JP2000030165A - Alarm unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an alarm unit by which a gas alarm unit is integrally formed with a fire alarm unit, the signals of a gas sensor and a fire sensor are integrated and processed and an erroneous report is reduced. SOLUTION: This alarm unit is provided with four sensors, that is, a thermosensitive sensor 11, a smoke sensor 13, a CO sensor 15 and a hydrocarbon sensor 17. The signals of the respective sensors are transmitted to a judging part 21 which is constituted of a microcomputer or the like. The judging part 21 processes the signals of the respective sensors, judges a fire, a gas leakage and incomplete combustion or the like and displays the result in a voice alarm part 23 or a liquid crystal display part 25.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an alarm device in which a gas alarm device and a fire alarm device are integrated, and signals of a gas sensor and a fire sensor are integrated to perform signal processing, thereby reducing false alarms. Also, the present invention relates to an alarm which has a good appearance and requires less installation work and maintenance.

[0002]

2. Description of the Related Art Conventionally, a gas alarm and a fire alarm were separately installed, so that their functions were only used independently.

[0003]

For this reason, there has been a drawback that a fire alarm gives a false alarm at the time of fish cooking, which is not a fire. Regarding gas alarms, when a fire actually occurred, the gas alarms were often activated, which was a false alarm. Furthermore, because of the two housings, not only the appearance was poor, but also the installation work and maintenance had to be performed separately. In addition, an application for preventing a false alarm by mounting a gas sensor on a conventional fire alarm (registered patent 104644)
7), but it did not have a function as a gas alarm and was merely used as a high-performance fire alarm.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and has an integrated alarm device and a fire alarm device. The purpose is to provide a vessel. It is another object of the present invention to provide an alarm which has a good appearance and requires less installation work and maintenance.

[0005]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, an alarm according to a basic aspect of the present invention includes a sensor for detecting leakage of combustion gas, a sensor for detecting incomplete combustion of combustion gas, A sensor for detecting the occurrence of a fire,
A signal is input from the sensor, and a determination unit that determines gas leakage, incomplete combustion, and fire, and an alarm unit that issues an alarm in accordance with the determination are provided. Characterized by being arranged in Since the above three alarms are integrated, the appearance is good and installation and maintenance work is only required once. In addition, if the signals from the sensors are processed in an integrated manner, the output of the gas sensor can be stopped in the event of a fire, and false alarms from the gas alarm can be prevented.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First, the configuration of the most basic alarm device according to one embodiment of the present invention will be described with reference to FIG.
FIG. 1 is a block diagram showing the configuration of the most basic alarm device according to one embodiment of the present invention. The alarm 1 has four sensors as a sensor, a heat sensor 11, a smoke sensor 3, a CO sensor 15, and a hydrocarbon sensor 17. The signal of each sensor is sent to a determination unit 21 composed of a microcomputer or the like. The determination unit 21 processes signals from the sensors to determine fire, gas leakage, incomplete combustion, and the like. The result is sent to the voice alarm unit 23 and the liquid crystal display unit 2.
5 is displayed.

Examples of the thermal sensor include a temperature sensor such as a thermistor and a thermocouple, an infrared sensor, an ultraviolet sensor, and a pyroelectric sensor. Examples of the smoke sensor include an ionization type and a photoelectric type.

The type and role of each sensor are as follows. CO sensor: Incomplete combustion of combustion gas and C in the early stage of fire
O gas generation is detected. Hydrocarbon gas sensor: Since recent city gas is natural gas mainly composed of CH ₄ , such gas leak is detected. Since hydrocarbon gas is emitted in the early stage of the fire, it is also detected.

The following gas sensor can be provided as another gas sensor. O ₂ sensor: Detects incomplete combustion, lack of oxygen, and full-scale fire. CO ₂ sensor: Detects incomplete combustion, lack of oxygen, and full-scale fire.

Hereinafter, various examples of patterns for determining gas leakage, incomplete combustion, and fire will be described. 2 to 6 are flowcharts showing examples of each determination pattern.

FIG. 2 is a flowchart showing a judgment pattern of an alarm provided with a hydrocarbon gas sensor and a CO sensor. First, in S1, the concentration of the hydrocarbon gas detected by the hydrocarbon gas sensor is determined. If the hydrocarbon gas concentration exceeds the first threshold, the process proceeds to S2, and it is determined that the gas is leaked. Next, in S3, the CO gas concentration detected by the CO sensor is determined. If the CO gas concentration exceeds the first threshold value, the process proceeds to S4, and it is determined that the combustion is incomplete. At this time, even when the hydrocarbon concentration does not exceed the first threshold, if the CO concentration exceeds the first threshold, it is determined that the combustion is incomplete. Further, if the hydrocarbon concentration of the hydrocarbon gas sensor exceeds the second threshold value in S5, the process proceeds to S6, and the CO concentration of the CO sensor is determined. If the CO concentration exceeds the second threshold value, the process proceeds to S7 and it is determined that a fire has occurred.
Since the hydrocarbon concentration and the CO concentration are determined in two stages, a gas alarm function for detecting gas leakage or incomplete combustion in the first stage and a fire alarm function in the second stage can be provided simultaneously.

FIG. 3 is a flow chart showing a judgment pattern of an alarm provided with a hydrocarbon gas sensor, a CO sensor, and a thermal sensor. First, in step S21, the concentration of the hydrocarbon gas detected by the hydrocarbon gas sensor is determined.
Proceed to 2 and determine that gas is leaking. Next, in S23,
The CO concentration detected by the CO sensor is determined. When the CO concentration exceeds the threshold value, the process proceeds to S24, and it is determined that the combustion is incomplete. At this time, even if the hydrocarbon gas concentration does not exceed the first threshold, if the CO concentration exceeds the threshold, it is determined that the combustion is incomplete. Next, the process proceeds to S25, where the amount of heat detection detected by the heat sensor is determined. If the amount of heat detection exceeds the threshold value, the process proceeds to S26 to determine a fire. At this time, even if the CO concentration does not exceed the threshold value, it is determined that a fire has occurred if the heat sensing amount exceeds the threshold value. Further, the CO concentration determined in S23 may be a CO concentration increasing speed.

FIG. 4 is a flow chart showing a judgment pattern of an alarm provided with a hydrocarbon gas sensor, a CO sensor, and a combustion gas flow meter. First, when the combustion gas flow rate detected by the combustion gas flow meter exceeds the threshold value in S31, the process proceeds to S32 and a fire is determined. If the combustion gas flow rate does not exceed the threshold value, the process proceeds to S33, where the hydrocarbon gas concentration detected by the hydrocarbon gas sensor is determined. If the hydrocarbon gas concentration exceeds the threshold, S3
Proceed to 4 to determine the CO concentration detected by the CO sensor. If the CO concentration exceeds the threshold value, the process proceeds to S32, where it is determined that a fire has occurred. Therefore, even if the flow rate of the combustion gas does not exceed the threshold value, a fire is determined when the hydrocarbon gas concentration and the CO concentration exceed the threshold value.

FIG. 5 relates to an alarm provided with a CO sensor and a thermal sensor, and further with a device for inputting air volume in the kitchen. First, in S41, the air volume of the kitchen in which the alarm is installed is input. The input value is a coefficient of a determination formula for determining threshold values of the CO concentration, the CO concentration increasing speed, and the temperature increasing speed. In S42, the CO concentration detected by the CO sensor is determined. If the CO concentration exceeds the threshold, S
Proceed to 43 to determine an initial fire. Next, proceed to S44,
The rate of increase in the CO concentration of the CO sensor is determined. When the CO concentration increasing speed exceeds a certain value (= a), the process proceeds to S45. S
At 45, the temperature detected by the thermal sensor is determined, and if the rising speed exceeds a certain value (= b), the process proceeds to S46, and it is determined that a fire has occurred. Even if the CO concentration does not exceed the threshold value in S42, if the CO concentration increasing speed exceeds a certain value in S44 and if the temperature increasing speed exceeds a certain value in S45, the process proceeds to S46, and a fire is determined. Therefore, even when the rate of temperature rise is high, CO 2
If the rate of increase in the concentration or the CO concentration is equal to or less than the threshold value, no fire is determined.

FIG. 6 is a flow chart showing a judgment pattern of an alarm provided with a hydrocarbon gas sensor, a CO sensor, and a smoke sensor. First, in S51, the hydrocarbon concentration detected by the hydrocarbon gas sensor is determined. When the hydrocarbon concentration exceeds the threshold, the process proceeds to S52,
It is determined that gas is leaking. Next, the process proceeds to S53, where the CO concentration detected by the CO sensor is determined. When the CO concentration exceeds the threshold value, the process proceeds to S54, where it is determined that the combustion is incomplete. Even if the hydrocarbon concentration is lower than the threshold value in S51, if the CO concentration exceeds the threshold value in S53, S
At 54, it is determined that the combustion is incomplete. Next, the process proceeds to S55, where the amount of smoke detected by the smoke sensor is determined. If the amount of smoke exceeds the threshold value, the process proceeds to S56, and a fire is determined. Therefore, even if the amount of smoke exceeds the threshold,
If gas leak and incomplete combustion have not been determined,
No fire judgment is made. Therefore, malfunction of the fire alarm when a large amount of smoke is generated due to fish dishes or the like can be prevented.

FIG. 7 is a flowchart showing a judgment pattern of an alarm provided with a hydrocarbon gas sensor, a CO sensor, a thermal sensor, and a smoke sensor. First, in S61, the hydrocarbon concentration detected by the hydrocarbon gas sensor is determined. If the hydrocarbon concentration exceeds the threshold value, the process proceeds to S62, where it is determined that gas is leaking. Next, the process proceeds to S63, where the CO concentration detected by the CO sensor is determined. C
If the O concentration exceeds the threshold value, the process proceeds to S64, where it is determined that the combustion is incomplete. Even if the hydrocarbon concentration is equal to or less than the threshold value in S61, if the CO concentration exceeds the threshold value in S63, it is determined in S64 that the combustion is incomplete.
Next, the process proceeds to S65, where the amount of smoke detected by the smoke sensor is determined. When the amount of smoke exceeds the threshold value, the process proceeds to S66, where an initial fire is determined. Next, the process proceeds to S67, where the amount of heat detected by the thermal sensor is determined. If the calorific value exceeds the threshold value, the process proceeds to S68, where it is determined that a fire has occurred.

In the above-described determination pattern, when a gas leak, incomplete combustion, an initial fire, or a fire is determined by the determination unit 21, any one of the voice alarm unit 21 and the liquid crystal display unit 25 of the alarm device 1 or Appears in both.

[0018]

According to the present invention, a gas alarm and a fire alarm can be integrated, and the signals of the gas sensor and the fire sensor can be integrated and processed to provide an alarm with less false alarm. Further, it is possible to provide an alarm which has a good appearance and requires less installation work and maintenance.

[Brief description of the drawings]

FIG. 1 is a block diagram showing the configuration of the most basic alarm device according to one embodiment of the present invention.

FIG. 2 is a flowchart showing a determination pattern of an alarm provided with a hydrocarbon gas sensor and a CO sensor.

FIG. 3 is a flowchart showing a determination pattern of an alarm provided with a hydrocarbon gas sensor, a CO sensor, and a thermal sensor.

FIG. 4 is a flowchart showing a determination pattern of an alarm provided with a hydrocarbon gas sensor, a CO sensor, and a combustion gas flow meter.

FIG. 5 relates to an alarm provided with a CO sensor and a thermal sensor, and further with a device for inputting air volume in the kitchen.

FIG. 6 is a flowchart showing a determination pattern of an alarm provided with a hydrocarbon gas sensor, a CO sensor, and a smoke sensor.

FIG. 7 is a flowchart showing a determination pattern of an alarm provided with a hydrocarbon gas sensor, a CO sensor, a thermal sensor, and a smoke sensor.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Alarm 11 Thermal sensor 13 Smoke detection sensor 15 CO sensor 17 Hydrocarbon gas sensor 21 Judgment part 23 Voice alarm part 25 Liquid crystal display part

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G08B 17/10 G08B 17/10 K 5G405 25/00 510 25/00 510C 29/02 29/02 (72) Inventor Hiroshi Nakae 7-12-30-309 Tsudanuma, Narashino-shi, Chiba (72) Inventor Taeko 3-28-70 Minamisenju, Arakawa-ku, Tokyo (72) Inventor Tatsuo Fujimoto 3- 2-10 (72) Inventor Yukio Koshiba 1-3-1-218 Haraki, Ichikawa-shi, Chiba F-term (reference) 2G046 AA02 AA03 AA11 AA18 DC12 DC14 EB01 2G060 AA02 AA03 AB08 AB15 AB16 AB19 AE11 AE19 AE33 HC07 HC18 HD07 KA01 5C085 AA01 AA03 AA06 AA13 AA14 AB01 AC16 AC18 BA12 BA14 BA22 BA31 BA37 CA03 CA04 CA08 CA15 CA16 CA19 CA23 DA10 DA16 DA17 EA27 EA31 EA55 EA56 FA11 FA32 5C086 AA01 AA02 BA01 CA02 CA04 CA12 CA13 CB02 CB11 CB 16 CB17 CB18 DA01 DA10 DA16 DA27 DA29 EA11 EA40 EA41 EA45 FA06 FA18 GA10 5C087 AA02 AA25 AA37 AA44 BB11 CC41 DD04 DD07 DD24 EE08 EE12 EE16 FF04 GG07 GG08 GG19 GG21 GG30 AC03 GG31 AC01 GG37 AD09 CA03 CA05 CA06 CA09 CA22 CA25 CA55 DA10 DA21 DA22 EA27 EA31 EA55 EA56 FA06 FA22

Claims (37)

[Claims] 1. A sensor for detecting a leakage of a combustion gas, a sensor for detecting an incomplete combustion of a combustion gas, a sensor for detecting a fire occurrence, and a signal from the sensor for inputting a gas leak. An alarm device comprising: a judgment unit for judging incomplete combustion and fire; and an alarm unit for issuing an alarm in accordance with the judgment, wherein each of the sensors and each unit is arranged in an integral casing. 2. A sensor for detecting a hydrocarbon gas concentration, a sensor for detecting a CO gas concentration, and a determination unit which receives a signal from the sensor and determines gas leakage, incomplete combustion, and fire. An alarm unit that issues an alarm in accordance with the determination, wherein the sensors and the units are arranged in an integral casing. 3. A gas leak is determined by the hydrocarbon gas concentration exceeding the first threshold, and an incomplete combustion is determined by the CO gas concentration exceeding the first threshold. 3. The alarm according to claim 2, wherein it is determined that a fire has occurred when the CO gas concentration exceeds the second threshold after the hydrocarbon gas concentration exceeds the second threshold. 4. The alarm according to claim 2, wherein a fire occurrence is determined in consideration of the CO gas concentration or its rising speed and the hydrocarbon gas concentration. 5. A sensor for detecting a hydrocarbon gas concentration, a sensor for detecting a CO gas concentration, a heat-sensitive sensor, and a signal input from the sensor to determine gas leakage, incomplete combustion, and fire. An alarm device comprising: a unit; and an alarm unit that issues an alarm in accordance with the determination, wherein the sensors and the units are arranged in an integral casing. 6. A heat sensor detects heat when a hydrocarbon gas concentration exceeds a threshold value, determines that gas is leaking, and when a CO gas concentration exceeds a threshold value determines incomplete combustion. 6. The alarm according to claim 5, wherein it is determined that a fire has occurred when the amount exceeds the threshold value. 7. A heat-sensing sensor, wherein a gas leak is determined when the hydrocarbon gas concentration exceeds a threshold value, and an incomplete combustion is determined when the CO gas concentration exceeds a first threshold value. 6. The alarm according to claim 5, wherein it is determined that a fire has occurred when the amount of heat exceeds a threshold value and the CO gas concentration exceeds a second threshold value. 8. A gas leak is determined when the hydrocarbon gas concentration exceeds the first threshold, and an incomplete combustion is determined when the CO gas concentration exceeds the first threshold. The hydrocarbon gas concentration exceeds a second threshold and CO
6. The alarm according to claim 5, wherein an initial warning of a fire occurrence is issued when the gas concentration exceeds the second threshold value. 9. The alarm device according to claim 8, wherein a full-scale alarm of fire occurrence is issued when the heat sensor detects heat equal to or higher than the threshold value. 10. The alarm according to claim 5, wherein the occurrence of a fire is determined in consideration of the CO gas concentration or its rising speed and the amount of heat detection. 11. The alarm according to claim 5, wherein said thermal sensor is of a constant temperature type. 12. The alarm according to claim 5, wherein said thermal sensor is of a differential type. 13. The alarm device according to claim 1, wherein the alarm device is installed only in a kitchen. 14. The alarm according to claim 1, further comprising communication means for communicating with a combustion gas flow meter. 15. A fire is determined to have occurred when the CO gas concentration exceeds the threshold after the hydrocarbon gas concentration exceeds the threshold even though the combustion gas flow rate is below the threshold. The alarm according to claim 14, wherein: 16. The method according to claim 1, wherein each of the threshold values or the determination logic is determined stepwise, an initial warning is issued at an early stage of each determination, and a full-scale alarm is issued at a stage when the determination level is advanced. The alarm according to any one of claims 1 to 15. 17. The alarm device according to claim 1, wherein an air volume of an installation location is input to the determination unit, and the various determinations are performed in consideration of the air volume. 18. The alarm device according to claim 17, wherein the occurrence of a fire is determined in consideration of three factors, namely, a CO gas concentration increasing speed, a temperature increasing speed, and air volume at an installation location. 19. The alarm according to claim 5, wherein an initial warning of gas leakage or fire is issued when only the CO gas concentration exceeds the threshold value. 20. The alarm according to claim 19, wherein a full-scale alarm of fire occurrence is issued when the CO gas concentration further increases and the temperature increasing speed increases. 21. The method according to claim 5, wherein when the temperature rises to some extent and the rise is saturated and no increase in the CO gas concentration is observed, it is determined that no fire has occurred. Alarm. 22. A sensor for detecting the concentration of hydrocarbon gas, a sensor for detecting the concentration of CO gas, a smoke detection sensor, and a signal from the sensor is inputted to determine gas leakage, incomplete combustion and fire. An alarm device, comprising: a determination unit; and an alarm unit that issues an alarm in accordance with the determination, wherein the sensors and the units are arranged in an integral casing. 23. A gas leak is determined when the hydrocarbon gas concentration exceeds a threshold value, and incomplete combustion is determined when the CO gas concentration exceeds the threshold value. 23. The alarm according to claim 22, wherein the alarm is detected and the occurrence of a fire is determined when the CO gas concentration exceeds a threshold value. 24. It is determined that gas is leaking when the hydrocarbon gas concentration exceeds the first threshold value, and is determined to be incomplete combustion when the CO gas concentration exceeds the first threshold value. The hydrocarbon gas concentration exceeds a second threshold and CO
23. The alarm device according to claim 22, wherein an initial warning of a fire occurrence is issued when the gas concentration exceeds the second threshold value. 25. The alarm according to claim 24, wherein a full fire alarm is issued after the smoke sensor detects smoke above the threshold value. 26. The alarm according to claim 22, wherein the occurrence of a fire is determined in consideration of the CO gas concentration or its rising speed and the hydrocarbon gas concentration. 27. A gas leak is determined when the hydrocarbon gas concentration exceeds a threshold value, and incomplete combustion is determined when the CO gas concentration exceeds the threshold value. 23. The alarm according to claim 22, wherein it is determined that a fire has occurred based on the detection of a fire. 28. The alarm according to claim 27, wherein the smoke detection sensor detects smoke, and when no increase in the CO gas concentration is observed, it is determined that no fire has occurred. 29. A sensor for detecting a hydrocarbon gas concentration, a sensor for detecting a CO gas concentration, a thermal sensor, a smoke sensor, and a signal from the sensor. An alarm device comprising: a judgment unit for judging a fire; and an alarm unit for issuing an alarm in accordance with the judgment, wherein each of the sensors and each unit is disposed in an integral casing. 30. A gas leak is judged when the hydrocarbon gas concentration exceeds a threshold value, and an incomplete combustion is judged when the CO gas concentration exceeds the threshold value. 30. The alarm according to claim 29, wherein the alarm is detected by detecting heat equal to or greater than the value and determining that a fire has occurred by detecting the smoke by the smoke detection sensor. 31. The alarm according to claim 29, wherein a fire occurrence is determined in consideration of the CO gas concentration or its rising speed and the hydrocarbon gas concentration. 32. The alarm according to claim 29, wherein the smoke detection sensor detects smoke, and when no increase in the CO gas concentration is observed, it is determined that no fire has occurred. 33. The alarm according to claim 29, wherein said thermal sensor is of a constant temperature type. 34. The alarm according to claim 29, wherein said thermal sensor is of a differential type. 35. A thermal sensor, wherein a gas leak is determined when the hydrocarbon gas concentration exceeds a threshold value, and an incomplete combustion is determined when the CO gas concentration exceeds a first threshold value. Detects heat above a threshold value, and determines that a fire has occurred based on the fact that the smoke detection sensor detects smoke and the CO gas concentration exceeds a second threshold value. 30. The alarm according to claim 29. 36. A gas leak is determined when the hydrocarbon gas concentration exceeds a threshold value, and an incomplete combustion is determined when the CO gas concentration exceeds the threshold value. 30. The alarm device according to claim 29, wherein an alarm for generating an initial fire is issued when the threshold value is exceeded and the smoke detection sensor detects smoke. 37. The alarm according to claim 36, wherein a full-scale fire alarm is issued when the heat sensor detects heat equal to or higher than the threshold value.