JPH0828878A - Method of specifying carbon monooxide generating gas combustion device - Google Patents

Abstract

PURPOSE:To enable a gas combustion device for generating carbon monoxide to be specified and further to enable an accident to be prevented. CONSTITUTION:A gas combustion device to be operated is specified in reference to a gas consumption amount of a plurality of gas combustion devices on the basis of a variation of a flow rate signal obtained from a gas meter 3. The number of times of the same gas combustion devices contained in the gas combustion device specified every time a carbon monoxide sensor 4 outputs a carbon monoxide sensing signal is counted and if the number of times reaches 5 times, the gas combustion device is specified as one to generate carbon monoxide.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a carbon monoxide-generating gas combustion instrument specifying method for identifying a gas combustion instrument generating carbon monoxide.

[0002]

2. Description of the Related Art Conventionally, in order to measure carbon monoxide generated when gas is incompletely burned, a carbon monoxide detector is installed in a room where a gas combustion instrument is used. Measure the carbon monoxide concentration in the room. Then, when the carbon monoxide concentration exceeds a predetermined constant value, an alarm is issued or the gas flow path is shut off to stop the supply of gas to the gas combustion appliance. The carbon monoxide generated by the gas combustion equipment gradually increases due to the secular change of the gas combustion equipment and the deposition of dust on the gas combustion part. , Increases over time.

[0003]

The conventional method for measuring the concentration of carbon monoxide by the carbon monoxide detector is such that, when a plurality of gas combustion appliances are used, the generation of carbon monoxide is detected in the entire gas combustion appliance. Even if it can be detected, it is not possible to identify which gas combustion appliance is generating carbon monoxide.Therefore, the gas combustion appliance generating carbon monoxide is identified and an alarm is issued, and the occurrence of an accident is detected. It could not be prevented in advance.

The present invention has been made in order to eliminate the above-mentioned inconvenience, and it is possible to identify a gas combustion appliance generating carbon monoxide and prevent an accident from occurring. A method for identifying a carbon-evolving gas combustion appliance is provided.

[0005]

First, a first aspect of the present invention specifies a gas combustion appliance to be used from gas consumptions of a plurality of gas combustion appliances based on fluctuations in a flow signal from a gas flow signal transmitter. However, if there is one gas combustion appliance specified when the carbon monoxide detector outputs the carbon monoxide detection signal, carbon monoxide generation that specifies that the gas combustion appliance is generating carbon monoxide This is a method for identifying gas combustion appliances.

Next, a second aspect of the present invention specifies the gas combustion equipment being used from the gas consumption of a plurality of gas combustion equipment based on the fluctuation of the flow rate signal from the gas flow rate signal generator, and determines the carbon monoxide. Each time the detector outputs a carbon monoxide detection signal, the number of times of the same gas combustion instrument included in the specified gas combustion instrument is counted, and when this number reaches the predetermined number, the gas combustion instrument generates carbon monoxide. It is a method of identifying a carbon monoxide generating gas combustion appliance that is identified as being present.

A third aspect of the present invention specifies the gas combustion appliance being used from the gas consumption of a plurality of gas combustion appliances based on the fluctuation of the flow signal from the gas flow signal transmitter.
Each time the carbon monoxide detector outputs a carbon monoxide detection signal,
The number of times of the same gas combustion instrument included in the specified gas combustion instrument is counted every time the flow rate signal from the gas flow rate signal transmitter changes while the carbon monoxide detector is outputting the carbon monoxide detection signal. A method for identifying a carbon monoxide-generating gas combustion instrument, wherein the gas combustion instrument, which has reached a predetermined number of times, is identified as generating carbon monoxide.

[0008]

According to the method for identifying a carbon monoxide generating gas combustion instrument of the present invention, the gas combustion instrument being used is identified from the gas consumption of a plurality of gas combustion instruments based on the fluctuation of the flow rate signal from the gas flow rate signal transmitter. If there is one gas combustion instrument specified when the carbon monoxide detector outputs the carbon monoxide detection signal in the state of being activated, it is determined that the gas combustion instrument is generating carbon monoxide. .

However, if there is not one gas combustion instrument specified when the carbon monoxide detector outputs the carbon monoxide detection signal, it is specified each time the carbon monoxide detector outputs the carbon monoxide detection signal. The state in which the carbon monoxide detector outputs the carbon monoxide detection signal every time the number of times the same gas combustion instrument is included in the gas combustion instruments is counted or the carbon monoxide detector outputs the carbon monoxide detection signal. Each time the flow rate signal from the gas flow rate signal generator changes, the number of times the same gas combustion instrument included in the specified gas combustion instrument is counted, and when this number reaches the predetermined number, the gas combustion instrument generates carbon monoxide. Identify that you are doing.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a carbon monoxide generating gas combustion appliance identifying device to which the present invention is applied. In FIG. 1, 1 is a gas flow path, 2 is a cutoff valve disposed in the middle of the gas flow path 1, 3 is a gas meter as a gas flow rate signal transmitter, and this gas meter 3 is on the downstream side of the cutoff valve 2. Is provided in the gas flow path 1 and outputs a flow rate signal that detects the flow rate of the gas flowing through the gas flow path 1.

The gas meter 3 is provided with a film driven by the flow of gas, a magnet that rotates in conjunction with the motion of the film, and a reed switch that is repeatedly turned on and off by the rotary motion of the magnet. When the film is driven according to the flow of gas and the magnet rotates, the reed switch is turned on and off, and one pulse is output each time the film makes one reciprocation, that is, each time the magnet makes one rotation. Therefore, when the gas flow rate increases, the number of pulses per unit time increases, and when the gas flow rate decreases, the number of pulses per unit time decreases.

Reference numeral 4 denotes a carbon monoxide detector, which outputs a carbon monoxide detection signal corresponding to the carbon monoxide concentration, for example, a higher potential (voltage) as the carbon monoxide concentration becomes higher, or a signal corresponding thereto. It is a thing. Reference numeral 5 is a display unit for displaying information, 6 is a notification device such as a buzzer or a bell, and 7 is a microcomputer as an arithmetic processing means. The microcomputer 7 is based on the fluctuation of the flow rate signal from the gas meter 3 as described later. The consumption classification of the gas combustion equipment and the gas combustion equipment being used are specified, and the gas combustion equipment generating carbon monoxide is specified based on the signals from the gas meter 3 and the carbon monoxide detector 4. The information is displayed on the display unit 5 and the alarm 6 is operated. Reference numeral 8 denotes a return safety mechanism for returning the shutoff valve 2.

FIG. 2 is an explanatory diagram showing the correspondence between the consumption amount classification and the gas consumption amount. In FIG. 2, for example, the rice cooker
Since it is 0.1 kg / h, it is the second division, and the stove is 0.3 kg / h, it is the second division, and the gas dryer is 0.4 kg / h, it is the second division. The gas water heater has a capacity of 0.9 kg / h and thus is in the sixth section, and the bath burner has a capacity of 1.2 kg / h and is in the eighth section.

Therefore, it is possible to specify the consumption classification and the gas combustion appliance based on the fluctuations in the gas consumption and the total gas consumption. It should be noted that this illustration is of LP gas, and the gas will be described as LP gas in the following description.

FIG. 3 is a time chart showing an example of the total gas consumption. In FIG. 3, the vertical axis represents the total gas consumption amount Q, and the horizontal axis represents the time t.

FIG. 4 is a flow chart of an example in which the microcomputer specifies the carbon monoxide generating gas combustion appliance. In FIG. 4, ST1 to ST11 indicate steps.

FIG. 5 is an explanatory view showing an example of the gas combustion appliance specified by the microcomputer and stored in the memory. In FIG. 5, A is a rice cooker, B is a stove, C is a gas dryer, D is a gas water heater, and E is a bath burner.

Next, the specification of the gas combustion appliance used will be described. First, since the total gas consumption Q changes as shown in, for example, FIG. 3 by using a gas combustion appliance, the total gas consumption Q from time t ₁ to time t ₂ is 0.1 kg / h. Therefore, the rice cooker is used from time t ₁ to time t _2, and the total gas consumption Q from time t ₂ to time t ₃ is 0.4 kg / h, so the rice cooker from time t ₂ to time t ₃ And the stove is used, and the total gas consumption Q from time t ₃ to time t ₄ is 0.3 kg / h, the stove is used from time t ₃ to time t ₄ ,
The total gas consumption Q from time t ₄ to time t ₅ is 0 kg /
Since it is h, it can be estimated that the gas combustion appliance is not used from time t ₄ to time t ₅ .

[0019] And, since the time t total gas consumption Q up to ₆ from the time t ₅ is 0.9kg / h, gas water heater from time t ₅ to time t ₆ is used, the time from the time t ₆ t _{Since the} total gas consumption Q up to ₇ is 1.3 kg / h, the gas water heater and the gas dryer are used from time t ₆ to time t ₇ , and the total gas consumption from time t ₇ to time t ₈ Since Q is 0.4 kg / h, the gas dryer is used from time t ₇ to time t ₈ , and time t ₈ to time t ₉
Since the total gas consumption Q up to is 0 kg / h, time t
_{From 8} to time t ₉ it can be estimated that the gas combustion appliance is not in use.

Further, since the total gas consumption Q from time t ₉ to time t ₁₀ is 0.1 kg / h, the rice cooker is used from time t ₉ to time t ₁₀ , and the time t ₁₀ to time t ₁₁ is used.
Since the total gas consumption Q up to t is 0.4 kg / h, the rice cooker and the stove are used from time t ₁₀ to time t ₁₁ , and the total gas consumption Q from time t ₁₁ to time t ₁₂ is 0.
Since it is 3 kg / h, the stove is used from time t ₁₁ to time t _12, and the total gas consumption Q from time t ₁₂ to time t ₁₃ is 1.5 kg / h, so from time t ₁₂ to time t
_A stove and a bath burner are used until ₁₃ o'clock at time t
_The total gas consumption Q from ₁₃ to time t ₁₄ is 1.2 kg / h.
Therefore, the bath burner is used from time t ₁₃ to time t _14, and the total gas consumption Q from time t ₁₄ to time t ₁₅ is 0 kg / h, so from time t ₁₄ to time t _15. has not been used the gas combustion appliances, gas total consumption Q from time t ₁₅ to time t ₁₆ is because it is 0.9 kg / h, gas water heaters are used from time t ₁₅ to time t _16,
The total gas consumption Q from time t ₁₆ to time t ₁₇ is 1.3k
Since it is g / h, the gas water heater and the gas dryer are used from the time t ₁₆ to the time t ₁₇ , and the time t ₁₇ to the time t ₁₈
Since the total gas consumption Q up to 2.5 kg / h is 2.5 kg / h, the gas water heater, gas dryer and bath burner are used from time t ₁₇ to time t _18, and the gas from time t ₁₈ to time t ₁₉ is used. Since the total consumption Q is 1.6 kg / h, the time t
Gas dryer and bath burner are used from ₁₈ to time t ₁₉ , and total gas consumption Q from time t ₁₉ to time t ₂₀
Is 0.4 kg / h, the gas dryer is used from time t ₁₉ to time t _20, and the total gas consumption Q after time t ₂₀ is 0 kg / h, so gas combustion is performed after time t _20. It can be assumed that the device is not in use.

Next, a specific example of a gas combustion appliance that generates carbon monoxide will be described. Since the gas combustion appliance being used can be specified as described above, the microcomputer 7 first resets the counter (step ST1) and outputs the carbon monoxide detection signal from the carbon monoxide detector 4. Wait for it to be done (step ST
2).

When a carbon monoxide detection signal is output from the carbon monoxide detector 4, a flow rate signal of the gas meter 3,
That is, it is determined whether the total gas consumption amount Q is zero (step ST3). If the total gas consumption amount Q is zero, it means that carbon monoxide has not been generated from the gas combustion appliance, so step ST3
Return to 2. Next, in step ST3, the total gas consumption Q
If is not zero, carbon monoxide is generated from the gas combustion appliance, so identify the gas combustion appliance in use and store it in the built-in memory in sequence as shown in Fig. 5 (step ST
4) From the carbon monoxide detection signal, it is determined whether or not the carbon monoxide concentration is within the range of the first stage alarm, for example, 50 ppm or more and less than 250 ppm (step ST5).

If the determination in step ST5 is not within the range of the first-stage alarm, the range of the second-stage alarm, that is, the carbon monoxide concentration is 250 ppm or more. The gas consumption of the specified gas combustion equipment and the gas consumption (kg
/ H) is all displayed on the display unit 5 and a shutoff process for ringing the alarm 6 is performed (step ST6). Also, step ST
If it is within the range of the first-stage alarm in the judgment of 5, the number of times of the same gas combustion appliances included in the specified gas combustion appliances is counted (step ST7), and it is judged whether or not there is a fifth gas combustion appliance ( Step ST8).

If it is determined in step ST8 that there is no gas combustion appliance for the fifth time, it is determined whether the carbon monoxide concentration is within the range of the second stage alarm (step ST9), and the carbon monoxide concentration is the second. If it is in the step alarm range, the process proceeds to step ST6. If the carbon monoxide concentration is not in the second step alarm, it is determined whether or not the carbon monoxide detector 4 is outputting the carbon monoxide detection signal (step). ST10). Next, if it is determined in step ST10 that the carbon monoxide detector 4 outputs the carbon monoxide detection signal, the process returns to step ST9 and the carbon monoxide detector 4 must output the carbon monoxide detection signal. If so, return to step ST2.

Further, if there is a gas combustion appliance with the fifth number of times determined in step ST8, the consumption classification and gas consumption (kg / h) of the gas combustion appliance are displayed on the display unit 5,
The alarm 6 is operated, the data of the gas combustion appliance is reset (step ST11), and the process returns to step ST2.

As described above, according to one embodiment of the present invention, the same gas combustion unit included in the gas combustion apparatus used every time the carbon monoxide detector 4 outputs the carbon monoxide detection signal. In order to identify the gas burning appliance that is generating carbon monoxide by counting the number of appliances, that is, to identify the gas burning appliance that is generating carbon monoxide while monitoring the gas burning appliance in use, It is possible to reliably identify the gas combustion appliance that is generating carbon monoxide.

Then, the specified gas combustion appliance is displayed on the display unit 5.
Since it is displayed and the alarm 6 is operated to notify, the treatment can be performed promptly, so that the occurrence of an accident can be prevented in advance. In addition, in the data of FIG. 5, it can be specified that the gas combustion appliance generating carbon monoxide is the gas water heater D.

FIG. 6 is a flow chart of another example in which the microcomputer identifies the carbon monoxide generating gas combustion appliance. In FIG. 6, ST21 indicates a step.

Next, another specific example of the gas combustion appliance generating carbon monoxide will be described, but only the part different from the previous example will be described. If the carbon monoxide detector 4 outputs the carbon monoxide detection signal in the determination of step ST10 in the previous example, it is determined whether the total gas consumption Q has changed (step ST21), and the total gas consumption Q If changes, the process returns to step ST4.

As described above, according to another embodiment of the present invention, every time the carbon monoxide detector 4 outputs the carbon monoxide detection signal, the carbon monoxide detector 4 outputs the carbon monoxide detection signal. The number of times of the same gas combustion instrument included in the gas combustion instrument being used, which is specified each time the gas flow rate signal changes while specifying the gas combustion instrument generating carbon monoxide, It is possible to obtain the same effect as that of the previous embodiment. Further, the number of times of the same gas combustion instrument included in the gas combustion instrument being used is counted every time the gas flow rate signal changes while the carbon monoxide detector 4 is outputting the carbon monoxide detection signal. Since the gas combustion appliance generating carbon monoxide is specified, the gas combustion appliance generating carbon monoxide can be specified quickly.

In the above-mentioned embodiment, the case where there are a plurality of gas combustion appliances specified when the carbon monoxide detector 4 outputs the carbon monoxide detection signal has been described. Needless to say, may be specified as a gas combustion appliance that generates carbon monoxide. Therefore, in the third time in FIG. 5, the gas combustion appliance generating carbon monoxide can be immediately identified as the gas water heater D.

The predetermined number of times is 5, but it may be 2 or more, but is preferably 3 or more. Furthermore, although an example has been described in which the gas is LP gas, other gas,
Needless to say, it is possible to specify a gas combustion appliance that similarly generates carbon monoxide even for city gas, for example.

[0033]

As described above, according to the present invention, the gas combustion appliance to be used is identified from the gas consumption of a plurality of gas combustion appliances based on the fluctuation of the flow signal from the gas flow signal generator. The gas combustion device specified when the carbon monoxide detector outputs a carbon monoxide detection signal in
If so, it is specified that the gas combustion device is generating carbon monoxide, and therefore the gas combustion device generating carbon monoxide can be specified quickly.

However, if there is not one gas combustion instrument specified when the carbon monoxide detector outputs the carbon monoxide detection signal, the carbon monoxide detector specifies each time the carbon monoxide detector outputs the carbon monoxide detection signal. The number of times the same gas burning appliance included in the gas burning appliance is counted, and it is specified that the gas burning appliance that has reached this number of times has generated carbon monoxide, so carbon monoxide is generated. It is possible to reliably identify the gas combustion appliance.

If there is not one gas combustion instrument specified when the carbon monoxide detector outputs the carbon monoxide detection signal, one carbon monoxide detector outputs the carbon monoxide detection signal. Each time the flow rate signal from the gas flow rate signal transmitter changes while the carbon oxide detector is outputting the carbon monoxide detection signal, the number of times the same gas combustion instrument is included in the specified gas combustion instrument is counted. Since it is determined that the gas combustion device that has reached the predetermined number of times is generating carbon monoxide, it is possible to quickly specify the gas combustion device that is generating carbon monoxide. Therefore, since the specified gas combustion appliance can be treated, it is possible to prevent an accident from occurring.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a carbon monoxide generating gas combustion appliance identifying device to which the present invention is applied.

FIG. 2 is an explanatory diagram showing a correspondence between a consumption amount classification and a gas consumption amount.

FIG. 3 is a time chart showing an example of total gas consumption.

FIG. 4 is a flow chart of an example in which a microcomputer identifies a carbon monoxide generating gas combustion appliance.

FIG. 5 is an explanatory diagram showing an example of a gas combustion appliance specified by a microcomputer and stored in a memory.

FIG. 6 is a flow chart of another example of how a microcomputer identifies a carbon monoxide generating gas combustion appliance.

[Explanation of symbols]

 1 gas flow path 3 gas meter 4 carbon monoxide detector 5 display section 6 alarm 7 microcomputer

Claims (3)

[Claims] 1. A carbon monoxide detector detects a carbon monoxide by identifying the gas combustion instrument being used from the gas consumption of a plurality of gas combustion instruments based on fluctuations in the flow rate signal from the gas flow rate signal generator. A method for identifying a carbon monoxide-generating gas combustion instrument, characterized in that if the number of the identified gas combustion instrument is one when the signal is output, the gas combustion instrument is identified as generating carbon monoxide. . 2. A carbon monoxide detector detects carbon monoxide based on the fluctuation of the flow rate signal from the gas flow rate signal transmitter, and identifies the gas combustion instrument being used from the gas consumption of a plurality of gas combustion instruments. Each time a signal is output, the number of times of the same gas combustion appliance included in the specified gas combustion appliance is counted, and it is specified that the gas combustion appliance that has reached this number of times has generated carbon monoxide, A method for identifying a carbon monoxide-evolving gas combustion device, comprising: 3. The carbon monoxide detector detects the carbon monoxide by identifying the gas combustion appliance being used from the gas consumption of the plurality of gas combustion appliances based on the fluctuation of the flow signal from the gas flow signal generator. Each time you output a signal,
Each time the flow rate signal from the gas flow rate signal transmitter changes while the carbon monoxide detector is outputting the carbon monoxide detection signal, the number of times of the same gas combustion instrument included in the specified gas combustion instrument is determined. A method for identifying a carbon monoxide-generating gas combustion instrument, comprising: counting and identifying that the gas combustion instrument that has reached a predetermined number of times generates carbon monoxide.