KR890001464Y1 - An alarm - Google Patents

Abstract

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Description

Voice gas alarm

1 is a block diagram of a circuit of the present invention.

2 is a detailed circuit diagram of FIG.

3 is an output waveform diagram of the alarm generation control circuit I of FIG.

* Explanation of symbols for main parts of the drawings

A: gas detector B: interface

D: Speech synthesizer C: Microcomputer

E: Memory Sp: Speaker

F: preamplifier and low pass filter circuit G: audio amplification circuit

H: Power control circuit L: Alarm control circuit

J: Gas leak display circuit

The present invention relates to a voice gas alarm that outputs an alarm sound and an alarm message through a voice synthesis device when detecting a gas leak and maintaining a dangerous concentration for a predetermined time or more, and in particular, improves the sound quality of a voice gas alarm sound output sound and a buzzer. It is a circuit that can generate buzzer sound without using and reduce power consumption and noise by shutting off power supply when it is not necessary.

The circuit of the conventional voice gas alarm uses a sound quality improvement circuit and a PARCOR synthesis method and generates a warning message. However, a bit for quantizing the PARCOR coefficient in the sound quality improvement circuit and the PARCOR synthesis method is used. Due to the limitation of the number of commercially available buzzers, the cost and complexity of the entire circuit were complicated and the power consumption was high.

Accordingly, an object of the present invention is to provide a circuit capable of generating accurate sound of the sound of the sound of the voice alarm.

Another object of the present invention is to provide a voice gas alarm that can output the alarm sound of a simple voice gas alarm using an alarm control circuit without using a buzzer.

Still another object of the present invention is to provide a circuit for outputting an alarm message corresponding to an alarm sound by a voice synthesis method.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram of the present invention, and FIG. 2 is a detailed circuit diagram of the present invention.

In the figure, the gas detection circuit A is composed of a gas sensor and a compensation circuit to detect a gas leak.

The interface B serves to connect the data detected by the gas leak in the gas detection circuit A to the microcomputer C.

The microcomputer C receives the data detected by the gas leak input from the interface B, accesses a program inside, selects a voice message to be output through the speaker Sp, and inputs a corresponding address to the voice synthesizer D. ) Is a circuit for controlling alarm generation control circuit (I), gas leakage display circuit (J), voice synthesizer (D), and power control circuit (H).

The voice synthesizer (D) reads the voice data to be synthesized in the memory (E) under the control of the microcomputer (C) when the microcomputer (C) inputs any arbitrary data (gas leak) by a program therein. The sound is synthesized by the (PARCOR) method.

The memory E serves to store voice data to be synthesized in the voice synthesizer.

The preamplifier and low pass filter circuit F includes a noise removing capacitor (Rcc), an R7 capacitor, an amplifier (AMPI), a capacitor (C6), and a noise removing capacitor (Vcc) input to a power input terminal of the amplifier (AMPI). A non-inverting amplifier composed of C4) and a noise canceling capacitor for the power supply (Vcc) input to the resistors (R8-R10), capacitors (C5, C8, C9), amplifier (AMP2) and amplifier (AMP2) power input terminals. The low-pass filter circuit composed of (C7), the low-pass filter circuit composed of the resistors (R12-R14), the capacitors (C10-C13), the amplifier (AMP3), and the like, and the gas leak output from the voice synthesizer (D) described above. Is a circuit that adjusts the level so that any data on the audio amplifier (G) is suitable for the characteristics.

The audio amplifier circuit G amplifies the data output from the preamplifier and the low pass filter circuit F. The audio amplifier circuit G includes a resistor R11, a variable resistor VR1, an amplifier AMP4, and a capacitor C4.

The power control circuit H controls the power of the voice synthesizer D, the memory E, and the audio amplification circuit G according to the program of the microcomputer C. The output port of the microcomputer C The resistor R3 and the transistor Q1 are connected to the PC6.

The alarm generation control circuit (I) is composed of resistors (R4), (R5), transistors (Q2), and capacitors (C3, C3 ', C15) at the output port (PC7) of the microcomputer (C) to control the alarm generation. do.

The gas leakage display circuit J has a function of displaying the outside when a gas leak is detected.

The speaker Sp is a speaker that outputs voice sound when gas leakage is detected.

With such a configuration, first, when gas leakage is confirmed by the gas detection circuit A, it is input to the microcomputer C through the interface B. FIG.

Therefore, the microcomputer C selects the voice warning message for the gas leak and inputs the corresponding data to the data input terminals D0-D7 of the voice synthesizer D through the output ports PB0-PB7.

The voice synthesizer (D) reads the output data of the microcomputer (C) from the memory (E) and then reads the voice data read from the memory (E) in the PALCOR method under the control of the voice synthesizer (D) itself. The synthesized voice is input to the audio amplifier circuit G through the preamplifier and the low pass filter circuit F.

At this time, when the gas detection and the dangerous state are reached, the contents synthesized by the voice synthesizer (D) and notified to the user are “dangerous”, “gas is leaking”, “briquette gas is leaking” and “open the window”. The microcomputer C inputs data on gas leakage from the gas detection circuit A, selects one of the above contents, and applies the corresponding address to the speech synthesizer D. FIG.

The output of the speech synthesizer D is input to the audio amplifier circuit G through the preamplifier and the low pass filter circuit F.

On the other hand, when data on gas leakage is input to the input terminal of the microcomputer C, the microcomputer C applies the output port PC6 for power control to the "low" state and applies it to the base of the transistor Q1. .

Therefore, the transistor Q1 is turned "on" by applying the "low" pulse output from the output port PC6 of the microcomputer C to the base terminal of the transistor Q1 which is a part of the power control H.

Therefore, the power supply Vcc is applied to the memory E, the audio amplifier G, and the voice synthesizer D, respectively. After the output of the microcomputer C and the output port PC6 is " low ", the output port PC7 has the same frequency (4KHz) and periodic pulse ( The waveform of T) is repeatedly output eight times and applied to the base terminal of the transistor Q2 of the alarm generation control circuit I.

The transistor Q2 is turned on and off by the output pulse of the port PC7. That is, when the transistor Q2 which outputs the high pulse is turned on and the low pulse is output, the transistor Q2 is turned off.

The vibration of the buzzer is controlled by connecting the gain control terminal of the amplifier AMP4 to the base of the transistor Q2 via the capacitor C15, and connecting the capacitor C3 'to the input terminal of the amplifier AMP4 without using a buzzer. After the buzzer is output through the speaker Sp, the output of the voice synthesizer is output through the audio amplifier circuit G and the speaker Sp to inform the user of the gas leakage state.

In this way, the audio data signal output from the voice synthesizer D is input to the audio amplifier G through the preamplifier and the low pass filter circuit F, and the audio amplification circuit G alarms according to the alarm generation control circuit I. (Voice) sound is generated in the speaker Sp.

As described above, according to the present invention, the sound output of the voice gas alarm is accurate, and there is an advantageous advantage that a simple circuit with low power consumption can be configured.

Claims (2)

A gas detection circuit A for detecting gas leakage, an interface B for interfacing data output from the gas detection circuit A to the microcomputer C, and a microcomputer C for accessing a program in accordance with the gas leakage. ), A voice synthesizer (D) for reading voice data from the memory (E) and synthesizing the voices according to the data output from the microcomputer (C), and a memory (E) for storing voice data to be synthesized in the voice synthesizer (E). ), The gas leakage display circuit J which is displayed externally when a gas leak is detected, and the level of the data signal output from the voice synthesizer D in a voice gas alarm provided with a speaker Sp or the like. A preamplifier and low pass filter circuit F, an audio amplification circuit G for amplifying the output of the speech synthesizer D passed through the preamp and low pass filter circuit F, and an output of the microcomputer C Wave to control power supply (Vcc) by PC6) And an alarm generation control circuit (I) for controlling alarm generation by the war control circuit (H) and the output (PC7) of the microcomputer (C). 2. The amplifier of claim 1, wherein the preamplifier and the low pass filter circuit F include an amplifier AMP1 and resistors R6 and R7, in which a power supply voltage Vcc is input to a power supply input terminal via a coupling capacitor C4. Amplifier (AMP2), resistors (R8-R10), and capacitors (C5, C8, C9) in which a non-inverting amplifier consisting of a capacitor (C6) and a power supply voltage (Vcc) are input via a coupling capacitor (C7) to a power input terminal. It consists of a low pass filter circuit consisting of a low pass filter circuit consisting of a low pass filter circuit consisting of amplifiers (AMP3) and resistors (R12-R14) and capacitors (C10-C13), and the audio amplifier circuit (G) includes a resistor (R11) and a variable resistor (VR1). , The amplifier (AMP4) and the condenser (C14), the gas alarm generation control circuit (I) is composed of condensers (C3, C3 ', C15), transistors (Q2), resistors (R4, R5), power control The circuit (H) is comprised from the resistor (R3) and the transistor (Q1), The voice gas alarm characterized by the above-mentioned.