KR101475087B1 - Fire alarm device - Google Patents

Abstract

A fire detector comprising an integrated circuit which can be used for a plurality of models according to the type of a fire detection unit and a sound unit, comprising: a fire detection unit for detecting a physical quantity based on a fire phenomenon; Circuit 1 and selects either the smoke detecting section 2 or the heat detecting section 3 as a fire detecting section and the buzzer circuit 4 or the speaker circuit 5 as an acoustic section on the basis of the inputted ID identifying signal And performs a fire detection operation in accordance with the selected fire detection unit and an alarm operation in accordance with the selected sound unit.

Fire detection, smoke detection, heat detection, sound, buzzer, speaker

Description

FIRE ALARM DEVICE

The present invention relates to a fire alarm having an integrated circuit.

A conventional fire alarm is a configuration in which power is supplied by a power source and a warning sound is output by an acoustic unit when a fire is detected by a fire detection unit (see, for example, Patent Document 1).

Patent Document 1: Japanese Patent Application Laid-Open No. 2004-362537

In a conventional fire alarm, a fire detection unit for detecting a physical quantity based on a fire phenomenon is used to detect smoke or to detect heat. There is also an acoustic unit for outputting an alarm sound, which is output by a buzzer or an output by sound. As a power supply unit for supplying a power source for operating the smoke alarm, there is a method using a DC voltage such as a battery or an AC voltage such as a commercial power supply.

In addition, a plurality of models are constituted by adopting a circuit configuration depending on the type of a fire detection unit, an acoustic unit, and a power supply unit to be used.

On the other hand, it is desirable to reduce the size of the fire alarm and the number of the manufacturing processes by using an integrated circuit (IC: Integrated Circuit) in which components constituting the fire alarm are formed into chips.

However, in the case of using an integrated circuit in which components constituting a fire alarm are used, an integrated circuit dedicated to the type of the circuit in which a circuit is formed according to the type of a fire detection unit, an acoustic unit, and a power supply unit is used.

Assuming that an integrated circuit having a plurality of functions is used, it is conceivable to change the function of operating by inputting a predetermined identification signal to a terminal (I / O port, etc.) provided in the integrated circuit.

However, a dedicated terminal for inputting such an identification signal needs to be provided in the integrated circuit, which increases the number of terminals of the integrated circuit.

This problem is more significant as the functions of the integrated circuit are larger.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a fire alarm having an integrated circuit which can be used for a plurality of models corresponding to at least a fire detection unit and an acoustic unit.

In addition, a fire alarm capable of reducing the number of terminals provided in the integrated circuit is obtained.

A fire alarm according to the present invention includes a fire detection unit for detecting a physical quantity based on a fire phenomenon and an integrated circuit to which at least an acoustic unit for outputting an alarm sound can be connected, and the integrated circuit includes a smoke detection unit A light receiving circuit connecting terminal to which a light receiving circuit constituting a smoke detecting section as a fire detecting section can be connected, and a light detecting circuit connecting terminal to which a heat detecting section as a fire detecting section can be connected, A buzzer circuit connection terminal to which a buzzer circuit as the acoustic unit can be connected; a speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic unit can be connected; A light receiving amplifier circuit constituting a smoke detecting section as a fire detecting section, A digital-to-analog converter circuit connected to the connection terminal and constituting a speaker circuit as the acoustic unit; a digital-analog conversion circuit connected to the audio amplifying circuit to constitute a speaker circuit as the acoustic unit; And a control unit connected to the digital-analog conversion circuit, wherein the control unit controls the light-receiving unit, the light-detecting unit, the buzzer circuit connection terminal, The buzzer circuit or the speaker circuit is selected as the acoustic portion, and a fire detection operation according to the selected fire detection portion and an alarm operation according to the selected acoustic portion are performed.

The smoke alarm according to the present invention includes an integrated circuit at least connected to a fire detection unit for detecting a physical quantity based on a fire phenomenon, an acoustic unit for outputting an alarm sound, and a power supply unit for supplying power, A light receiving circuit connecting terminal to which a light receiving circuit constituting a smoke detecting section as a fire detecting section can be connected; and a light detecting circuit connecting terminal as a fire detecting section, A buzzer circuit connection terminal to which a buzzer circuit as the acoustic section can be connected, a speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic section can be connected, A power supply connection terminal to which a DC voltage source or an AC voltage source can be connected, A sound amplification circuit connected to the light receiving circuit connection terminal and constituting a smoke detection section as the fire detection section; an audio amplifier circuit connected to the speaker connection terminal and constituting a speaker circuit as the sound section; A constant voltage circuit which is connected to the power supply connection terminal and supplies a DC voltage supplied from the DC voltage source or the AC voltage source serving as the power supply section to each component as a predetermined constant voltage, And a control section connected to the light-receiving circuit connection terminal, the light-receiving and amplifying circuit, the heat detecting section connecting terminal, the buzzer circuit connecting terminal, the digital-analog converting circuit and the constant voltage circuit, Based on the ID identification signal, Wherein the control unit selects the smoke detection unit or the heat detection unit and selects the buzzer circuit or the speaker circuit as the acoustic unit and selects the DC voltage source or the AC voltage source as the power source unit, , An alarm operation according to the selected acoustic unit, and a predetermined operation according to the selected power unit.

The smoke detector according to the present invention includes an integrated circuit capable of connecting at least a fire detection unit for detecting a physical quantity based on a fire phenomenon and an acoustic unit for outputting an alarm sound, A light receiving circuit connecting terminal to which a light receiving circuit constituting a smoke detecting section as a fire detecting section can be connected and a light receiving circuit connecting terminal to which a heat detecting section as a fire detecting section can be connected A buzzer circuit connection terminal to which a buzzer circuit as the acoustic section can be connected; a speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic section can be connected; A light receiving amplifier circuit constituting a smoke detecting section as the fire detecting section, A digital-to-analog conversion circuit connected to the picker connection terminal and constituting a speaker circuit as the acoustic portion, a digital-analog conversion circuit connected to the audio amplification circuit and constituting a speaker circuit as the acoustic portion, The smoke detecting section or the heat detecting section as the fire detecting section is connected to the light receiving amplifier circuit, the heat detecting section connecting terminal, the buzzer circuit connecting terminal, and the digital analog converting circuit, And a control section for selecting the buzzer circuit or the speaker circuit as the acoustic section and performing a fire detection operation in accordance with the selected fire detection section and an alarm operation in accordance with the selected acoustic section, The input voltage from the terminal is converted into the ID identification signal of the acoustic unit And, characterized in that selecting the buzzer circuit as the sound unit when the input voltage of the buzzer circuit connecting terminals when the pull-up (pull-up) or pull-down (pull-down).

The smoke detector according to the present invention includes an integrated circuit capable of connecting at least a fire detection unit for detecting a physical quantity based on a fire phenomenon and an acoustic unit for outputting an alarm sound, A light receiving circuit connecting terminal to which a light receiving circuit constituting a smoke detecting section as a fire detecting section can be connected and a light receiving circuit connecting terminal to which a heat detecting section as a fire detecting section can be connected A buzzer circuit connection terminal to which a buzzer circuit as the acoustic section can be connected; a speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic section can be connected; A light receiving amplifier circuit constituting a smoke detecting section as the fire detecting section, A digital-to-analog conversion circuit connected to the picker connection terminal and constituting a speaker circuit as the acoustic portion, a digital-analog conversion circuit connected to the audio amplification circuit and constituting a speaker circuit as the acoustic portion, The smoke detecting section or the heat detecting section as the fire detecting section is connected to the light receiving amplifier circuit, the heat detecting section connecting terminal, the buzzer circuit connecting terminal, and the digital analog converting circuit, And a control unit for selecting the buzzer circuit or the speaker circuit as the acoustic unit and performing a fire detection operation according to the selected fire detection unit and an alarm operation according to the selected acoustic unit, The input voltage from the terminal is converted into an ID identification signal And selects the smoke detection section as the fire detection section when the input voltage of the heat detection section connection terminal is pulled up or pulled down.

The smoke detector according to the present invention includes an integrated circuit capable of connecting at least a fire detection unit for detecting a physical quantity based on a fire phenomenon and an acoustic unit for outputting an alarm sound, A light receiving circuit connecting terminal to which a light receiving circuit constituting a smoke detecting section as a fire detecting section can be connected and a light receiving circuit connecting terminal to which a heat detecting section as a fire detecting section can be connected A buzzer circuit connection terminal to which a buzzer circuit as the acoustic section can be connected; a speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic section can be connected; A light receiving amplifier circuit constituting a smoke detecting section as the fire detecting section, A digital-to-analog conversion circuit connected to the picker connection terminal and constituting a speaker circuit as the acoustic portion, a digital-analog conversion circuit connected to the audio amplification circuit and constituting a speaker circuit as the acoustic portion, The smoke detecting section or the heat detecting section as the fire detecting section is connected to the light receiving amplifier circuit, the heat detecting section connecting terminal, the buzzer circuit connecting terminal, and the digital analog converting circuit, And a control unit for selecting the buzzer circuit or the speaker circuit as the acoustic unit and performing a fire detection operation according to the selected fire detection unit and an alarm operation according to the selected acoustic unit, The temperature detection signal based on the input voltage from the terminal ID to identify the signal of the re-detection, and when the temperature detector detects the temperature that is obtained by the signal range of the predetermined temperature tomorrow, characterized by selecting the heat detector as the fire detecting unit.

The smoke detector according to the present invention includes an integrated circuit capable of connecting at least a fire detection unit for detecting a physical quantity based on a fire phenomenon and an acoustic unit for outputting an alarm sound, A light receiving circuit connecting terminal to which a light receiving circuit constituting a smoke detecting section as a fire detecting section can be connected and a light receiving circuit connecting terminal to which a heat detecting section as a fire detecting section can be connected A buzzer circuit connection terminal to which a buzzer circuit as the acoustic section can be connected; a speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic section can be connected; A light receiving amplifier circuit constituting a smoke detecting section as the fire detecting section, A digital-to-analog conversion circuit connected to the picker connection terminal and constituting a speaker circuit as the acoustic portion, a digital-analog conversion circuit connected to the audio amplification circuit and constituting a speaker circuit as the acoustic portion, The smoke detecting section or the heat detecting section as the fire detecting section is connected to the light receiving amplifier circuit, the heat detecting section connecting terminal, the buzzer circuit connecting terminal, and the digital analog converting circuit, And a control unit for selecting the buzzer circuit or the speaker circuit as the acoustic unit and performing a fire detection operation in accordance with the selected fire detection unit and an alarm operation in accordance with the selected acoustic unit, Or the heat detector, and the buzzer circuit or the buzzer Wherein the control unit controls the smoke detection unit or the heat detection unit and the buzzer circuit or the speaker circuit that are selected based on the ID identification signal and the buzzer circuit or the speaker circuit to match the ID information A predetermined abnormal output operation is performed.

The present invention is characterized by selecting a smoke detection unit or a heat detection unit as a fire detection unit, selecting a buzzer circuit or a speaker circuit as an acoustic unit, performing a fire detection operation according to the selected fire detection unit, As shown in Fig. Therefore, the integrated circuit can be used for a plurality of models according to the types of the fire detection unit and the acoustic unit.

Further, based on the input ID identification signal, a smoke detection unit or a heat detection unit is selected as a fire detection unit, a buzzer circuit or a speaker circuit is selected as an acoustic unit, a DC voltage source or an AC voltage source is selected as a power supply unit, An alarm operation according to the selected acoustic unit, and a predetermined operation according to the selected power supply unit. Therefore, the integrated circuit can be used for a plurality of models depending on the type of the fire detection unit, the acoustic unit, and the power supply unit.

When the input voltage from the buzzer circuit connection terminal is the ID identification signal of the acoustic unit and the input voltage of the buzzer circuit connection terminal is pulled up or pulled down, do. Therefore, the number of terminals provided in the integrated circuit can be reduced.

Also, the input voltage from the heat detecting section connection terminal is used as the ID identification signal of the fire detection section, and when the input voltage of the heat detection section connection terminal is pulled up or pulled down, the smoke detection section is selected as the fire detection section. Therefore, the number of terminals provided in the integrated circuit can be reduced.

Also, the temperature detection signal based on the input voltage from the thermal detection unit connection terminal is set as the ID identification signal of the fire detection unit, and the heat detection unit is selected as the fire detection unit when the detection temperature obtained by the temperature detection signal is within the predetermined temperature range . Therefore, the number of terminals provided in the integrated circuit can be reduced.

When the ID information does not match the smoke detection unit or the heat detection unit and the buzzer circuit or the speaker circuit selected based on the ID identification signal, a predetermined abnormal output operation is performed. Therefore, erroneous connection to the integrated circuit or erroneous setting of the ID information can be detected.

MODES FOR CARRYING OUT THE INVENTION [

- Embodiment 1 -

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a smoke alarm according to a first embodiment. FIG.

As shown in Fig. 1, the smoke alarm has an integrated circuit 1. Fig.

The smoke detection unit 2 or the heat detection unit 3 is selectively connected to the integrated circuit 1 as a fire detection unit.

The buzzer circuit 4 or the speaker circuit 5 is selectively connected to the integrated circuit 1 as an acoustic unit.

In addition, a DC voltage source or an AC voltage source is selectively connected to the integrated circuit 1 as the power supply unit 8. [

An EEPROM (Electrically Erasable and Programmable Read Only Memory) 6 and a display unit 7 are connected to the integrated circuit 1.

This fire alarm operates by receiving power from the power supply unit 8, detects a physical quantity based on a fire phenomenon by a fire detection unit, and outputs an alarm sound by the acoustic unit.

In addition, the smoke alarm constitutes a plurality of models depending on the type of the components selectively connected to the integrated circuit 1.

For example, it is operated by a DC voltage source to detect a smoke caused by a fire and output a warning sound by a buzzer, or by an AC voltage source to detect heat by a fire and output a warning sound by a speaker It is possible to operate according to the type of the constituent part.

Thus, the integrated circuit 1 can be used for a plurality of models.

The type of the component selectively connected to the integrated circuit 1 is selected, for example, in accordance with the type of the fire alarm in the production of the fire alarm.

1 shows a state in which the smoke detecting portion 2 and the heat detecting portion 3 are connected together to the integrated circuit 1. In FIG.

1 shows a state in which the buzzer circuit 4 and the speaker circuit 5 are connected together to the integrated circuit 1. In addition,

The integrated circuit 1 includes a control section 10, an oscillator 11, a reset portion 12, a light receiving amplifier 24 constituting the smoke detecting section 2, and a speaker circuit 5 (DAC & LPF) 51 constituting the speaker circuit 5, an acknowledgment driving circuit 70, and a constant voltage circuit 80, which constitute the speaker amplifier 5,

The integrated circuit 1 is a semiconductor electronic component in which a plurality of electronic elements constituting each component are encapsulated in a chip and sealed in a small package.

The light receiving amplifier 24 corresponds to the light receiving amplifying circuit in the present invention.

The voice amplifier 52 corresponds to the voice amplifier circuit of the present invention.

The audio DAC & LPF 51 corresponds to the digital-analog conversion circuit of the present invention.

In addition, the integrated circuit 1 has a plurality of connection terminals (ports).

The light emitting circuit connection terminal 101 can be connected to an infrared LED (Light Emitting Diode) drive circuit 21 constituting the smoke detection section 2. [

The photodetection circuit connection terminal 102 can be connected to a photodiode (PD) conversion circuit 23 constituting the smoke detection section 2. [

The heat detecting portion 3 can be connected to the heat detecting portion connecting terminals 103 and 104. [

The abnormal signal output terminal 105 outputs an abnormal signal (to be described later) from the control section 10.

The EEPROM connection terminal 106 is connected to the EEPROM 6.

The buzzer circuit connection terminal 107 can be connected to the buzzer circuit 4. [

The speaker connection terminals 108 and 109 can be connected to the speaker 53 constituting the speaker circuit 5. [

The power supply connection terminal 110 may be connected to a DC voltage source or an AC voltage source as the power supply unit 8.

An ID identification signal (to be described later) related to the power supply unit 8 is input to the power supply ID terminal 111. [

The display unit 7 is connected to the connection terminals 112 and 113 for confirmation and the like.

The infrared LED driving circuit 21 corresponds to the light emitting circuit of the present invention.

The PD conversion circuit 23 corresponds to the light receiving circuit of the present invention.

The EEPROM connection terminal 106 corresponds to the storage unit connection terminal in the present invention.

The smoke detection unit 2 includes an infrared LED driving circuit 21, an infrared LED 22, and a PD conversion circuit 23.

The infrared LED driving circuit 21 is connected to the control unit 10 via the light emitting circuit connection terminal 101 and drives the infrared LED 22 according to an instruction from the control unit 10. [

The infrared LED 22 emits infrared light. The infrared light is scattered by the smoke flowing into the smoke detecting section 2. [

The PD conversion circuit 23 is connected to the light reception amplifier 24 through the light reception circuit connection terminal 102. [ The PD conversion circuit 23 receives scattered light emitted from the infrared LED 22 and scattered by the smoke.

The light receiving amplifier 24 is formed in the integrated circuit 1. The light receiving amplifier 24 is connected to the control section 10 and amplifies the light receiving signal of the PD conversion circuit 23 and inputs the amplified light receiving signal to the control section 10.

The control unit 10 intermittently emits the infrared LED 22 and converts the received light reception signal to AD (analog / digital), judges the presence or absence of smoke, judges occurrence of a fire do.

The heat detecting unit 3 is constituted by a resistor 31 and a thermistor 32.

The resistor 31 is connected to the control unit 10 through the heat detecting unit connection terminal 103. [

The thermistor 32 is connected in series with the resistor 31. [

The connection point of the resistor 31 and the thermistor 32 is connected to the control section 10 through the heat detection section connection terminal 104. [

The resistance value of the thermistor 32 is changed by the heat caused by the fire and the partial pressure ratio of the resistor 31 and the thermistor 32 is changed.

The control unit 10 intermittently supplies the voltage (temperature detection signal) input from the heat detection unit connection terminal 104 to the resistor 31 and the thermistor 32 through the heat detection unit connection terminal 103 as AD / Digital), detects the temperature, and judges occurrence of fire based on the detected temperature.

The detection of the temperature is performed by associating the range of the input voltage with the range of the detection temperature. For example, -50 ° C to 100 ° C is set for an input voltage of 0 to 5V.

The range of the detection temperature can be set arbitrarily. For example, it is preferable to set the temperature range (for example, 25 占 폚 占 10 占 폚) assumed to be in the normal state .

The EEPROM 6 is connected to the control unit 10 via an EEPROM connection terminal 106. [

The EEPROM 6 stores ID information that selects at least the smoke detection section 2 or the heat detection section 3 as the fire detection section and the buzzer circuit 4 or the speaker circuit 5 as the sound section, (10).

The operation of the control unit 10 based on this ID information will be described later.

In the first embodiment, the ID information is stored in an EEPROM (Electrically Erasable and Programmable Read Only Memory). However, the present invention is not limited to this, and other nonvolatile memory or ROM Or the like.

The buzzer circuit 4 is composed of a buzzer drive circuit 41 and a buzzer 42.

The buzzer drive circuit 41 is connected to the control unit 10 via the buzzer circuit connection terminal 107. [

The buzzer 42 is driven by the buzzer drive circuit 41.

An example of the circuit configuration of the buzzer circuit 4 will be described with reference to Fig.

2 is a diagram showing a circuit configuration when the heat detecting section 3 is connected as a fire detecting section and the buzzer circuit 4 is connected as an acoustic section.

As shown in FIG. 2, the buzzer circuit 4 is connected to a power supply line of a predetermined potential Vbat through a resistor R and a coil L. And the transistor Q is connected in series through the coil L and the diode D. The buzzer 42 is constituted by, for example, a piezoelectric buzzer BZ, one of which is connected to the power supply line and the other of which is grounded via the transistor Q.

Then, by providing a PWM (Pulse Width Modulation) signal from the control unit 10 to the base of the transistor Q, the transistor Q is driven to drive the buzzer 42 by the induced voltage generated in the coil L according to the PWM pulse.

2, when the buzzer circuit 4 is connected, the buzzer circuit connection terminal 107 is pulled down through the resistor RBZ.

The circuit configuration of the buzzer circuit 4 is not limited to this, and any circuit configuration can be used. In the first embodiment, a case in which the buzzer circuit connection terminal 107 is pulled down when the buzzer circuit 4 is connected is described. However, the present invention is not limited to this, The buzzer circuit connection terminal 107 may be pulled up at the time of connection.

1, the speaker circuit 5 is constituted by an audio DAC & LPF 51, an audio amplifier 52 and a speaker 53.

The audio DAC & LPF 51 is formed in the integrated circuit 1. The voice DAC & LPF 51 is connected to the control unit 10 and converts the digital voice signal output from the control unit 10 into an analog voice signal.

Also, the voice DAC & LPF 51 has a low pass filter, and cuts unnecessary frequency bands among the converted analog voice signals.

The voice amplifier 52 is formed in the integrated circuit 1. The voice amplifier 52 is connected to the speaker 53 via the speaker connection terminals 108 and 109. [ The voice amplifier 52 amplifies the analog voice signal generated by the voice DAC & LPF 51 and outputs it to the speaker 53.

The power supply unit 8 is constituted by a battery 81 or an AC voltage source (not shown) as a DC voltage source for generating a DC voltage. The power supply unit 8 is connected to the power supply connection terminal 110.

1 shows the case where the battery 81 as the power supply unit 8 is connected, an AC voltage source may be connected instead. The AC voltage source includes an AC power source for generating an AC voltage and an AC-DC conversion circuit for converting an AC voltage to a DC voltage.

The constant voltage circuit (80) is formed in the integrated circuit (1). The constant voltage circuit 80 is connected to the power supply unit 8 through the power supply connection terminal 110. Then, the DC voltage supplied from the power supply unit 8 is supplied to each constituent unit as a predetermined constant voltage.

The reset section 12 is formed in the integrated circuit 1. The reset unit 12 detects a voltage output from the constant voltage circuit 80 and performs a predetermined reset operation when the voltage is lower than a predetermined voltage. For example, when the voltage of the constant voltage circuit 80 drops, the control unit 10 stops the operation of the control unit 10 so that the control unit 10 does not perform an undefined operation.

The oscillator (11) is formed in the integrated circuit (1). The oscillator 11 is connected to the control unit 10 and supplies a predetermined operation clock to the control unit 10. [

The display section 7 is constituted by a green LED 71 and a red LED 72.

The green LED 71 is connected to the confirmation light driving circuit 70 through the confirmation light connection terminal 112.

The red LED 72 is connected to the confirmation light driving circuit 70 through the confirmation light connection terminal 113.

The confirmation drive circuit 70 is formed in the integrated circuit 1. The confirmation drive circuit 70 is connected to the control section 10 and drives the green LED 71 and the red LED 72 according to an instruction from the control section 10. [

The control unit 10 controls the entire fire alarm. In addition, based on the ID identification signal input by an operation to be described later, the operation is performed in accordance with the type of the component selectively connected to the integrated circuit 1. [

The detailed configuration of each part constituting the smoke alarm has been described above.

Next, the operation of the fire alarm according to the type of the component selectively connected to the integrated circuit 1 will be described.

(Fire detection operation)

3 and 4 are diagrams showing a circuit configuration when the smoke detecting section 2 is connected as a fire detecting section and the speaker circuit 5 is connected as an acoustic section.

First, the fire detection operation when the smoke detection unit 2 or the heat detection unit 3 is selectively connected as the fire detection unit will be described with reference to Figs. 1 to 4. Fig.

(Using the heat detecting unit 3)

2, the heat detecting portion 3 is connected to the heat detecting portion connecting terminals 103 and 104. In this case,

The infrared LED driving circuit 21 and the PD conversion circuit 23 of the smoke detection unit 2 shown in Fig. 1 are not connected to the light emitting circuit connection terminal 101 and the light reception circuit connection terminal 102 at this time.

In this state, the control unit 10 performs the fire detection operation in accordance with the connected fire detection unit, using the temperature detection signal inputted from the heat detection unit connection terminal 104 as the ID identification signal.

First, the control unit 10 energizes the resistor 31 and the thermistor 32 through the heat detection unit connection terminal 103 at a predetermined timing, such as when the power is turned on.

Then, the control unit 10 AD-converts the temperature detection signal (voltage) input from the heat detection unit connection terminal 104.

At this time, the thermistor 32 has a resistance value according to the installation environment due to its thermal characteristics. A voltage corresponding to the voltage division ratio of the thermistor 32 and the resistor 31 is input to the control unit 10 as a temperature detection signal.

Next, the control unit 10 determines whether or not the detection temperature obtained from the AD-converted temperature detection signal (AD value level) is within a predetermined temperature range. The temperature range is set so as not to include the upper limit value and the lower limit value of the detection range. For example, it is set at a temperature range assumed at a normal time (when a fire is not generated), for example, 25 ° C ± 10 ° C.

When the detection temperature is within the predetermined temperature range, the control unit 10 selects the heat detection unit 3 as the fire detection unit.

The case where the detection temperature is not within the predetermined temperature range will be described later.

Thereafter, a fire detection operation according to the selected heat detection unit 3 is performed.

That is, the control unit 10 intermittently energizes the resistor 31 and the thermistor 32 via the heat detection unit connection terminal 103 and outputs the voltage (temperature detection signal) input from the heat detection unit connection terminal 104 to the A / And judges occurrence of fire based on the detection temperature.

(Using the smoke detection unit 2)

1, the infrared LED driving circuit 21 of the smoke detection unit 2 is connected to the light emitting circuit connection terminal 101, and the PD conversion circuit 23 And is connected to the light receiving circuit connection terminal 102.

At this time, as shown in Fig. 3, the heat detecting portion connection terminal 104 is pulled up through the pull-up resistor Rpu. Further, the heat detecting section 3 is not connected to the heat detecting section connection terminal 103.

In this state, the control unit 10 performs the fire detection operation in accordance with the connected fire detection unit, using the input voltage when the heat detection unit connection terminal 104 is pulled up as the ID identification signal.

First, the control unit 10 AD-converts the voltage input from the heat detection unit connection terminal 104 at a predetermined timing, such as when the power is turned on.

At this time, since the heat detecting portion connection terminal 104 is pulled up, the high level voltage VDD is inputted to the control section 10. [ Therefore, the detection temperature obtained by the AD-converted input voltage (AD value level) is the temperature of the upper limit value.

Next, the control unit 10 determines whether or not the detection temperature is within a predetermined temperature range. The temperature range is set so as not to include the upper limit value and the lower limit value of the detection range. For example, it is set at a temperature range assumed at a normal time (when a fire is not generated), for example, 25 ° C ± 10 ° C.

As described above, since the detection temperature is the upper limit value, the controller 10 determines that the detection temperature is not within the predetermined temperature range. In this case, the control unit 10 selects the smoke detection unit 2 as a fire detection unit.

Thereafter, a fire detection operation according to the selected smoke detection unit 2 is performed.

That is, the control unit 10 drives the infrared LED driving circuit 21 to intermittently emit the infrared LED 22. The photodetection signal detected by the PD conversion circuit 23 is input to the control section 10 through the light receiving amplifier 24. [ The control unit 10 determines the presence or absence of smoke and determines the occurrence of a fire by performing AD conversion on the received light signal.

3, the case where the heat detecting portion connecting terminal 104 is pulled up has been described. However, as shown in Fig. 4, the heat detecting portion connecting terminal 104 may be pulled down through the pull down resistor Rpd, The input voltage may be used as the ID identification signal, and the smoke detection unit 2 may be selected as the fire detection unit.

That is, when the heat detecting portion connection terminal 104 is pulled down, the low level voltage GND is input to the control unit 10. [ At this time, the detection temperature obtained from the AD-converted input voltage (AD value level) is the temperature of the lower limit value. Thereby, the control unit 10 determines that the detection temperature is not within the predetermined temperature range.

(Alarm operation)

Next, an alarm operation when the buzzer circuit 4 or the speaker circuit 5 is selectively connected as the acoustic portion will be described with reference to Figs. 1 to 3. Fig.

(Using the buzzer circuit 4)

In the case of outputting the sound of the buzzer as the acoustic portion, the buzzer circuit 4 is connected to the buzzer circuit connection terminal 107 as shown in Fig.

At this time, the speaker 53 of the speaker circuit 5 shown in Fig. 1 is not connected to the speaker connection terminals 108 and 109. [

In this state, the control unit 10 performs an alarm operation in accordance with the connected acoustic unit by using the input voltage when the buzzer circuit connection terminal 107 is pulled down as the ID identification signal.

First, the control unit 10 detects a voltage value input from the buzzer circuit connection terminal 107 at a predetermined timing, such as when the power is turned on.

When the buzzer circuit 4 is connected, the buzzer circuit connection terminal 107 is pulled down through the resistor RBZ as shown in Fig. Therefore, the low-level voltage GND is input to the control unit 10. [

The control unit 10 determines whether or not the buzzer circuit connection terminal 107 is pulled down based on the detected voltage value.

Further, the judgment as to whether or not the voltage is pulled down is judged by whether or not the voltage value is within a predetermined range of zero bolt or its vicinity.

Then, when it is determined that the buzzer circuit connection terminal 107 is pulled down, the buzzer circuit 4 is selected as the acoustic unit.

Thereafter, an alarm operation is performed in accordance with the selected buzzer circuit 4.

That is, the control unit 10 determines the occurrence of a fire by the above-described fire detection operation, and outputs a PWM signal to the buzzer circuit connection terminal 107 when a fire is detected.

Thereby, the PWM signal is supplied to the transistor Q of the buzzer drive circuit 41 to drive the transistor Q, and the buzzer 42 is driven by the induced voltage generated in the coil L according to the PWM pulse.

(Using the speaker circuit 5)

1, the speaker 53 of the speaker circuit 5 is connected to the speaker connection terminals 108 and 109. In this case,

At this time, the buzzer circuit connection terminal 107 is not connected to the buzzer circuit 4, but is pulled up through the pull-up resistor Rsp as shown in Fig.

In this state, the control unit 10 performs an alarm operation in accordance with the connected acoustic unit by using the input voltage when the buzzer circuit connection terminal 107 is pulled up as an ID identification signal.

First, the control unit 10 detects a voltage value input from the buzzer circuit connection terminal 107 at a predetermined timing, such as when the power is turned on.

At this time, since the buzzer circuit connection terminal 107 is pulled up, the high-level voltage VDD is input to the control unit 10. [

The control unit 10 determines whether or not the buzzer circuit connection terminal 107 is pulled up based on the detected voltage value.

The determination as to whether the voltage is pulled up or not is determined based on whether the voltage value is within an upper limit value of the input voltage (for example, 5 V) or a predetermined range in the vicinity thereof.

When it is determined that the buzzer circuit connection terminal 107 is pulled up, the speaker circuit 5 is selected as the acoustic portion.

Thereafter, an alarm operation in accordance with the selected speaker circuit 5 is performed.

That is, the control unit 10 determines the occurrence of a fire by the above-described fire detection operation, and outputs a digital voice signal to the voice DAC & LPF 51 when a fire is detected.

The voice DAC & LPF 51 converts the digital voice signal from the control unit 10 into an analog voice signal, and blocks unnecessary frequency bands by the low pass filter.

The voice amplifier 52 amplifies the analog voice signal from the voice DAC & LPF 51 and outputs it to the speaker 53. The speaker 53 emits voice or the like by an analog voice signal.

In the above description, when it is judged that the buzzer circuit connection terminal 107 is pulled down, the buzzer circuit 4 is selected as the acoustic section, and when it is judged that the buzzer circuit connection terminal 107 is pulled up, The case where the circuit 5 is selected has been described.

The present invention is not limited to this, and the acoustic unit may be selected by reverse logic. That is, the buzzer circuit connection terminal 107 is pulled up when the buzzer circuit 4 is connected. When it is determined that the buzzer circuit connection terminal 107 is pulled up, And selects the speaker circuit 5 as an acoustic unit when it is determined that the buzzer circuit connection terminal 107 is pulled down.

(A predetermined operation according to the power supply unit 8)

Next, a predetermined operation when the DC voltage source or the AC voltage source is selectively connected as the power supply unit 8 will be described with reference to Fig.

1, an ID identification signal for identifying whether the power supply unit 8 is a DC voltage source or an AC voltage source is input to the power supply ID terminal 111. [

The ID identification signal input to the power supply ID terminal 111 is set to a high level voltage (for example, 5 V) when the power supply unit 8 indicates the cause of the DC voltage, and the power supply unit 8 And a low level voltage (for example, zero volt) is set when the cause of the AC voltage is indicated.

In this state, the control unit 10 performs a predetermined operation according to the connected power supply unit 8 based on the ID identification signal input from the power supply ID terminal 111. [

(Using a DC voltage source)

When a DC voltage source is used as the power supply unit 8, the battery 81 is connected to the power supply connection terminal 110 as shown in Fig.

An ID identification signal (for example, a high level) indicating that the power source unit 8 is a DC voltage is inputted to the power source ID terminal 111. [

First, the control unit 10 detects an ID identification signal input from the power supply ID terminal 111 at a predetermined timing, such as when the power is turned on.

Based on the detected voltage value of the ID identification signal, the control unit 10 determines whether the power supply unit 8 is a DC voltage source or an AC voltage source.

This determination is made based on whether or not the voltage value is within a predetermined range of a high level (for example, 5 V) or the vicinity thereof and whether or not the voltage value is within a predetermined range of a low level (for example, zero volts) .

If the power supply unit 8 determines that the power supply unit 8 is a direct current voltage source, the control unit 10 drives the confirmation light driving circuit 70 to turn on only the red LED 72 when necessary as a predetermined operation according to the power supply unit 8. [

(Using an AC voltage source)

When an AC voltage source is used as the power supply unit 8, an AC power supply and an AC-DC conversion circuit (not shown) are connected to the power supply connection terminal 110. [

An ID identification signal (for example, a low level) indicating that the power source unit 8 is an AC voltage is input to the power source ID terminal 111. [

In this state, the control unit 10 determines whether the power supply unit 8 is a DC voltage source or an AC voltage source, based on the detected voltage value of the ID identification signal.

The control unit 10 drives the confirmation light driving circuit 70 when necessary so that the red LED 72 and the green LED 71 are turned on when necessary as a predetermined operation corresponding to the power supply unit 8, .

The predetermined operation according to the power supply unit 8 is not limited to this, and an arbitrary operation can be performed. For example, when it is determined that the voltage is a direct current voltage source, a circuit or the like for monitoring the battery voltage connected to the outside may be driven.

The operation of the fire alarm according to the type of the component selectively connected to the integrated circuit 1 has been described above.

Next, an operation of detecting a state of a component connected to the integrated circuit 1 and an operation state selected by the control unit 10 will be described.

(Abnormal detection)

As described above, the control unit 10 performs the operation according to the type of the fire alarm according to the type of the component selectively connected to the integrated circuit 1.

Here, for example, in a manufacturing process of a smoke alarm or the like, when the constituent parts selected in accordance with the model are not connected to the integrated circuit 1 due to connection failure or the like, the control section 10 performs an operation different from the model.

An operation of detecting inconsistency between the connection state of the component connected to the integrated circuit 1 and the operation state selected by the control unit 10 will be described with reference to FIG.

It should be noted that this abnormality detection is assumed to be performed, for example, in the process of manufacturing a smoke alarm, but the present invention is not limited to this, and the smoke alarm may be set at the time of turning on power or at a predetermined timing even in the installed state.

5 is a flowchart showing an abnormality detecting operation.

Hereinafter, a description will be given based on each step in Fig.

(S1)

The control unit 10 starts an anomaly detection operation when the power is turned on.

(S2)

Next, the control unit 10, based on the ID identification signal input according to the type of the constituent unit selectively connected to the integrated circuit 1, by the above-described operation, the smoke detection unit 2 or the heat detection unit 3), and the buzzer circuit 4 or the speaker circuit 5 as the acoustic portion.

(S3)

The control unit 10 reads the ID information from the EEPROM 6 connected via the EEPROM connection terminal 106. [

The EEPROM 6 stores in advance the ID information selected by the smoke detecting section 2 or the heat detecting section 3 as the fire detecting section and the buzzer circuit 4 or the speaker circuit 5 as the acoustic section.

(S4)

The control unit 10 compares the fire detection unit and the sound unit selected by the inputted ID identification signal with the fire detection unit and the sound unit selected by the ID information, and determines whether or not they are all the same.

(S5)

If it is determined in step S4 that they do not coincide with each other, the control unit 10 outputs an abnormal signal to the abnormal signal output terminal 105 as an abnormal output operation.

The abnormality signal output terminal 105 is connected to, for example, a test apparatus for diagnosing and setting a fire alarm.

The output of the abnormal signal is not limited to the abnormal signal output terminal 105, and may be communicated to, for example, a test apparatus by providing a communication means.

In addition, the abnormal output operation is not limited to this, and instead of outputting an abnormal signal to the abnormal signal output terminal 105, or in addition to outputting a predetermined sound or voice by a predetermined display or sound unit by the display unit 7 .

For example, each LED of the display unit 7 is set in a blinking state different from a normal state. Further, for example, a sound such as " I am strange " is outputted from the speaker circuit 5.

(S6)

The control unit 10 ends the abnormality detection operation.

In addition, it is also possible to stop the operation of the control unit 10 so that the abnormality detection operation is ended and the smoke alarm does not malfunction.

(S7)

On the other hand, in step S4, when it is determined that the values match, the control section 10 shifts to the normal mode and performs normal operation processing.

(S8)

The control unit 10 ends the abnormality detection operation.

By this operation, it is possible to detect the inconsistency between the connection state of the component connected to the integrated circuit 1 and the operation state selected by the control unit 10. [

The control unit 10 selects the smoke detection unit 2 or the heat detection unit 3 as the fire detection unit based on the input ID identification signal and controls the buzzer circuit 4 as the acoustic unit, Or the speaker circuit 5, performs a fire detection operation in accordance with the selected fire detection unit, and an alarm operation in accordance with the selected sound unit.

Therefore, the integrated circuit 1 can be used for a plurality of types according to the types of the fire detection unit and the acoustic unit.

The control unit 10 selects a DC voltage source or an AC voltage source as the power supply unit 8 based on the ID identification signal input from the power supply ID terminal 111 and performs a predetermined operation according to the selected power supply unit 8. [

Therefore, the integrated circuit 1 can be used for a plurality of types of the power source unit 8.

In addition, a part of the constituent parts constituting the smoke alarm is formed in the integrated circuit 1. As a result, it is possible to reduce the size of the fire alarm and the number of manufacturing steps.

The infrared LED driving circuit 21 and the PD conversion circuit 23 are not formed in the integrated circuit 1. As a result, the generation of smoke can be detected with high accuracy without reducing the accuracy accompanying integration.

In addition, the buzzer drive circuit 41 is not formed in the integrated circuit 1. Thereby, the buzzer 42 can be driven by using a coil having a large capacity.

When the input voltage of the buzzer circuit connection terminal 107 is pulled up or pulled down, the control unit 10 uses the input voltage from the buzzer circuit connection terminal 107 as the ID identification signal of the acoustic unit, 4) is selected.

Therefore, the number of terminals provided in the integrated circuit 1 can be reduced.

The control unit 10 sets the input voltage from the heat detection unit connection terminal 104 as an ID identification signal of the fire detection unit and when the input voltage of the heat detection unit connection terminal 104 is pulled up or pulled down, (2).

Therefore, the number of terminals provided in the integrated circuit 1 can be reduced.

The control unit 10 uses the temperature detection signal based on the input voltage from the heat detection unit connection terminal 104 as the ID identification signal of the fire detection unit and when the detection temperature obtained by the temperature detection signal is within the predetermined temperature range, And the heat detector 3 is selected as the fire detector.

Therefore, the number of terminals provided in the integrated circuit 1 can be reduced.

The control unit 10 reads out the ID information stored in the EEPROM 6 and the smoke detection unit 2 or the heat detection unit 3 and the buzzer circuit 4 or the speaker circuit 5 selected based on the input ID identification signal, A predetermined abnormal output operation is performed.

Therefore, erroneous connection to the integrated circuit 1 or erroneous setting of the ID information can be detected.

In this embodiment, the control unit 10 selects the fire detection unit and the acoustic unit according to the connection state of the component unit connected to the integrated circuit 1. The control unit 10 determines the type of the power supply unit 8 based on the ID identification signal from the power supply ID terminal 111. [

The control unit 10 uses the ID information input from the EEPROM 6 as an ID identification signal and identifies only the type of the fire detection unit, the acoustic unit, and the power supply unit 8 May be selected.

With this operation, the integrated circuit 1 can be used for a plurality of models corresponding to the kinds of the fire detection unit, the acoustic unit, and the power supply unit 8. In addition, it is possible to reduce the size of the fire alarm and the number of manufacturing steps.

In this embodiment, the control unit 10 selects the type of the fire detection unit and the acoustic unit according to the connection state of the component unit connected to the integrated circuit 1.

The integrated circuit 1 may be provided with an ID exclusive terminal for selecting a fire detection section and an ID exclusive terminal for selecting an acoustic section and the fire detection section may be provided between the smoke detection section 2 and the heat detection section 3 An ID identification signal for identifying which one of the buzzer circuit 4 and the speaker circuit 5 is to be input, and an ID identification signal for identifying which of the buzzer circuit 4 or the speaker circuit 5 is to be input.

With this configuration, the controller 10 can also select the type of the fire detection unit and the acoustic unit based on the ID identification signal input from these ID-dedicated terminals.

Therefore, the integrated circuit 1 can be used for a plurality of models depending on the type of the fire detection unit and the acoustic unit. In addition, it is possible to reduce the size of the fire alarm and the number of manufacturing steps.

In the present embodiment, the integrated circuit 1 is provided with the sound DAC & LPF 51 and the sound amplifier 52 constituting the light receiving amplifier 24 and the speaker circuit 5 constituting the smoke detection section 2, Is formed.

The present invention is not limited to this, and these devices may be provided outside the integrated circuit 1.

With this configuration, the control section 10 can select the fire detection section and the sound section depending on the connection state of each constituent section. Therefore, the number of terminals provided in the integrated circuit 1 can be reduced.

In the present embodiment, the ID identification signal may also be used when setting various kinds of setting information of the smoke alarm in the factory. For example, in the case of writing the operation parameter information corresponding to the EEPROM, if the ID identification signal is read and the ID identification signal and the operation parameter information are combined, for example, It is possible to avoid that the information of the heat detecting unit is erroneously written while the detecting unit is connected.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a smoke alarm according to a first embodiment. FIG.

2 is a diagram showing a circuit configuration when a heat detecting section 3 is connected as a fire detecting section and a buzzer circuit 4 is connected as an acoustic section.

3 is a diagram showing a circuit configuration when the smoke detection section 2 is connected as a fire detection section and the speaker circuit 5 is connected as an acoustic section.

4 is a diagram showing a circuit configuration when the smoke detecting section 2 is connected as a fire detecting section and the speaker circuit 5 is connected as an acoustic section.

5 is a flowchart showing an abnormality detecting operation.

<Description of Symbols>

  1: Integrated circuit 2: Smoke detector

  3: Thermal detection unit 4: Buzzer circuit

  5: Speaker circuit 6: EEPROM

  7: Display part 8: Power part

 10: control unit 11: oscillator

 12: Reset section 21: Infrared LED driving circuit

 22: Infrared LED 23: PD conversion circuit

 24: receiving amplifier 31: resistance

 32: thermistor 41: buzzer driving circuit

 42: buzzer 51: DAC & LPF for voice

 52: voice amplifier 53: speaker

 70: Check drive circuit 71: Green LED

 72: Red LED 80: Constant voltage circuit

 81: Battery 101: Light emitting circuit connection terminal

102: light receiving circuit connection terminal 103: thermal detection connection terminal

104: Thermal detection part connection terminal 105: Abnormal signal output terminal

106: EEPROM connection terminal 107: Buzzer circuit connection terminal

108: Speaker connection terminal 109: Speaker connection terminal

110: Power supply connection terminal 111: Power supply ID terminal

112: Confirmation light connection terminal 113: Confirm light connection terminal

Claims (6)

delete delete A fire detection unit for detecting a physical quantity based on a fire phenomenon, and an acoustic unit for outputting an alarm sound, The integrated circuit comprising: A light emitting circuit connection terminal to which a light emitting circuit constituting a smoke detection section as the fire detection section can be connected, A light receiving circuit connection terminal to which a light receiving circuit constituting a smoke detecting section as the fire detecting section can be connected, A heat detecting section connection terminal to which a heat detecting section as the fire detecting section can be connected, A buzzer circuit connection terminal to which a buzzer circuit as the acoustic unit can be connected, A speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic unit can be connected, A light receiving amplifier circuit connected to the light receiving circuit connection terminal to constitute a smoke detecting section as the fire detecting section, An audio amplifier circuit connected to the speaker connection terminal and constituting a speaker circuit as the acoustic unit, A digital-to-analog converter circuit connected to the audio amplifier circuit and constituting a speaker circuit as the acoustic unit, The light detecting circuit connecting terminal, the buzzer circuit connecting terminal, and the digital analog converting circuit, and based on the input ID identifying signal, the light detecting circuit connecting terminal, the light receiving and amplifying circuit, the heat detecting portion connecting terminal, And a control unit for selecting the smoke detection unit or the heat detection unit and selecting the buzzer circuit or the speaker circuit as the sound unit and performing a fire detection operation according to the selected fire detection unit and an alarm operation according to the selected sound unit , Wherein, An input voltage from the buzzer circuit connection terminal is set as an ID identification signal of the acoustic unit, And the buzzer circuit is selected as the acoustic unit when the input voltage of the buzzer circuit connection terminal is pulled up or pulled down. A fire detection unit for detecting a physical quantity based on a fire phenomenon, and an acoustic unit for outputting an alarm sound, The integrated circuit comprising: A light emitting circuit connection terminal to which a light emitting circuit constituting a smoke detection section as the fire detection section can be connected, A light receiving circuit connection terminal to which a light receiving circuit constituting a smoke detecting section as the fire detecting section can be connected, A heat detecting section connection terminal to which a heat detecting section as the fire detecting section can be connected, A buzzer circuit connection terminal to which a buzzer circuit as the acoustic unit can be connected, A speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic unit can be connected, A light receiving amplifier circuit connected to the light receiving circuit connection terminal to constitute a smoke detecting section as the fire detecting section, An audio amplifier circuit connected to the speaker connection terminal and constituting a speaker circuit as the acoustic unit, A digital-to-analog converter circuit connected to the audio amplifier circuit and constituting a speaker circuit as the acoustic unit, The light detecting circuit connecting terminal, the buzzer circuit connecting terminal, and the digital analog converting circuit, and based on the input ID identifying signal, the light detecting circuit connecting terminal, the light receiving and amplifying circuit, the heat detecting portion connecting terminal, And a control unit for selecting the smoke detection unit or the heat detection unit and selecting the buzzer circuit or the speaker circuit as the sound unit and performing a fire detection operation according to the selected fire detection unit and an alarm operation according to the selected sound unit , Wherein, The input voltage from the heat detecting unit connection terminal is set as the ID identification signal of the fire detection unit, And selects the smoke detection section as the fire detection section when the input voltage of the heat detection section connection terminal is pulled up or pulled down. A fire detection unit for detecting a physical quantity based on a fire phenomenon, and an acoustic unit for outputting an alarm sound, The integrated circuit comprising: A light emitting circuit connection terminal to which a light emitting circuit constituting a smoke detection section as the fire detection section can be connected, A light receiving circuit connection terminal to which a light receiving circuit constituting a smoke detecting section as the fire detecting section can be connected, A heat detecting section connection terminal to which a heat detecting section as the fire detecting section can be connected, A buzzer circuit connection terminal to which a buzzer circuit as the acoustic unit can be connected, A speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic unit can be connected, A light receiving amplifier circuit connected to the light receiving circuit connection terminal to constitute a smoke detecting section as the fire detecting section, An audio amplifier circuit connected to the speaker connection terminal and constituting a speaker circuit as the acoustic unit, A digital-to-analog converter circuit connected to the audio amplifier circuit and constituting a speaker circuit as the acoustic unit, The light detecting circuit connecting terminal, the buzzer circuit connecting terminal, and the digital analog converting circuit, and based on the input ID identifying signal, the light detecting circuit connecting terminal, the light receiving and amplifying circuit, the heat detecting portion connecting terminal, And a control unit for selecting the smoke detection unit or the heat detection unit and selecting the buzzer circuit or the speaker circuit as the sound unit and performing a fire detection operation according to the selected fire detection unit and an alarm operation according to the selected sound unit , Wherein, A temperature detection signal based on an input voltage from the heat detecting section connection terminal is set as an ID identification signal of the fire detection section, And the heat detection unit is selected as the fire detection unit when the detection temperature obtained by the temperature detection signal is within a predetermined temperature range. A fire detection unit for detecting a physical quantity based on a fire phenomenon, and an acoustic unit for outputting an alarm sound, The integrated circuit comprising: A light emitting circuit connection terminal to which a light emitting circuit constituting a smoke detection section as the fire detection section can be connected, A light receiving circuit connection terminal to which a light receiving circuit constituting a smoke detecting section as the fire detecting section can be connected, A heat detecting section connection terminal to which a heat detecting section as the fire detecting section can be connected, A buzzer circuit connection terminal to which a buzzer circuit as the acoustic unit can be connected, A speaker connection terminal to which a speaker constituting a speaker circuit as the acoustic unit can be connected, A light receiving amplifier circuit connected to the light receiving circuit connection terminal to constitute a smoke detecting section as the fire detecting section, An audio amplifier circuit connected to the speaker connection terminal and constituting a speaker circuit as the acoustic unit, A digital-to-analog converter circuit connected to the audio amplifier circuit and constituting a speaker circuit as the acoustic unit, The light detecting circuit connecting terminal, the buzzer circuit connecting terminal, and the digital analog converting circuit, and based on the input ID identifying signal, the light detecting circuit connecting terminal, the light receiving and amplifying circuit, the heat detecting portion connecting terminal, And a control unit for selecting the smoke detection unit or the heat detection unit and selecting the buzzer circuit or the speaker circuit as the sound unit and performing a fire detection operation according to the selected fire detection unit and an alarm operation according to the selected sound unit , The integrated circuit comprising: And a storage section connection terminal to which the smoke detection section or the heat detection section and the ID information selected by the buzzer circuit or the speaker circuit are inputted, Wherein, And performs a predetermined abnormal output operation when the ID information does not match the smoke detection unit or the heat detection unit and the buzzer circuit or the speaker circuit selected based on the ID identification signal.

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