JP5198110B2 - Fire alarm - Google Patents

Description

  The present invention relates to a residential fire alarm.

  Conventionally, residential fire alarms installed on ceilings and walls of detached houses and the like are known. This residential fire alarm uses a battery, an AC power source, or the like as a driving power source, and detects smoke or heat that is a cause of a fire to notify the residents of the surrounding area by an alarm sound such as a buzzer or sound.

  Also, this type of residential fire alarm is provided with a control circuit IC and the like. The control circuit IC uses a general-purpose microcontroller that uses a general-purpose crystal unit, and uses low power consumption (sleep and interrupt) and high-speed processing to detect the above-mentioned fire, as well as inspection and fault diagnosis processing, etc. Various control processes for fire alarms.

  By the way, the general-purpose microcontroller (control circuit IC) uses a general-purpose crystal resonator serving as a clock signal generation means (reference clock generation means) according to the application, or a CR circuit incorporated in the microcontroller, for example. There are various types such as those using high-speed internal clock signal generation means or those using these two. However, residential fire alarms have been required to reduce power consumption and extend their service life, and a general-purpose quartz crystal (reference clock) can be used to fulfill these requirements for the fire detection function of fire alarms. A microcontroller using signal generation means) and internal clock signal generation means is preferred.

  That is, for example, in the case of a smoke-type fire alarm, the microcontroller (specifically, the CPU of the microcontroller) causes the LED for smoke detection to emit light at intervals of several seconds to several tens of seconds (hereinafter, T [sec]). What is necessary is just to use a low-speed clock at this time. On the other hand, the microcontroller shifts from the sleep mode to the active mode when counting T seconds of the light emission cycle, and further starts the fire detection processing program and emits the LED to perform fire detection processing control at a high speed (several hundreds). μs, hereinafter, t [μsec]). And after a fire detection process is completed, it transfers to sleep mode again from active mode.

In other words, the fire detection function of the fire alarm uses only a low-frequency clock when timing the fire detection, so the entire microcontroller consumes less power, and a high-speed clock is used when controlling the fire detection process. It uses to perform high-speed processing, and as a result, shortens the time of high power consumption and suppresses the power consumption of the microcontroller.
Note that the timing accuracy (frequency accuracy) of the light emission period is not strictly required. Specifically, the light emission period is determined based on the power consumption of the entire fire alarm and predetermined conditions defined by the Fire Service Law. It suffices to meet the timing accuracy (frequency accuracy) to the extent that a fire can be detected within a time (within 60 seconds). Therefore, the frequency accuracy is satisfied as long as the reference clock signal generating means and the internal clock signal generating means of the general-purpose microcontroller as described above.

Furthermore, the fire alarm is provided with an alarm output unit that receives an alarm output signal output from the control circuit IC when a fire, a battery voltage drop, or the like is detected and outputs an alarm (for example, Patent Document 1). reference).
JP 2006-048194 A

The alarm output unit includes, for example, a coil that outputs and amplifies an ON / OFF alarm output signal output from the control circuit IC, and alarm output means such as a buzzer or a speaker. Also, it is composed of an oscillation circuit that modulates an ON / OFF alarm output signal output from the control circuit IC to a predetermined frequency, an amplifier circuit that amplifies the signal, and a buzzer or speaker that outputs the amplified alarm signal. Some are.
On the other hand, the fire alarm is configured to output an alarm with a sound pressure of 70 dB or more, as defined by the Fire Service Law standard. Then, it is preferable to output a warning at a frequency of about 3 KHz at which a person, particularly an elderly person, can reliably hear the warning sound, and the warning output signal sent to the buzzer is set to a frequency of 3 KHz. In addition, for example, the structure of the buzzer storage part of the fire alarm is designed in consideration of resonance due to the structure so that the frequency band of the alarm sound when output from the buzzer is 2 KHz to 4 KHz centering on 3 KHz. Has been made.

  Furthermore, there are various requests for fire alarms, such as reducing power consumption, extending the life of fire alarms, or reducing costs by reducing the number of parts. From the above, the microcontroller outputs alarm output signals when alarms are output. It is effective to perform oscillation control.

However, due to the characteristics of the microcontroller itself, it is known that the internal clock signal generator means that the timekeeping accuracy (frequency accuracy) varies greatly depending on temperature and voltage, and the microcontroller outputs signal for alarm output. Even when performing oscillation control by the above, because the alarm output signal is output based on the signal generated by the internal clock signal generating means, the predetermined output interval and the predetermined frequency as described above are set. Cannot recognize whether the alarm output signal is output correctly.
That is, in the above-described example, there is a problem that the buzzer alarm output is not surely performed with a preset sound pressure or tone color. In particular, fire alarms have been a serious problem because various functions are required to operate normally and reliably in a wide allowable temperature range.

  Therefore, as described above, the present invention can reliably operate various functions that are indispensable as a fire alarm device under various requests such as power consumption reduction, long life, or cost reduction by reducing the number of parts. The purpose is to provide a fire alarm for residential use. Specifically, in the alarm output function that requires high frequency accuracy to realize each of the above requirements, the CPU clock of the microcontroller using the clock signal generation means (clock source) with low frequency accuracy is used as the reference clock with high frequency accuracy. An object of the present invention is to provide a residential fire alarm capable of adjusting a CPU clock by a signal generating means and performing a reliable alarm output.

In order to achieve the above object, a fire alarm device according to a first aspect of the present invention generates a reference clock signal having a higher frequency accuracy than a control circuit unit having an internal clock signal generation unit and the internal clock signal generation unit. In a fire alarm including a reference clock signal generation unit and an alarm output unit that receives an alarm output signal from the control circuit unit and outputs an alarm, the control circuit unit includes a modulation circuit, and the reference circuit Each time the clock signal is counted, the pulse count value of the internal clock signal is sequentially stored, and the difference between the stored pulse count values before and after the calculation is calculated, and the difference coincides with a predetermined specified value or falls within a predetermined specified value range. As described above, the frequency of the internal clock signal is corrected by modulating the frequency by the modulation circuit. Lifting and, and outputs the alarm output signal based on the frequency of the internal clock signal is maintained at said predetermined frequency to said alarm output means.

The invention of claim 2, in the fire alarm of claim 1, wherein the control circuit unit counts a predetermined time based on the internal clock signal is maintained at the predetermined frequency, each the predetermined time And outputting the alarm output signal to the alarm output means.

  According to the present invention, the residential fire alarm device of the present invention can perform reliable fire alarm while realizing reduction of power consumption, longer life, cost reduction by reducing the number of parts, and the like. .

Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.
(Configuration and function of fire alarm)
FIG. 1 is a schematic configuration diagram showing a fire alarm device 100 that is an example of a fire alarm device of the present invention and detects a fire factor such as smoke and issues an alarm with a buzzer sound or voice.
As shown in FIG. 1, a fire alarm 100 includes a power supply unit 50 such as a battery or an AC power supply, a sensor circuit unit 30 for detecting a fire, a control circuit unit 1 (microcontroller 1), an alarm output unit 40, and an operation display unit. 60 and a switch input unit 70.
In the present embodiment, a smoke-type residential fire alarm using a battery for the power supply unit 50 and a buzzer for the alarm output unit 40 will be described.

The fire alarm 100 is driven by the power supply unit 50 and monitors the occurrence of a fire in a predetermined monitoring area such as a bedroom. When a fire occurs in the monitoring area, the fire alarm 100 converts a fire factor into a predetermined physical quantity in the sensor circuit unit 30 and transmits a fire detection signal to the control circuit unit 1. The control circuit unit 1 is a general-purpose microcontroller provided with a CPU that performs various controls. The control circuit unit 1 receives a fire detection signal, performs a fire determination process, and determines that a fire has been detected, and outputs an alarm output signal to the alarm output unit 40. The alarm is sounded by a buzzer (not shown) which is an alarm output means of the alarm output unit 40. Further, a lighting control signal is sent to the operation display unit 60 to light up and display an operation indicator lamp (not shown). The switch input unit 70 is an operation unit (alarm sound stop button) for stopping the buzzer sounding, and is also a test switch.
In addition, the fire alarm 100 is used as a reference clock signal generation unit (reference clock source) of the control circuit unit 1 (hereinafter referred to as the microcontroller 1), for example, an external frequency 32 according to the frequency accuracy requested by the user. A general-purpose crystal resonator (crystal oscillator) 6 having .768 kHz and frequency accuracy of ± 20 ppm crystal is provided.

Next, various controls of the fire alarm 100 by the microcontroller 1 and the microcontroller 1 will be described.
As shown in FIG. 1, the microcontroller 1 includes an oscillation circuit 5 that oscillates the crystal oscillator 6, and a timer 1 (auxiliary clock counter) (number 7 in FIG. 1) that receives and counts the oscillation signal of the crystal oscillator 6. , Hereinafter referred to as “timer 1 (7)”), CPU 2 operating in the sleep mode and active mode based on the timing of timer 1 (7), RAM 3 and ROM 4, and internal clock 8 (internal clock signal generating means 8). ) And a timer 2 (main clock counter) (number 9 in FIG. 1, hereinafter referred to as “timer 2 (9)”) that counts by inputting the oscillation signal of the internal clock 8 and CR of the internal clock, etc. Is provided with a setting unit 10 (modulation circuit 10) that can be modulated and set by bit setting by software (CPU).

The timer 1 (7) of the microcontroller 1 counts the oscillation signal oscillated from the crystal oscillator 6 which is a reference clock signal generation means, and counts 1 [sec] (every 32768 counts). ) Is sent to the CPU 2. When the CPU 2 receives the interrupt signal, the CPU 2 shifts from the sleep mode to the active mode. In the active mode, the CPU 2 activates the internal clock 8 to perform various control processes.
Note that the microcontroller 1 operates at a current consumption of 300 μA at 3 V of 1 MHz in the active mode, and requires a current consumption of 1.6 μA at 3 V in the sleep mode. The clock routine operates at 130 μA.

Specifically, the CPU 2 of the microcontroller 1 activates a fire detection determination program every 16 [sec], for example, and causes the smoke detection light emitting LED provided in the sensor circuit unit 30 to emit 200 [msec] pulses. Then, the light reception output received and amplified by the light receiving element (photodiode) of the sensor circuit unit 30 is input, and fire detection determination processing is performed.
The internal clock 8 of the microcontroller 1 is a main clock that generates a signal having a frequency of about 1 MHz by an oscillation circuit such as a CR and performs various control processes of the CPU 2.

  Further, the CPU 2 activates the battery voltage drop detection program when, for example, 50 minutes have been counted other than when the fire detection judgment is made, and performs a battery voltage drop detection judgment process. Similarly, the CPU 2 executes various control processes at a preset timing.

  When it is necessary to perform alarm output in the middle of each control process or as a result, the CPU 2 activates or shifts to an alarm output program to perform alarm output control. For example, when fire alarm output is performed, when an alarm output signal is output from the microcontroller 1, the CPU 2 outputs a 1 MHz frequency signal generated by internal clock generation ON / OFF at intervals of 150 [μsec]. That is, the alarm output signal sent to the buzzer generates an alarm signal having a frequency of 3 KHz by outputting a signal having a frequency of 1 MHz ON / OFF every 150 [μsec].

Next, the operation at the time of correcting the internal clock is used with reference to FIG.
In the present embodiment, the microcontroller 1 uses a general-purpose one, and the internal clock 8 changes with respect to a temperature change within an allowable temperature range (−10 to 50 ° C.) in which a fire alarm is required. The frequency accuracy is a rate of 0.05% / ° C. Since the frequency accuracy varies greatly depending on the current difference caused by the individual resistance difference for the internal clock, the frequency accuracy of the internal clock 8 also differs in the comparison for each fire alarm. On the other hand, the crystal oscillator 6 serving as the reference clock signal generating means has ± 20 ppm, and the frequency accuracy is extremely high as compared with the internal clock 8. As described above, the crystal oscillator 6 has a low frequency (about 32 KHz), and the internal clock signal generation means (CR oscillation circuit) built in the internal clock 8 has a high frequency of 1 MHz.

(Correction action)
[1] At a predetermined timing, the CPU 2 activates an “internal oscillator adjustment” program stored in the ROM 4 (such as the RAM 3) in the active mode, and counts the timer 1 (7) and the timer 2 (9). Is reset (S1).
[2] The crystal oscillator 6 is set as the clock source of the timer 1 (7) (S2).
[3] The CPU 2 stores and stores the count number of the internal clock by the timer 2 (9) when the timer 1 (7) counts 1 (S3, S4) (RAM3).
(The timer 1 may be divided to further improve the 1-count accuracy.)

[4] The CPU 2 calculates (calculates) the difference between the count value of the timer 2 (9) stored last time and the count value of the timer 2 (9) stored this time (S5).
[5] The difference calculation value is compared with a predetermined specified value (or within a predetermined specified value range) (S6).
[6-1] When the calculated difference value coincides with a predetermined specified value (or is within a predetermined specified value range), it is assumed that the internal clock 8 is not time-shifted (the internal clock 8 has an error). It is determined that the alarm output signal is within the allowable error range and that the alarm output signal can be generated at the designed frequency and at a predetermined interval), and the timer 1 (7) and timer 2 (9) counts are stopped to adjust the built-in oscillator. Is finished (S9, 10).

  [6-2] When the calculated difference value is smaller than the predetermined specified value (or below the predetermined specified value range), it is assumed that the internal clock 8 has a time lag (delay) (internal). The CPU 2 determines that the error of the clock 8 is out of the allowable error range and the alarm output signal cannot be generated at the designed frequency and at a predetermined interval), and the CPU 2 sets the timer adjuster (setting unit (modulation circuit) 10). Is set by changing the bit so that the resistance is set one step faster (S7).

  [6-3] When the calculated difference value is larger than the predetermined specified value (or when it is equal to or larger than the predetermined specified value range), it is assumed that the internal clock has a clock error (advance) (internal clock). The CPU 2 determines that the error of 8 is outside the allowable error range and the alarm output signal cannot be generated at the designed frequency and at a predetermined interval), and the CPU 2 sets the timer adjuster (setting unit (modulation circuit) 10). The bit is changed and set so that the resistance is set one step slower (S8).

  [7] Based on the internal clock 8 changed by the timer adjuster (setting unit (modulation circuit) 10), until the difference calculation value matches a predetermined specified value (or until it falls within a predetermined specified value range) ) Repeat [2] to [5] and [6-2] (or [6-3]).

  As described above, since the internal clock is regularly corrected using the fire alarm 100 for homes of the present invention and the reference clock signal generating means with high frequency accuracy, an alarm that requires processing with high frequency accuracy is required. In output control, it is possible to always generate and output an alarm output signal at a predetermined frequency and a predetermined interval at the time of design.

Although the embodiment of the present invention has been described with respect to a fire alarm using a buzzer, the present invention can also be used when an alarm is output by a speaker. That is, the alarm output signal voltage, frequency, etc., such as voice data and voice IC, are designed in advance so that the sound emitted from the speaker can be recognized as a voice message with a volume that can be surely heard by humans. If the fire alarm is used, the internal clock is corrected at any time, and an alarm output signal with high frequency accuracy can be continuously output to the speaker, so that the voice message is not delayed or turned quickly. Or the pitch doesn't go off.
Moreover, although the embodiment of the present invention has been described with respect to the case where a general-purpose crystal resonator (crystal oscillator) with high frequency accuracy is externally attached to the microcontroller, it may be built in the microcontroller.

  The present invention can be applied as appropriate without departing from the scope of the present invention. For example, when transmitting or receiving a sound signal or a fire alarm interlocking signal from one residential fire alarm to another residential fire alarm by high-speed processing control, the internal clock of the present invention is corrected. An accurate transmission signal can be transmitted and received, and a highly reliable fire alarm system can be constructed.

  The present invention can also be applied to gas alarms and crime prevention devices.

It is a figure which shows the schematic circuit structure of the fire alarm for houses which concerns on this invention. It is an operation | movement flowchart at the time of correct | amending an internal clock.

Explanation of symbols

100 Residential fire alarm 1 Control circuit (microcontroller)
2 CPU
3 RAM
4 ROM
5 Oscillator 6 Crystal oscillator (Crystal, 32.768 KHz (reference clock signal generation means))
7 Timer 1 (auxiliary clock counter)
8 Internal clock (Internal clock signal generation means)
9 Timer 2 (Main clock counter)
10 Setting section (modulation circuit)
30 Sensor circuit (detection unit)
40 Alarm output section (alarm output means, buzzer)
50 Power supply unit 60 Operation display unit 70 Switch input unit

Claims (2)

A control circuit unit having an internal clock signal generation unit, a reference clock signal generation unit that generates a reference clock signal with higher frequency accuracy than the internal clock signal generation unit, and an alarm that receives an alarm output signal from the control circuit unit In the fire alarm having an alarm output means for performing output, the control circuit unit includes a modulation circuit, and sequentially stores the pulse count value of the internal clock signal every time the reference clock signal is counted. By calculating the difference between the stored pulse count values before and after, and correcting the frequency of the internal clock signal by the modulation circuit so that the difference matches or falls within a predetermined specified value range. maintaining the frequency of the internal clock signal to a predetermined frequency, the frequency of the internal clock signal is maintained at said predetermined frequency Fire alarm device and outputs the alarm output signal to said alarm output means Zui. The fire alarm device according to claim 1 , wherein the control circuit unit measures a predetermined time based on an internal clock signal maintained at the predetermined frequency, and outputs the alarm output signal at the predetermined time. A fire alarm that outputs to an alarm output means.

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