unit 7 from the storage unit 70, and reproduces the extracted WAV file. That is, the sound generator 4 generates a sound of a pattern according to the signal from the signal generator 2. As a result, the sound of the pattern set by the setting unit 7 is generated from the sound generation unit 4 as an alarm sound.

(3) Summary The sound generation device 1 according to the first aspect includes a sound generation unit 4 and a signal generation unit 2. The sound generator 4 can generate sounds of a plurality of patterns having different tones. The signal generation unit 2 outputs a signal corresponding to one of the plurality of patterns to the sound generation unit 4. The sound generator 4 generates a sound of a pattern according to the signal from the signal generator 2.

  With the above configuration, since the sound producing device 1 can generate sounds of a plurality of patterns with different tones, it is possible to share the configuration without changing the configuration of the sound producing device 1 for each sound of a plurality of patterns. It becomes.

  In the first aspect, the sound generation device 1 according to the second aspect further includes a setting unit 7 that sets a pattern corresponding to a signal output from the signal generation unit 2 to the sound generation unit 4 in the signal generation unit 2.

  With the above configuration, it is possible to set the pattern of the sound generated from the sound generator 4.

  In the sound generation device 1 according to the third aspect, in the second aspect, the setting unit 7 sets a pattern based on the setting signal from the parent device 9 in the signal generation unit 2.

  With the above-described configuration, it is possible to set a sound pattern to be generated from the sound generation unit 4 using the parent device 9 provided separately from the sound generation device 1.

  In the sound generation device 1 according to the fourth aspect, in the second aspect, the setting unit 7 includes an operation unit 71 that receives an operation from the user. The setting unit 7 sets a pattern based on the operation signal output from the operation unit 71 in the signal generation unit 2.

  With the above configuration, it is possible to set the pattern of the sound generated from the sound generation unit 4 by the sound generation device 1 alone.

  In the sound generation device 1 according to the fifth aspect, in any of the first to fourth aspects, the signal generation unit 2 generates a PWM signal whose frequency is variable as a signal. The sound generator 4 generates a sound according to the frequency and duty of the PWM signal. The signal generation unit 2 changes the frequency of the PWM signal, and changes the duty of the PWM signal according to the change of the frequency of the PWM signal.

  With the above-described configuration, since the period in which the duty of the PWM signal is small is generated as compared with the case where the duty of the PWM signal is constant, the sound generation device 1 can reduce power consumption.

  The sound generation device 1 according to the sixth aspect further includes a housing 11 for housing the sound generation unit 4 in the fifth aspect. The signal generation unit 2 changes the frequency of the PWM signal to a frequency including the first frequency f1 and the second frequency f2. The difference between the resonant frequency f0 of the case 11 and the first frequency f1 is smaller than the difference between the resonant frequency f0 of the case 11 and the second frequency f2. The signal generation unit 2 makes the duty when the frequency of the PWM signal is the first frequency f1 larger than the duty when the frequency of the PWM signal is the second frequency f2.

  According to the above configuration, the duty of the PWM signal when generating the sound of the first frequency f1 in which the casing 11 easily resonates is increased, and the instantaneous sound pressure of the sound of the first frequency f1 is efficiently increased. Therefore, the sound generation device 1 can increase the sound pressure of the sound generated from the sound generation unit 4. When the sound generation unit 4 generates an audible sound, the sound generation device 1 can increase the volume. However, this configuration is not an essential configuration of the sound producing device 1. For example, the signal generation unit 2 determines the duty when the frequency of the PWM signal is close to the frequency at which human ear sensitivity is high than the duty when the frequency of the human ear is far from high frequency. It may be configured to be large.

  The sound generation device 1 according to a seventh aspect is the sound generator 1 according to the sixth aspect, wherein the signal generation unit 2 performs the first period T10 in which the frequency of the PWM signal is the first frequency f1 and the frequency of the PWM signal is the second frequency f The period is longer than T20.

  With the above configuration, the ratio of the generation period of the sound of the first frequency f1 having a large instantaneous sound pressure increases, and the sound generation device 1 can increase the sound pressure of the sound generated from the sound generation unit 4. However, this configuration is not an essential configuration for the sound producing device 1. For example, in the sound producing device 1, the second period T20 in which the frequency of the PWM signal is the second frequency f2 and the frequency of the PWM signal is the first frequency f1 It may be longer than a certain first period T10. This makes it possible to further reduce power consumption.

  In the sound generation device 1 according to the eighth aspect, in any one of the fifth to seventh aspects, the signal generation unit 2 gradually changes the frequency of the PWM signal over a plurality of bands as time passes. In addition, the signal generation unit 2 changes the duty of the PWM signal for each of a plurality of bands.

  With the above configuration, the signal generation unit 2 changes the duty of the PWM signal for each band, so that the signal generation unit 2 generates the PWM signal compared to when both the frequency and the duty of the PWM signal are gradually changed. Processing is easy.

  In the sound generation device 1 according to the ninth aspect, in any one of the fifth to seventh aspects, the signal generation unit 2 gradually changes the frequency of the PWM signal as time passes. Further, the signal generation unit 2 changes the duty of the PWM signal to a duty corresponding to the frequency of the PWM signal.

  With the above configuration, the duty of the PWM signal gradually changes in accordance with the change of the PWM signal. Therefore, the sound generation device 1 can gradually change the sound pressure of the sound generated from the sound generation unit 4.

  The sound producing device 1 according to the tenth aspect further includes a housing 11 for housing the sound producing unit 4 in the fifth aspect. As time passes, the signal generation unit 2 generates the second frequency f2 in which the difference between the frequency of the PWM signal, the first band B1 including the first frequency, and the resonance frequency of the housing 11 is larger than the first frequency f1. It gradually changes over a plurality of bands including the second band B2 that includes. Also, the duty of the PWM signal is changed for each of a plurality of bands. The amount of change in the frequency of the PWM signal per unit time when the frequency of the PWM signal changes in the first band B1 is taken as a first change amount Δ1. A change amount of the frequency of the PWM signal per unit time when the frequency of the PWM signal changes in the second band B2 is set as a second change amount Δ2. The signal generation unit 2 changes the frequency of the PWM signal so that the first change amount Δ1 becomes smaller than the second change amount Δ2.

  With the above configuration, the sound generation device 1 can increase the sound pressure of the sound generated by the sound generation unit 4 by lengthening the generation period of the sound in the first band B1 including the first frequency f1. However, this configuration is not an essential configuration of the sound producing device 1, and the amount of change of the frequency of the PWM signal per unit time may be constant.

  The sound producing device 1 according to the eleventh aspect further includes a housing 11 for housing the sound producing unit 4 in the fifth aspect. The signal generation unit 2 changes the duty of the PWM signal based on the radiation characteristic of the sound radiated from the sound generation unit 4 to the outside of the housing 11.

  With the above configuration, the sound generation device 1 can increase the sound pressure of the sound generated from the sound generation unit 4. When the sound generation unit 4 generates an audible sound, the sound generation device 1 can increase the volume.

  In the sound generation device 1 according to the twelfth aspect, in any of the fifth to eleventh aspects, the signal generation unit 2 corrects the duty of the PWM signal with a coefficient based on the frequency of the PWM signal.

  With the above configuration, it is possible to adjust the sound generated from the sound generation unit 4 according to the frequency of the PWM signal.

  In the sound generation device 1 according to the thirteenth aspect, in any one of the fifth to twelfth aspects, the signal generation unit 2 sets the duty of the PWM signal so that the change width of the duty of the PWM signal falls within a predetermined range. Change.

  With the above configuration, the sound generation device 1 can suppress that the difference between the instantaneous sound pressures of the sounds generated from the sound generation unit 4 becomes too large. However, this configuration is not an essential configuration of the sound producing device 1, and the change width of the duty of the PWM signal may be outside the predetermined range.

  In the sound generation device 1 according to the fourteenth aspect, in any one of the fifth to thirteenth aspects, the frequency of the PWM signal is 20 Hz or more and 20 kHz or less.

  With the above-described configuration, it is possible to reduce power consumption in the sound generation device 1 that generates human audible sound.

  The alarm device 10 according to the fifteenth aspect is the sound generation device 1 according to any one of the first to fourteenth aspects, and the sound generation unit 4 generates an alarm sound.

  With the above configuration, since the alarm device 10 generates a period in which the duty of the PWM signal is small, power consumption can be reduced as compared with the case where the duty of the PWM signal is constant.

  The sensor 100 according to the sixteenth aspect includes the alarm device 10 according to the fifteenth aspect and the detection unit 6 for detecting a specific event, and the alarm device 10 generates an alarm sound when the detection unit 6 detects a specific event. generate.

  According to the above configuration, since the sensor 100 generates a period in which the duty of the PWM signal is small, power consumption can be reduced as compared with the case where the duty of the PWM signal is constant.

DESCRIPTION OF SYMBOLS 1 sound generation device 10 alarm device 100 sensor 11 housing 2 signal generation unit 3 acoustic circuit 4 sound generation unit 6 detection unit 7 setting unit 71 operation unit 9 master unit f1 first frequency f2 second frequency T10 first period T20 second period B1 first band B2 second band Δ1 first change amount Δ2 second change amount

Claims (16)

A sound generator capable of generating sounds of a plurality of patterns having different tones;
And a signal generation unit that outputs a signal corresponding to any one of the plurality of patterns to the sound generation unit.
The sound generation device, wherein the sound generation unit generates a sound of a pattern according to the signal from the signal generation unit. The sound generation device according to claim 1, further comprising: a setting unit configured to set, in the signal generation unit, a pattern corresponding to the signal output from the signal generation unit to the sound generation unit. The sound generation device according to claim 2, wherein the setting unit sets, in the signal generation unit, a pattern based on a setting signal from a parent device. The sound generation according to claim 2, wherein the setting unit has an operation unit that receives an operation from a user, and sets a pattern based on an operation signal output from the operation unit to the signal generation unit. apparatus. The signal generation unit generates a PWM signal whose frequency is variable as the signal,
The sound generator generates a sound according to the frequency and duty of the PWM signal.
The signal generation unit changes the frequency of the PWM signal, and changes the duty of the PWM signal according to a change in the frequency of the PWM signal. The sound producing device described in. The apparatus further comprises a housing for housing the sound generator,
The signal generator changes the frequency of the PWM signal to a frequency including a first frequency and a second frequency,
The difference between the resonant frequency of the housing and the first frequency is smaller than the difference between the resonant frequency of the housing and the second frequency,
The signal generation unit is characterized in that the duty when the frequency of the PWM signal is the first frequency is larger than the duty when the frequency of the PWM signal is the second frequency. The sound producing device described in. The signal generation unit may make the first period in which the frequency of the PWM signal is the first frequency longer than the second period in which the frequency of the PWM signal is the second frequency. The sound producing device described in. The signal generation unit is characterized in that the frequency of the PWM signal is gradually changed over a plurality of bands as time passes, and the duty of the PWM signal is changed for each of the plurality of bands. The sound-producing device as described in any one of -7. The signal generation unit gradually changes the frequency of the PWM signal as time passes, and changes the duty of the PWM signal to a duty corresponding to the frequency of the PWM signal. The sound production apparatus of any one of Claims 5-7. The apparatus further comprises a housing for housing the sound generator,
The signal generation unit includes, as time passes, a frequency of the PWM signal, and a second frequency in which a difference between a first band including the first frequency and a resonant frequency of the casing is larger than the first frequency. Gradually changing over a plurality of bands including the second band, and changing the duty of the PWM signal for each of the plurality of bands,
The amount of change in the frequency of the PWM signal per unit time when the frequency of the PWM signal changes in the first band is a first amount of change,
The amount of change of the frequency of the PWM signal per unit time when the frequency of the PWM signal changes in the second band is a second amount of change,
The sound generation device according to claim 5, wherein the signal generation unit changes the frequency of the PWM signal such that the first change amount is smaller than the second change amount. The apparatus further comprises a housing for housing the sound generator,
The sound generation device according to claim 5, wherein the signal generation unit changes a duty of the PWM signal based on a radiation characteristic of a sound radiated to the outside of the casing from the sound generation unit. The sound generation device according to any one of claims 5 to 11, wherein the signal generation unit corrects the duty of the PWM signal with a coefficient based on the frequency of the PWM signal. The sound generation device according to any one of claims 5 to 12, wherein the signal generation unit changes the duty of the PWM signal such that a change width of the duty of the PWM signal falls within a predetermined range. . The sound generation device according to any one of claims 5 to 13, wherein the frequency of the PWM signal is 20 Hz or more and 20 kHz or less. The sound generation device according to any one of claims 1 to 14, wherein
The alarm unit generates the alarm sound. An alarm device according to claim 15;
A detection unit for detecting a specific event,
The alarm device generates an alarm sound when the detection unit detects the specific event.

Images