1. Field of the Invention
The present invention relates to a gas leak detection apparatus and detection method used in a gas meter or the like which is disposed in a gas supply line to a domestic dwelling and has a gas flow meter, and more particularly it relates to technology which enables the provision of higher advanced safety functions and services by detecting the presence of a gas leak during occurrence and continuation of the flow volume by a gas supply.
2. Description of the Related Art
A gas meter incorporating a gas flow meter is installed at the inlet port of the gas supply line to a domestic dwelling. The gas meter measures the gas flow volume passing through the gas supply line, and the measured gas flow volume is used to calculate a periodic gas billing amount. In addition to basic functions, such as measuring the gas flow volume, the gas meter also has a safety function for shutting off the gas supply when an abnormal state occurs. This safety function is a function which shuts off the gas by means of a shut-off valve provided in the gas flow path of the gas meter, in response to the detection of an abnormal usage state, for instance, if an earthquake is detected, if there is a gas leak or if the appliance is left without turned off, and the like.
As shown in
The gas meter judges that a gas appliance of some kind has started to be used, when a gas flow volume has occurred and or when the gas flow volume has changed into an increase, and based on this judgement, measures the time during which this flow rate continues. If this flow volume continues for a time exceeding the safe continuous use time shown in
However, as shown in
On the other hand, in the prior art, a technique has also been proposed in which a gas leak is judged by comparison with patterns of flow volume change under reduced pressure or flow volume values measured in the past (see, for example, Japanese Patent Application Publication No. 2005-331373. However, even if a technique such as this is used, since a state of no change in the flow volume range or pattern continues both in the case of a gas leak and in the case of continuous use of a gas appliance which is not fitted with a governor (pressure regulator), such as cooking stove, then it has been difficult to distinguish between these two cases. In particular, when using an appliance which has been newly installed in a dwelling receiving a gas supply, since there is no data for comparison in relation to that appliance, then there has been a possibility of a gas leak being detected mistakenly.
The present invention was devised in order to resolve the problems of the prior art described above, an object thereof being to provide a gas leak detection apparatus and method whereby a gas leak can be detected rapidly, efficiently and accurately, and mistaken detection of a gas leak can be prevented, even when using an appliance which has been newly installed in a dwelling receiving a gas supply.
In order to achieve the aforementioned objects, the gas leak detection apparatus according to the present invention comprises: a flow volume measurement means for measuring the instantaneous flow volume of gas flowing inside a gas flow channel; a instantaneous flow volume time differential operation means for operating the time differential value of the instantaneous flow volume which has been measured by the flow volume measurement means; a characteristics extraction means for extracting the characteristics of the gas flow including the instantaneous flow volume and the time differential value of the instantaneous flow volume, on the basis of the instantaneous flow volume which has been measured by the flow volume measurement means and the time differential value of the instantaneous flow volume which has been operated by the instantaneous flow volume time differential operation means; a storage means for registering characteristics data indicating different gas flow characteristics for respective types of gas appliance or for a gas leak; a characteristics data registration means for registering in the storage means characteristics data indicating characteristics which have been extracted by the characteristics extraction means from a flow volume pattern in which the occurrence of a flow volume has been measured by the flow volume measurement means and the flow volume has subsequently become zero; and a leak detection means for performing leak detection in which the presence or absence of a gas leak is judged, and outputting a judgment result, by comparing the characteristics data which has been registered in the storage means with the characteristics of the gas flow which has been extracted by the characteristics extraction means; wherein the characteristics data registration means registers the characteristics of the gas flow forming the basis of a judgment as new characteristics data, in the storage means, when it is judged by the leak detection means that there is no gas leak.
Furthermore, in one mode of the present invention, the gas leak detection apparatus further comprises: a pressure measurement means for measuring the pressure of the gas flowing inside the gas flow channel; wherein the characteristics extraction means extracts characteristics of the gas flow including the relationship between the flow volume and the pressure, on the basis of the instantaneous flow volume which has been measured by the flow volume measurement means, the time differential value of the instantaneous flow volume which has been operated by the instantaneous flow volume time differential operation means, and the pressure which has been measured by the pressure measurement means.
Furthermore, the gas leak detection method according to the present invention states the functions of the gas leak detection apparatus described above, in terms of a method.
The present invention described above is devised by focusing on the fact that a flow volume pattern in which a flow volume occurs and then returns to zero relates not to a gas leak but rather to the use of an appliance, and when a flow volume pattern of this kind is newly extracted, then it is registered as characteristics data and is used in subsequent gas leak detection, thereby making it possible to prevent mistaken detection of a gas leak.
In the present invention, if the characteristics of a newly extracted flow volume pattern match the flow volume pattern of registered characteristics data, then this means that an appliance corresponding to that characteristics data is in use, and if they do not match, then it can be judged that there is a gas leak or that a new appliance is in use. Furthermore, if there is no matching, then it is judged whether or not there is a change in the flow volume or a change in the nozzle, on the basis of a combination of the instantaneous flow volume and the time differential value of the instantaneous flow volume, or the ratio between the flow volume and the square root of the pressure, and by this judgement, it can be determined accurately and rapidly whether there is a gas leak or whether an unregistered appliance is in use.
If there is a change in the flow volume or a change in the nozzle, then this means that there is an appliance which implements flow volume control of some kind, and therefore by registering the characteristics of this flow volume pattern as characteristics data for a new appliance, the characteristics can be used in subsequent detection and judgment of gas leaks. Furthermore, if there is no change in the flow volume or change in the nozzle, then there is a high probability of a gas leak and therefore it is possible to respond swiftly to a gas leak by issuing a warning.
According to the present invention, it is possible to provide a gas leak detection apparatus and method whereby mistaken detection of a gas leak can be prevented even when using an appliance which has been newly installed in a dwelling receiving a gas supply, and whereby a gas leak can be detected rapidly, efficiently and accurately.
The flow volume measurement means 1 is a means for measuring the instantaneous flow volume Q of the gas flowing inside a gas supply flow channel (gas pipe). It is possible to use various types of measurement means for the flow volume measurement means 1, but in the present embodiment, it is supposed that an ultrasonic flow volume meter is used.
For example, this ultrasonic flow volume meter has a gas inflow port, a gas flow channel, a gas outflow port, a shut-off valve, a display unit and a control unit. Ultrasonic vibrating elements are provided inside the gas flow channel, respectively in the upstream portion and the downstream portion of the gas flow channel. An ultrasonic wave is transmitted and received repeatedly, in the forward direction and reverse direction of the flow respectively, between the ultrasonic vibrating element in the upstream portion and the ultrasonic vibrating element in the downstream portion, and the integral propagation time of the ultrasonic wave in either direction is determined. The instantaneous flow volume is calculated on the basis of the difference in propagation time thus obtained.
The pressure measurement means 2 is a means for measuring the pressure P of the gas flowing in a gas supply flow channel (gas pipe). It is possible to use various types of pressure meter and pressure sensor for this pressure measurement means 2.
The instantaneous flow volume time differential operation means 3 is connected to the flow volume measurement means 1, and operates the time differential value of the instantaneous flow volume data measured by the flow volume measurement means 1. The pressure time differential operation means 4 is connected to the pressure measurement means 2 and operates the time differential value of the pressure data measured by the pressure measurement means 2. These time differential operation means 3 and 4 can be achieved by a combination of an electronic circuit or computer, and a program specified for time differential operation.
Furthermore, the flow volume measurement means 1, the pressure measurement means 2, the instantaneous flow volume time differential operation means 3 and the pressure time differential operation means 4 are all connected to the characteristics extraction means 5, and the data obtained from these means 1 to 4, in other words, the instantaneous flow volume data and the instantaneous flow volume time differential value data, and the pressure data and the pressure time differential value data, are all inputted to the characteristics extraction means 5.
The characteristics extraction means 5 is a means for extracting characteristics of the gas flow which is flowing in a gas flow channel which is the object of judgment, on the basis of inputted instantaneous flow volume data and instantaneous flow volume time differential value data, and pressure data and pressure time differential value data.
Here, the instantaneous flow volume data measured by the flow volume measurement means 1, the instantaneous flow volume time differential value data obtained from same, and the pressure data measured at the same point in time and the pressure time differential value data obtained from same each has different characteristics for each type of gas appliance (or in the case of a gas leak). However, since there are also cases where any one of these data elements (for example, the instantaneous flow volume data alone) is the same for a plurality of different types of gas appliance, then it is difficult to judge the appliance accurately. Therefore, in the characteristics extraction means 5 according to the present embodiment, in addition to extracting the characteristics for each data type, the characteristics of a combination of a plurality of data types are also extracted, and hence it is possible to extract accurately the characteristics which differ between respective types of gas appliance.
This characteristics extraction means 5, and as described below, the leak detection means 7, the characteristics data registration means 8 and the unused data deletion means 10 can generally be achieved by a combination of electronic circuits or computers of various types, and programs specified in order to achieve the functions of these means.
Data composed of a plurality of items corresponding to the respective characteristics extracted by the characteristics extraction means 5 is previously registered in the storage means 6 in an initial stage before the start of operation of the gas leak detection apparatus, as characteristics data which indicates the characteristics which differ between such different types of gas appliance, and furthermore, new characteristics data can be additionally registered therein. This storage means 6 can be realized by various types of memory or storage unit.
The leak detection means 7 is a means for detecting the presence or absence of a gas leak by comparing the characteristics data for respective gas appliance types or for a gas leak which is registered in the storage means 6 with the characteristics of the gas flow which has been extracted by the characteristics extraction means 5.
The characteristics data registration means 8 is a means for registering the characteristics of the gas flow forming the basis of the judgment in the storage means 6 as new characteristics data, when it is judged by the leak detection means 7 that there is no gas leak or that an appliance is in use.
The warning means 9 is a means for outputting the judgment result in a form whereby it can be presented or reported to the human operator, when it is judged by the leak detection means 7 that there is a gas leak. In practice, this warning means 9 can be realized by various types of output means, such as an LCD or other display unit provided in a gas meter, an externally provided reporting unit, or a display monitor, printer or gas leak warning unit.
The unused data deletion means 10 is a means for deleting characteristics data having a use frequency not more than a prescribed level, as unused data, from the characteristics data registered in the storage means 6. In order to judge this use frequency, in the present embodiment, an indicator value showing the use frequency is registered additionally by the characteristics data registration means 8 in the characteristics data which is registered in the storage means 6.
The communication means 11 is a means for downloading or uploading the characteristics data registered in the storage means 6. This communication means 11 can be realized by a communication control unit installed in a computer or by various types of communication control means.
Overview of Gas Leak Detection Procedure
As shown in
In the instantaneous flow volume time differential operation means 3 and the pressure time differential operation means 4, the instantaneous flow volume time differential value (d/dt)Q and the pressure time differential value (d/dt)P are respectively operated from the measured instantaneous flow volume data Q and pressure data P (S120: time differential operation processing). The data obtained by the measurement means 1, 2 and the time differential operation means 3, 4, in other words, the instantaneous flow volume data and the instantaneous flow volume time differential value data, and the pressure data and the pressure time differential value data are supplied to the characteristics extraction means 5.
At each occurrence of a previously set characteristics extraction process timing, the characteristics extraction means 5 extracts the characteristics of the gas flow passing through the gas flow channel which is the object of judgment, on the basis of the acquired instantaneous flow volume data and instantaneous flow volume time differential value data, and the acquired pressure data and pressure time differential value data (S130: characteristics extraction processing).
In this characteristics extraction processing performed by the characteristics extraction means 5, firstly, the noise in the instantaneous flow volume data is removed, and the flow volume data which is to be the object of characteristics extraction is extracted from the instantaneous flow volume data after noise removal. The characteristics of the gas flow volume are then extracted on the basis of the extracted flow volume data, and the instantaneous flow volume time differential value and pressure value, and the like, corresponding to same.
The characteristics are extracted here for respective data types, such as the length (continuation time), initial flow volume, average value, gradient, standard deviation, and the like, in addition to which the characteristics of combinations of a plurality of data types are also extracted. In this case, various different combinations of a plurality of data types can be considered, but in the present embodiment, at least the characteristics of a combination of the instantaneous flow volume data and the instantaneous flow volume time differential value are extracted. More specifically, the “sequence of transited regions” is extracted as the characteristics of the combination of the instantaneous flow volume data and the instantaneous flow volume time differential value. This “sequence of transited regions” means the sequence of the regions which represent the temporal transitions when the instantaneous flow volume and the instantaneous flow volume time differential value are plotted on a two-dimensional graph and divided into regions.
Characteristics data which represents a plurality of characteristic elements, such as the length (continuation time), initial flow volume, average value, gradient, standard deviation, and sequence of transited regions, which have been obtained by the characteristics extraction processing performed by the characteristics extraction means 5, are supplied to the leak detection means 7.
The leak detection means 7 detects the presence or absence of a gas leak by comparing the characteristics data of the respective gas appliance types or the existence of a gas leak which is registered in the storage means 6 with the newly extracted characteristics data which has been extracted by the characteristics extraction means 5 (S140: leak detection processing). Further details of leak detection processing are described below. In the leak detection processing performed by the leak detection means 7, a judgment result is outputted to the warning means 9 when it is judged that there is a gas leak (YES in S141).
Furthermore, when it is judged by the leak detection means 7 that there is no gas leak (NO at S141) and if there is no data which matches the newly extracted characteristics data, in the existing characteristics data which has been registered by the storage means 6 (NO at S142), this means that the appliance in use is a new gas appliance which does not correspond to the existing characteristics data. In this case (NO at S142), the newly extracted characteristics data forming the basis of the judgment is supplied to the characteristics data registration means 8.
On the other hand, when it is judged by the leak detection means 7 that there is no gas leak (NO at S141) and if there is data which matches the newly extracted characteristics data in the existing characteristics data which has been registered in the storage means 6 (YES at S142), then the appliance in use is an appliance which corresponds to the existing characteristics data. In this case (YES at S142), a judgment result which indicates a matching with the existing characteristics data is supplied to the characteristics data registration means 8.
If the leak detection means 7 has judged that there is a gas leak (YES at S141), then the warning means 9 outputs an judgment result which indicates a gas leak in a form which can be presented or reported to a human operator, such as a display or print-out of a warning message, or a warning sound, or the like (S150: warning processing).
Upon receiving the newly extracted data which indicates a plurality of characteristic items, such as the length (continuation time), initial flow volume, average value, standard deviation and sequence of transited regions, from the leak detection means 7, (NO at S142), the characteristics data registration means 8 registers this newly extracted characteristics data in the storage means 6 as new characteristics data which corresponds to a new gas appliance type which has not yet been registered (S160: registration processing).
If a judgment result showing a matching with existing characteristics data has been received by the characteristics data registration means 8 (YES at S142), then either an indicator value which represents the use frequency is registered additionally in the existing characteristics data, or an additional indicator value which has already been registered is updated (S161: use frequency registration processing).
The unused data deletion means 10 carries out use frequency judgment with respect to the characteristics data which is registered in the storage means 6, at a previously set unused data judgment timing, such as when the characteristics data in the recording means 6 is updated or at a prescribed cycle, or when an unused data judgment instruction is issued, and if there is characteristics data having a use frequency not more than a prescribed level, then this data is deleted as unused data (S170: unused data deletion processing).
The communication means 11 downloads or uploads the characteristics data registered in the storage means 6, at a previously set communication timing, such as whenever the characteristics data in the storage means 6 is updated or at a prescribed cycle, of if a data download instruction of upload instruction has been issued (S180: communication processing). By carrying out communication processing of this kind, it becomes possible to exchange and use the characteristics data mutually, between the gas leak detection apparatus according to the present embodiment and other external apparatuses or systems.
Details of Gas Leak Detection Procedure
Below, a concrete example of the composition of the characteristics data used in the gas leak detection procedure shown in
Example of Composition of Characteristics Data
Here, the “length division” is a division number which indicates a division obtained by dividing the assumed range of the length of the continuation time into a plurality of divisions. The “transited regions” are region numbers which indicate the transitions of the instantaneous flow volume Q and the instantaneous flow volume time differential value (d/dt)Q in a case where the X-Y plane of the instantaneous flow volume Q and the instantaneous flow volume time differential value (d/dt)Q shown in
Moreover, in addition to these characteristic items, the last matching and frequency items are provided as indicator values which indicate the use frequency. For example, the “last matching” states the number of days which have elapsed since the last date and time that a matching was achieved by comparison with the newly extracted characteristics data in the leak detection processing, and the “frequency” states the number of times that a matching has been achieved in the past.
Example of Characteristics Extraction Processing
As stated above, in the characteristics extraction processing (S130 in
In the example shown in
As shown in
Furthermore, in the case of a proportionately controlled apparatus such as a fan heater, the amount of combustion is controlled in a stepwise fashion from maximum combustion until steady combustion, and therefore it is possible to extract the characteristics of the transitions of the amount of combustion accurately by dividing only the portion where (d/dt)Q is close to zero into fine divisions on the basis of the value of Q as shown in
In the example shown in
One Example of Leak Detection Processing
In the leak detection processing (S140 in
As shown in
If there is no characteristics data which matches the newly extracted characteristics data in the existing characteristics data (NO at S1402), then this means at the least that a gas appliance corresponding to the existing characteristics data is not in use, but in this case, moreover, it is judged whether or not the instantaneous flow volume time differential value in the newly extracted characteristics data is not less than a prescribed value or not less than a prescribed ratio, in other words, whether or not the change in the flow volume is not less than a prescribed level (S1403). In the present specification, the “prescribed value”, “threshold value” and “prescribed ratio” mean various boundary values or reference values which are previously established as range limits or for use in comparison and judgment. These boundary values can be included in either of higher and lower ranges which are divided by the respective values, but in the present embodiment, merely as one example, these values are included in respective higher ranges.
If the time differential value of the instantaneous flow volume in the newly extracted characteristics data is less than a prescribed value or less than a prescribed ratio, and the change in the flow volume is less than a prescribed level (NO at S1403), then it is furthermore judged whether or not the standard deviation of the instantaneous flow volume in the newly extracted characteristics data is not less than the prescribed value or is not less than a prescribed ratio, in other words, if the dispersion in the flow volume is not less than a prescribed level (S1404).
If the standard deviation of the instantaneous flow volume in the newly extracted characteristics data is less than the prescribed value or less than the prescribed ratio, and the dispersion in the flow volume is less than the prescribed level (NO in S1404), then it is further judged whether or not the standard deviation of the ratio between the instantaneous flow volume and the square root of the pressure in the newly extracted characteristics data is not less than a prescribed value or is not less than a prescribed ratio (S1405). In other words, if the ratio between the flow volume and the square root of the pressure is determined, then this value corresponds to the amount of opening of the gas spray nozzle section of the gas appliance, and therefore it is possible to judge whether or not the nozzle dispersion is not less than a prescribed level by determining the standard deviation in the ratio between the flow volume and the square root of the pressure.
If the standard deviation in the ratio between the instantaneous flow volume and the square root of the pressure in the newly extracted characteristics data is less than a prescribed value or less than a prescribed ratio, and the nozzle dispersion is less than the prescribed level (NO at S1405), then it is judged that there is a gas leak and this judgment result is outputted to the warning means 9 (S1406).
Furthermore, if there is characteristics data in the existing characteristics data which matches the newly extracted characteristics data (YES at S142), then this means that a gas appliance corresponding to this characteristics data is in use and hence there is no gas leak. Accordingly, it is judged that there is no gas leak or that an appliance is in use (S1407).
On the other hand, if the time differential value of the instantaneous flow volume in the newly extracted characteristics data is not less than a prescribed value or not less than a prescribed ratio (YES at S1403), or the standard deviation of the instantaneous flow volume is not less than a prescribed value or not less than a prescribed ratio (YES at S1404), or the standard deviation of the ratio between the instantaneous flow volume and the square root of the pressure is not less than a prescribed value or not less than a prescribed ratio (YES at S1405), in any of these cases, then there is no gas leak and a new gas appliance which does not correspond to existing characteristics data is in use. Therefore, it is judged that there is no gas leak or that an appliance is in use (S1408). In this case, the newly extracted characteristics data is supplied to the characteristics data registration means 8 and is registered as characteristics data for a new appliance (S1409).
According to the leak detection processing described above, if the newly extracted characteristics data does not match the existing characteristics data which is registered in the storage means 6, then it is only judged that there is a gas leak if the change in the flow volume, the dispersion in the flow volume, and the nozzle dispersion are each not more than a prescribed level, and therefore it is possible to judge the presence and absence of a gas leak in an accurate fashion.
Example of Unused Data Deletion Processing
In the unused data deletion processing which is performed by the unused data deletion means 10 (S170 in
When the composition of the characteristics data shown in
By carrying out unused data deletion processing of this kind, it is possible mechanically to delete characteristics data having a use frequency which is not more than a prescribed level, and therefore it is possible to prevent unnecessary registration and accumulation of unwanted characteristics data. Accordingly, it is possible to prevent situations, such as insufficient capacity of the storage means due to the accumulation of unwanted characteristics data, or decline in the characteristics data search speed during the leak detection process as a result of increase in the volume of characteristics data. Moreover, as an adaptation example, it is also possible to deal with characteristics data such that basic data, which is characteristics data which has been prepared in advance in an initial stage before the start of operation of the gas leak detection apparatus is not deleted, but rather only the characteristics data which has been registered newly after the start of operation is taken as an object for deletion.
Advantageous Effects of the Embodiment
According to the embodiments described above, advantageous effects of the following kind are obtained.
Firstly, as stated above, the present invention is premised on the fact that a flow volume pattern in which a flow volume occurs and then returns to a zero flow volume relates not a gas leak but rather to an appliance in use, and if a new flow volume pattern of this kind is extracted, this is registered as characteristics data and is used for subsequent gas leak detection. For example, the flow volume pattern such as that shown in
On the other hand, in the present embodiment, firstly, if the characteristics of a newly extracted flow volume pattern matches the flow volume pattern of registered characteristics data, then it can be judged that an appliance corresponding to the characteristics data is in use, and it if does not match, then it can be judged that there is a gas leak or that a new appliance is in use. Furthermore, if it does not match, then it is judged whether or not there is a flow volume variation or nozzle variation, on the basis of the combination of the instantaneous flow volume and the time differential value of the instantaneous flow volume and the ratio between the flow volume and the square root of the pressure, and this results in that it can be detected rapidly and accurately whether there is a gas leak or whether an unregistered appliance is in use.
If there is a flow volume variation or nozzle variation, then this means that there is an appliance which implements flow volume control of some kind, and therefore by registering the characteristics of this flow volume pattern as characteristics data for a new appliance, these characteristics can be used in subsequent detection and judgment of gas leaks. Furthermore, if there is no flow volume variation or nozzle variation, then there is a high probability of a gas leak and therefore it is possible to respond swiftly to a gas leak by issuing a warning.
In particular, in the present embodiment, leak detection is carried out by determining the ratio between the flow volume and the square root of the pressure, and therefore it is possible to judge accurately the presence of a governor. As stated previously, since the ratio of the flow volume and the square root of the pressure corresponds to the amount of opening of the gas spray nozzle section of the gas appliance, if the amount of opening of the gas spray nozzle is altered in response to pressure change so as to maintain a uniform flow volume, it can be judged that there is a governor, and if the amount of opening of the gas spray nozzle is uniform and the flow volume changes, it can be judged that there is no governor.
If no governor is present, then either there is a gas appliance which is not fitted with a governor, such as a cooking stove, or there is a gas leak, and a governor is present, then there is a gas appliance which is fitted with a governor, such as a fan heater. Consequently, it can be judged accurately between a gas leak or a cooking stove which requires the gas supply to be shut off especially by a safety function, and an appliance such as a fan heater, in which it is necessary to prevent unwanted shut-off. Therefore, it is possible to prevent mistaken shut-off in the case of prolonged use of a gas appliance which is fitted with a governor, such as a fan heater.
Furthermore, since it is possible to judge the start-up point and the switch-off point of the gas appliance, on the basis of the ratio between the flow volume and the square root of the pressure, or a substitute value, then it is possible to judge efficiently and accurately between the occurrence of a gas leak and the continued use of a gas appliance which is not fitted with a governor. In relation to this, it is also possible to measure the continuous use time of the gas appliance, and therefore an operation for issuing a suitable warning in respect of the prolonged use of a gas appliance, or the like, becomes possible.
If the gas pressure change is relatively small, then the pressure value itself is used as a substitute value for the square root of the pressure, and the presence of a governor can be judged with little error, simply by determining the ratio between the flow volume and the pressure. If the presence of a governor is judged by determining the ratio between the flow volume and the pressure in this way, then the calculational load can be reduced in comparison with a case where the ratio between the flow volume and the square root of the pressure is determined, and therefore the efficiency can be improved. On the other hand, if the variation in the gas pressure is relatively large, then better accuracy can be achieved by finding the ratio between the flow volume and the square root of the pressure.
Consequently, according to the present embodiment, it is possible to provide a gas leak detection apparatus and method whereby mistaken detection of a gas leak can be prevented, even when using an appliance which has been newly fitted in a dwelling receiving a gas supply, and whereby a gas leak can be detected rapidly, efficiently and accurately. Furthermore, it is also possible to judge accurately and efficiently the presence or absence of a governor in use, and it is also possible to judge efficiently and accurately between the occurrence of a gas leak and the continuous use of a gas appliance which is not fitted with a governor.
The present invention is not limited to the embodiments described above and various other modifications are possible, within the scope of the invention. Firstly, the composition of the apparatus indicated in the present embodiment is merely an example, and the concrete composition of the apparatus and the composition of the respective means can be selected freely, in which case the concrete processing procedure and the details of the respective processings can also be selected freely in accordance with same.
For example, in the present embodiment, the pressure is measured and the presence of a nozzle variation can be judged by determining the ratio between the flow volume and the square root of the pressure, but as a modification example, it is also possible to obtain the advantageous effects of the present invention simply by judging the presence or absence of a flow volume variation by determining the combination of characteristics of the instantaneous flow volume and the time differential value of the instantaneous flow volume. In this case, the comparison and judgment of pressure-related data is omitted from the leak detection processing.
In relation to this, in the leak detection processing, the actual processing other than the comparison between newly extracted characteristics data and registered characteristics data can be modified appropriately. For instance, in the leak detection processing, it is possible to judge that there is a gas leak after a prescribed period of time, if the extracted characteristics of the gas flow do not match any of the registered characteristics data, and in this case also, the advantageous effects of the present invention are obtained.
Furthermore, in the present embodiment, a case was described in which previously prepared characteristics data has been registered in the storage means in an initial stage before the start of operation of the gas leak detection apparatus, but the present invention may also be applied to a case where characteristics data is not prepared in an initial stage. In this case, for example, an operational procedure is adopted whereby a prescribed data accumulation time (for example, 10 days) is established in an initial stage, and during this prescribed time period, characteristics are extracted and characteristics data is registered so as to accumulate a certain amount of characteristics data, whereupon the gas leak detection judgment is commenced.
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