JP2009168651A - Gas meter, portable terminal and centralized monitoring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gas meter for giving an inspection instruction of a gas apparatus at an optimum time in each optimum period to perform efficient inspection, and a centralized monitoring system. <P>SOLUTION: The gas meter 2 detects a use time of each of gas apparatuses 11, and transmits the periodically detected use time of each of the gas apparatuses 11 to a central monitoring device 3 or a portable terminal 25. The central monitoring device 3 or the portable terminal 25 instructs inspection and replacement to the gas meter 2 or a dealer at each time when the use time of each gas equipment 11 exceeds an inspection period and a replacement period determined for each component of the gas apparatus 11. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a gas meter and a centralized monitoring system, and more particularly, a flow rate detection means for detecting a flow rate of gas supplied to a gas appliance, and a flow rate integration for obtaining a gas usage amount by integrating the gas flow rate detected by the flow rate detection means. And a centralized monitoring system that centrally monitors a plurality of gas meters, and a portable terminal that communicates with the gas meter.

  Conventionally, maintenance (inspection) and replacement of gas appliances in each household have been performed as follows. First, an operator manually inputs a predetermined maintenance time into a database of a center (centralized monitoring device) for each household gas appliance. Instruct the inspector to inspect at every maintenance time input by the center. Then, the inspector performs a predetermined inspection, and if a deterioration of the part is found at the site (each household), the part is replaced.

  However, the deterioration of the parts of the gas appliance depends on the usage (operation) time of the gas appliance, not just the installation date. Even if the same gas appliance is rarely used, there is almost no deterioration even if a predetermined maintenance time comes and an inspection is performed, and there is no need to replace it, and the inspection becomes wasteful man-hours. Gas appliances tend to be less prone to degradation if the usage time is short.

  On the other hand, if it is always used, deterioration may occur before the predetermined maintenance time comes, and the gas appliance may continue to be used in an unstable state without noticing it. Gas appliances tend to deteriorate if used frequently. The degree of deterioration differs depending on the actual use (operation) time. Therefore, the maintenance must be performed every shortest period during which no failure occurs under the worst condition use. It is a waste of maintenance costs (inspection man-hours, replacement parts costs). Conventionally, as described above, there has been a problem that inefficient periodic inspection has been performed according to instructions from the center.

  Therefore, the present invention pays attention to the above-described problems, and can provide a gas appliance inspection instruction at an optimal timing for each optimal period, and can perform an efficient inspection. The objective is to provide a centralized monitoring system.

  The invention according to claim 1, which has been made to solve the above-mentioned problems, obtains an integrated flow rate by integrating a flow rate detection means for detecting a flow rate of gas supplied to a gas appliance, and a gas flow rate detected by the flow rate detection means. In the gas meter having a flow rate integrating means, the use time detecting means for each device for detecting the use time for each gas appliance from the gas flow rate detected by the flow rate detecting means, and the use time detecting means for each appliance detected by the gas flow rate detecting means. A gas meter comprising: a first external output unit that outputs a use time for each gas appliance or a value corresponding to the use time to the outside.

  The invention according to claim 2 has an instrument-specific flow rate detection means for detecting a gas flow rate for each gas instrument from the gas flow rate detected by the flow rate detection means, and the first external output means is the Both the usage time for each gas appliance detected by the usage time detection means for each appliance and the gas flow rate for each gas appliance detected by the flow rate detection means for each appliance, or a value corresponding to both. The gas meter according to claim 1, wherein the gas meter is set to output.

  Invention of Claim 3 is a portable terminal which communicates with the gas meter of Claim 1 or 2, Comprising: The usage time according to the said gas appliance which the said 1st external output means of the said gas meter output, or A first input means for inputting a value according to the use time, and a use time for each gas appliance input by the first input means, or a value according to the use time. An inspection judging means for judging that it is necessary to inspect the parts of the gas appliance corresponding to the exceeded inspection threshold every time the inspection threshold determined corresponding to each part of the gas appliance is exceeded; A portable terminal characterized by comprising: a first check notification means for notifying a part of a gas appliance that is determined to be inspected by the determination means.

  According to a fourth aspect of the present invention, when a use time for each gas appliance or a value corresponding to the use time exceeds a threshold value for life determined corresponding to each part of the gas appliance, the lifetime is determined. Replacement judgment means for judging that it is necessary to replace the gas appliance exceeding the threshold for use, and replacement notification means for informing the gas appliance judged to be exchanged by the replacement judgment means. It exists in the portable terminal of Claim 3 characterized by these.

  The invention according to claim 5 includes the gas meter according to claim 1 or 2 and a centralized monitoring device installed outside the gas meter, and the centralized monitoring device is the first of the gas meter. A first input means for inputting a use time for each gas appliance output by one external output means, or a value corresponding to the use time, and the gas input by the first input means. Each time the usage time for each appliance or the value corresponding to the usage time exceeds the inspection threshold determined for each part of the gas appliance, the gas appliance corresponding to the exceeded inspection threshold Inspection judging means for judging that the parts need to be inspected, and first inspection notification means for notifying the parts of the gas appliance judged to be inspected by the inspection judging means. Centralized monitoring system It resides in.

  According to a sixth aspect of the invention, the centralized monitoring device has a life time for each gas appliance, or a value corresponding to the usage time exceeds a life threshold value determined corresponding to each part of the gas appliance. A replacement determination means for determining that the gas appliance that has exceeded the lifetime threshold needs to be replaced, and a replacement notification means for notifying the gas appliance that has been determined to be replaced by the replacement determination means. And a centralized monitoring system according to claim 5.

  According to a seventh aspect of the present invention, the first inspection notification means determines whether or not the part of the gas appliance that is determined to require inspection is a part that can be inspected by a user. A second external output means for outputting the gas appliance part to the gas meter when the gas instrument part is inspectable by the user, and the gas meter is connected to the second external output means. A second input means for inputting the parts of the gas appliance determined to require the inspection, and the gas appliance determined to require the inspection input by the second input means; The centralized monitoring system according to claim 5, further comprising: a second inspection notification unit that notifies the parts.

  As described above, according to the first aspect of the present invention, the usage time detection means detects the usage time for each gas appliance from the gas flow rate detected by the flow rate detection means, and the first external output means detects the usage time. Since the usage time for each gas appliance detected by the means or a value corresponding to the usage time is output to the outside, the usage time for each gas appliance output to the outside or a value corresponding to the usage time is output. If it inputs into a centralized monitoring apparatus, the centralized monitoring apparatus can give an inspection instruction | indication based on the use time of a gas appliance, or the value according to the usage time. Moreover, if the value according to the usage time for each gas appliance output to the outside or the usage time is input to the portable terminal, the portable terminal is based on the usage time of the gas appliance or the value according to the usage time. Inspection instructions can be given. Thereby, the inspection instruction | indication of a gas appliance can be issued at the optimal timing for every optimal period, and an efficient inspection can be performed.

  According to the second aspect of the present invention, the first external output means is detected by the usage time detecting means, paying attention to the fact that the deterioration of the gas depends not only on the usage time but also on the gas usage amount. It is set to output both the usage time for each gas appliance and the gas flow rate for each gas appliance detected by the appliance-specific flow rate detection means, or a value corresponding to both, as a value corresponding to the usage time. Therefore, if both the usage time for each gas appliance output to the outside and the gas flow rate for each gas appliance, or values corresponding to both are input to the central monitoring device, the central monitoring device Inspection instructions can be given based on both usage time and gas flow rate. Thereby, the inspection instruction | indication of a gas appliance can be further issued at the optimal timing for every optimal period, and an efficient inspection can be performed.

  According to the third aspect of the present invention, in the portable terminal, the first input means inputs the usage time for each gas appliance output by the first external output means of the gas meter, or a value corresponding to the usage time. Each time the inspection judgment means inputs the use time for each gas appliance input by the first input means, or the value corresponding to the use time exceeds the inspection threshold determined corresponding to each part of each gas appliance. , It is determined that the inspection of the gas appliance part corresponding to the inspection threshold exceeding that is necessary, and the first inspection notification means determines the part of the gas appliance determined to be inspected by the inspection determination means. Since the notification is made, the portable terminal can give an inspection instruction (notification) based on the usage time of the gas appliance or a value corresponding to the usage time. Thereby, the inspection instruction | indication of a gas appliance can be issued at the optimal timing for every optimal period, and an efficient inspection can be performed.

  According to the invention described in claim 4, in the portable terminal, the replacement judging means has a usage time for each gas appliance, or a value corresponding to the usage time exceeds a lifetime threshold determined for each gas appliance. Sometimes it is determined that it is necessary to replace a gas appliance whose life threshold has been exceeded, and the replacement notification means notifies the gas appliance that the replacement determination means has determined that replacement is necessary. The gas appliance replacement instruction (notification) can be given based on the usage time or a value corresponding to the usage time. Thereby, the exchange instruction | indication of a gas appliance can be issued at the optimal timing for every optimal period, and efficient replacement | exchange can be performed.

  According to the fifth aspect of the present invention, in the centralized monitoring apparatus, the first input means inputs the usage time for each gas appliance output by the first external output means of the gas meter, or a value corresponding to the usage time. Each time the inspection judgment means inputs the use time for each gas appliance input by the first input means or the value corresponding to the use time exceeds the inspection threshold value determined corresponding to each part of each gas appliance. In addition, it is determined that the inspection of the parts of the gas appliance corresponding to the inspection threshold exceeding that is required, and the first inspection notification means determines that the inspection is required by the inspection determination means. Therefore, the centralized monitoring device can give an inspection instruction (notification) based on the usage time of the gas appliance or a value corresponding to the usage time. Thereby, the inspection instruction | indication of a gas appliance can be issued at the optimal timing for every optimal period, and an efficient inspection can be performed.

  According to the sixth aspect of the present invention, in the centralized monitoring device, the replacement determination means has a usage time for each gas appliance, or a value corresponding to the usage time exceeds a lifetime threshold determined for each gas appliance. When the gas monitoring apparatus determines that it is necessary to replace the gas appliance that has exceeded the life threshold value, the replacement notification unit notifies the gas appliance that is determined to be replaced by the replacement determination unit. A gas appliance replacement instruction (notification) can be given based on the usage time of the gas appliance or a value corresponding to the usage time. Thereby, the exchange instruction | indication of a gas appliance can be issued at the optimal timing for every optimal period, and efficient replacement | exchange can be performed.

  According to the seventh aspect of the present invention, in the first check notification means, it is determined whether or not the part of the gas appliance for which the check availability means is determined to be inspectable is a part that can be checked by the user. When the second external output means is a gas appliance part that can be inspected by the user, the gas appliance part is output to the gas meter. In the gas meter, the second input means inputs the part of the gas appliance determined to be inspected, which is output from the second external output means, and the second inspection notifying means is input by the second input means. Since the parts of the gas appliance determined to be inspected are notified, it is possible to notify the gas meter user of the parts of the gas appliance determined to be inspected. For this reason, if it is the inspection which a user can do, it can be performed by the user side, and a much more efficient inspection can be performed.

  Hereinafter, a gas meter and a centralized monitoring system of the present invention will be described with reference to the drawings. As illustrated in FIG. 1, the centralized monitoring system 1 includes a gas meter 2 and a centralized monitoring device 3 or a portable terminal 25. The gas meter 2 is provided in a gas supply facility 4 as shown in FIG. In the gas supply facility 4 shown in FIG. 2, the high pressure gas from the two gas containers 5A and 5B is supplied to the pressure regulator 7 via the high pressure hoses 6A and 6B. The pressure regulator 7 adjusts the high-pressure gas from the gas containers 5A and 5B to a gas having a predetermined pressure.

  The adjusted gas is supplied to the gas meter 2 through a gas pipe 9 having a closing cock 8 on the way, and then further through a gas pipe 9 and a branch gas pipe 10 branched from the gas pipe 9. The gas appliance 11 provided in the room is supplied. Examples of the gas appliance 11 include a gas water heater 11A, a gas stove 11B, a gas heater 11C, and a gas floor heater 11D. In addition, examples of the gas appliance 11 include a gas rice cooker, a gas dishwasher, a gas oven, a gas fan heater, a gas instantaneous water heater, and a gas heat pump (GHP) (all not shown).

  Next, the configuration of the gas meter 2 that operates by supplying power from the battery will be described with reference to FIG. The gas meter 2 has a microcomputer (μCOM) 12 that operates according to a predetermined program. As is well known, the μCOM 12 includes a central processing unit (CPU) 12A that performs various processes and controls according to a predetermined program, a ROM 12B that is a read-only memory storing a program for the CPU 12A, and various data. And a RAM 12C, which is a readable / writable memory having an area necessary for processing operations of the CPU 12A.

  Further, the gas meter 2 is capable of storing various stored data even when the power supply from the battery is cut off, and is an electrically erasable / rewritable read-out having various storage areas necessary for processing operations of the CPU 12A. A dedicated memory (EEPROM) 13 is provided. This EEPROM 13 is an integrated flow rate obtained by integrating the detected gas flow rate, an appliance discrimination table for discriminating the start and end of use for each gas appliance 11, and a gas for counting the time from the start of use of the gas appliance 11 to the end of use. It has various areas for storing usage time counters and the like provided for each appliance 11.

  The gas meter 2 further includes a flow rate sensor 14 as a flow rate detection unit, a display unit 15, an operation unit 16, and a communication unit 17, each of which is connected to the μCOM 12 via an interface unit 18. As the flow rate sensor 14, a gas sensor in the gas meter 2, that is, a flow sensor for detecting a flow rate of gas flowing through the gas pipe 9 is used. Then, the flow rate sensor 14 is driven according to the sampling signal output by the μCOM 12 and inputs the detection result of the gas flow rate to the μCOM 12.

  As the display unit 15, a liquid crystal display (LCD) that displays various information such as an integrated value of gas usage and an alarm is used, and the display is performed under the control of the μCOM 12. The operation unit 16 includes a plurality of operation switches, and a signal corresponding to an operation of a meter reader or the like is input to the μCOM 12. A wireless unit is used for the communication unit 17 and enables communication with the centralized monitoring device 3 or the portable terminal 25 of the gas dealer via wireless communication, and is controlled by the μCOM 12.

  Next, the configuration of the centralized monitoring device 3 and the portable terminal 25 will be described. As shown in the figure, the centralized monitoring device 3 or the portable terminal 25 has a μCOM 19 that operates according to a predetermined program. Similar to the μCOM 12 of the gas meter 2, the μCOM 19 includes a CPU 19A, a ROM 19B, a RAM 19C, and the like. Further, the centralized monitoring device 3 and the portable terminal 25 can store various stored data even when the power supply is cut off, and can be electrically erased / rewritten with various storage areas necessary for the processing operation of the CPU 19A. A read-only memory (EEPROM) 20 is included. Note that the mobile terminal referred to here is a setting device, a handy terminal, a mobile phone, or the like.

  The EEPROM 20 stores an inspection / replacement table indicating an inspection period (= inspection threshold value) and replacement period (= lifetime threshold value) for parts of each gas appliance 11. The components of the gas appliance 11 include an ignition device such as a gas water heater 11A and a gas stove 11B, a valve such as a gas dishwasher and a gas heat pump, a gas water heater 11A, a gas stove 11B, a gas rice cooker temperature sensor, and a gas water heater. There are clogged burners such as 11A and gas stove 11B, a filter such as gas heater 11C, and a circulation pump for gas floor heating 11D. An inspection period and a replacement period are determined for each part of the gas appliance 11. Further, the EEPROM 20 stores an inspection availability table indicating whether or not the user can inspect each part of the gas appliance 11.

  The centralized monitoring device 3 and the portable terminal 25 further include a display unit 21, an operation unit 22, and a communication unit 23, each of which is connected to the μCOM 19 via the interface unit 24. The display unit 21 is a liquid crystal display (LCD) that displays various types of information such as the parts of the gas appliance 11 to be inspected or replaced, and performs display under the control of the μCOM 19. The operation unit 22 includes a plurality of operation switches, and a signal corresponding to the operation of the sales clerk is input to the μCOM 19. The communication unit 23 is wireless, and can be communicated with the gas meter 2 or a store computer via the wireless communication, and is controlled by the μCOM 19.

  Next, the operation of the centralized monitoring system 1 configured as described above will be described. First, in response to the power supply, the CPU 12A in the gas meter 2 functions as a flow rate integration unit, and starts a flow rate integration process for integrating the gas flow rate flowing in the gas pipe line 9 shown in FIG. In the flow rate integration process, the CPU 12A drives the flow rate sensor 14 to detect the gas flow rate Q (step S1). Thereafter, the CPU 12A stores a value obtained by adding the gas flow rate Q detected in step S1 to the integrated flow rate Qs stored in the RAM 12C as a new integrated flow rate Qs (step S2), and the integrated flow rate Qs is stored in the display unit 15. After the display (step S3), the process returns to step S1.

  In addition, the CPU 12A functions as an appliance-specific usage time detection unit, and performs an appliance-specific usage time detection process for counting the usage time for each gas appliance 11 shown in FIG. 4 in parallel with the flow rate integration process. First, the principle of the usage time detection process for each appliance will be described with reference to FIG. As shown in FIG. 4A, when the use of a new gas appliance 11 is started at time t1, the gas flow rate increases and becomes constant at a flow rate Qn + 1 (> Qn). More specifically, as shown in FIG. 5B, the gas flow rate overshoots the flow rate Qn + 1 to a peak flow rate Qpo, and after a predetermined time Δt1, undershoots to the flow rate Qn + 1 to become a flow rate Qpu. Thereafter, the flow rate is stabilized at Qn + 1 after a predetermined time Δt2.

  On the other hand, overshoot and undershoot do not occur when the gas flow rate increases without starting to use the new gas appliance 11. Therefore, if the flow rate is stabilized after repeating overshoot and undershoot when the gas flow rate is increased, it can be determined that the use of a new gas appliance 11 has started. In addition, a slope when the gas flow rate increases with the start of use of the new gas appliance 11 (a slope between the start of increasing the flow rate and the peak flow rate Qpo), and a peak increase amount ΔQpo at the peak flow rate Qpo (= Qpo−Qn) is a different value for each gas appliance 11. Therefore, an appliance discrimination table indicating the gradient of the gas flow rate and the peak increase amount ΔQpo for each gas appliance 11 is stored in advance in the EEPROM 13.

  When it is determined that the use of a new gas appliance 11 has started, the gas appliance 11 that has started to be used can be determined from the slope of the gas flow rate obtained at this time and the peak increase amount ΔQpo, and the appliance determination table. In addition, when the gas flow rate increase amount ΔQ = Qn + 1−Qn with the start of use of the new gas appliance 11 is reduced, it is possible to determine the stoppage of use of the gas appliance 11 that is determined to be started. Based on the determination of the start and end of use of the gas appliance 11, the usage time can be calculated for each gas appliance 11.

  Next, details of the use time detection process for each appliance described in the outline will be described with reference to FIG. First, in response to power supply, the CPU 12A in the gas meter 2 monitors the gas flow rate Q detected by the flow rate integration process (step S11). If the CPU 12A determines that an increase in the gas flow rate with overshoot and undershoot has occurred as a result of monitoring the gas flow rate Q (Y in step S12 and Y in step S13), the use of the new gas appliance 11 is confirmed. It is determined that the process has been started, and the process proceeds to the next step S14.

  In step S14, the CPU 12A determines the gas appliance 11 that has started to be used. At this time, the CPU 12A obtains the slope of the gas flow rate and the peak increase amount ΔQpo. Thereafter, the CPU 12A searches for the gas appliance 11 with respect to the obtained slope of the gas flow rate and the peak increase amount ΔQpo from the appliance discrimination table stored in the EEPROM 13, and the gas appliance 11 that has started to use the searched gas appliance 11 Determine.

  Next, the CPU 12A turns on a use flag provided for the gas appliance 11 determined to have been used in step S14 (step S15). Thereafter, the CPU 12 obtains the increase amount ΔQ of the gas flow rate accompanying the start of use of the new gas appliance 11, and registers it in the EEPROM 13 as the increase amount ΔQ of the gas appliance 11 whose use flag is turned on in step S15 (step S15). S16). Next, the CPU 12A starts counting by the use time counter provided for the gas appliance determined to have been used in step S14 (step S17), and then returns to step S11.

  On the other hand, while the gas flow rate increase accompanied by overshoot and undershoot does not occur (N in step S12 or N in step S13), the CPU 12A has the newly started gas appliance 11 in use. It judges that there is no, and progresses to step S18. In step S18, if the CPU 12A determines that the flow rate decrease corresponding to the increase amount ΔQ registered corresponding to the gas appliance 11 for which the use flag is turned on (Y in step S18), the CPU 12A corresponds to the increase amount ΔQ. It is determined that the use of the gas appliance 11 is stopped, and the use flag of the gas appliance 11 is turned off (step S19).

  Thereafter, the CPU 12A stops counting by the use time counter provided for the gas appliance 11 that has been determined to have been stopped (step S20), and then returns to step S11. On the other hand, the CPU 12A determines that there is no gas appliance 11 that has been newly used while the flow rate decrease by the increase amount ΔQ has not occurred (N in step S18), and returns to step S11. Thereby, the usage time for each gas appliance 11 can be counted by the usage time counter provided for each gas appliance 11. Further, the gas meter 2 described above functions as a first external output means, and attaches identification information of the gas meter 2 to various information such as an integrated flow rate and a usage time for each gas appliance 11 every fixed period such as one day. Then, the data is transmitted to the centralized monitoring device 3 or the portable terminal 25 via the communication unit 17.

  Note that the above-described method of obtaining the usage time for each gas appliance 11 is an example, and other known methods described in, for example, Japanese Patent Application Laid-Open Nos. 2003-194331, 2003-148728, 2003-149019, and the like. The method may be used.

  Next, operations of the centralized monitoring device 3 and the portable terminal 25 described above will be described below with reference to a flowchart of FIG. The CPU 19A of the centralized monitoring device 3 and the portable terminal 25 starts the inspection / replacement instruction process when the usage time for each gas appliance 11 transmitted from the gas meter 2 is input via the communication unit 23 as the first input means. . In the inspection / replacement instruction process, the CPU 19A functions as an inspection determination means, and refers to the above-described inspection / replacement table to determine whether the usage time from the previous inspection has exceeded the inspection period determined for each part of the gas appliance 11. Is determined (step S21). If there is a part that has passed the inspection time (Y in step S21), the CPU 19A functions as an inspection availability unit, and whether or not the part that has exceeded the inspection time is a part that can be inspected by the user based on the inspection availability table described above. Is determined (step S22).

  If it is a part that can be inspected by the user (Y in step S22), the CPU 19A functions as a first inspection notification unit and a second external output unit, and sets the inspection time for the gas meter 2 via the communication unit 23. After the part information of the gas appliance 11 that has exceeded, that is, needs to be inspected is transmitted to the gas meter 2 (step S23), the process proceeds to the next step S25. The CPU 19A in the gas meter 2 receives this component information via the communication unit 17 as the second input means. And the gas meter 2 functions as a 2nd inspection alerting | reporting means, for example, transmits component information to the alarm device installed indoors. Then, the parts information of the gas appliance 11 that needs to be inspected is notified from the alarm device to notify the user. For example, if the part of the gas appliance 11 that needs to be inspected is the burner of the gas stove 11B, the alarm device informs that “please clean and remove the clogging of the burner of the gas stove 11B”. Alternatively, a message may be displayed and notified on a home display board or the like.

  On the other hand, if it is not a part that can be inspected by the user (N in step S22), it acts as a first inspection notification means for a store or the like that can handle the gas meter 2 in which the gas appliance 11 that requires inspection is installed. After transmitting the parts information of the gas appliance 11 that needs to be checked and the installation location of the gas appliance 11 (step S24), the process proceeds to the next step S25. When this is received by the store-side computer or the portable terminal 25, the fact is notified. For example, if the part of the gas appliance 11 that needs to be inspected is the burner nozzle of the gas water heater 11A, it is informed that “Check the burner nozzle of the water heater at Yazaki-like house at 1234 in Tenryu-ku”.

  In step S25, the CPU 19A functions as a replacement determination unit, and refers to the inspection / replacement table described above to determine whether or not the usage time has exceeded the replacement time determined for each part of the gas appliance 11 from the previous replacement. to decide. If there is a part whose replacement time has passed (Y in step S25), the CPU 19A functions as a replacement notification means, and the CPU 19A replaces it with a store that can handle the gas meter 2 in which the gas appliance 11 requiring replacement is installed. After transmitting the necessary parts information of the gas appliance 11 and the installation location of the gas appliance 11 (step S26), the process returns to step S21. On the other hand, if there is no part whose inspection time or replacement time has passed (N in step S25), the CPU 19A immediately returns to step S21.

  According to the centralized monitoring system 1 described above, the gas meter 2 detects the usage time for each gas appliance 11 from the gas flow rate detected by the flow sensor 14, and outputs the detected usage time for the gas appliance 11 to the outside. . Then, the centralized monitoring device 3 or the portable terminal 25 inputs the usage time for each gas appliance 11 output from the gas meter 2, and the input usage time for each gas appliance 11 corresponds to each part of the gas appliance 11. Every time the specified inspection time is exceeded, it is judged that the inspection of the parts of the gas appliance 11 corresponding to the inspection time exceeding the predetermined time is necessary, and the fact is notified so that the centralized monitoring device uses the gas appliance 11. An inspection instruction (notification) can be given based on the time. Thereby, the inspection instruction | indication of the gas appliance 11 can be issued at the optimal timing for every optimal period, and an efficient inspection can be performed.

  For this reason, inspection instructions can be issued before parts deteriorate and break down, helping to prevent breakdowns, concentrating on risk management of detailed consumer equipment, and wasteful emergency of service personnel The number of dispatches decreases. Further, unnecessary maintenance costs can be reduced. Conventionally, a gas company has managed customer information individually, and inspected each gas appliance 11 of each user and managed life management with a manual input like a security ledger. According to the above, it is possible to perform the troublesome work of the gas company.

  Moreover, according to the centralized monitoring system 1 described above, when the centralized monitoring device 3 or the portable terminal 25 exceeds the replacement time determined corresponding to each part of the gas appliance 11, the usage time for each gas appliance 11 is exceeded. Since it is determined that it is necessary to replace the parts of the gas appliance 11 that have passed the replacement time and the fact is notified, the central monitoring device 3 or the portable terminal 25 determines the gas appliance 11 based on the usage time of the gas appliance 11. Exchange instructions (notifications) can be given. Thereby, the exchange instruction | indication of the gas appliance 11 can be issued at the optimal timing for every optimal period, and efficient replacement | exchange can be performed.

  Moreover, according to the centralized monitoring system 1 described above, the centralized monitoring device 3 or the portable terminal 25 outputs the parts of the gas appliance 11 determined to be inspected to the outside, and the gas meter 2 needs to be inspected. Since the part of the gas appliance 11 determined to be present is input and the fact is notified, the user of the gas meter 2 can be notified of the part of the gas instrument 11 determined to be inspected. For this reason, if it is the inspection which a user can do, it can be performed by the user side, and a much more efficient inspection can be performed.

  In the first embodiment, the usage time for each gas appliance 11 is transmitted to the centralized monitoring device 3 or the portable terminal 25, but the present invention is not limited to this. The deterioration of the gas appliance 11 depends not only on the usage time but also on the gas usage. Focusing on this, the gas flow rate for each gas appliance 11 is obtained, and the integrated value “use time × gas flow rate” for each gas appliance 11 is transmitted from the gas meter 2 to the centralized monitoring device 3 or the portable terminal 25. May be.

  In this case, the centralized monitoring device 3 or the portable terminal 25 records the inspection threshold and the life threshold determined for each part of the gas appliance 11 as in the first embodiment. The inspection threshold value and the life threshold value are determined corresponding to “use time × gas flow rate” as shown below. That is, 5000 [hour m3] is determined as a life threshold for the ignition device of the gas stove 11B, and 3000 [hour m3] is determined as a check threshold for a valve such as a gas heat pump. For the burner of the vessel 11A, 5000 [time m3] is set as the inspection threshold value. Thus, an exchange instruction is output to the dealer every time the accumulated value of the usage time of the gas stove 11B × the gas flow rate exceeds 5000 [time m3]. In addition, an inspection instruction is output to the dealer every time the integrated value of the gas heat pump exceeds 3000 [time m3]. Further, every time the integrated value of the gas water heater 11A exceeds 5000 [time m3], an instruction to clean the clogged burner of the gas water heater 11A is output to the user.

  In addition, as a method of calculating | requiring the gas flow rate according to the gas appliance 11 mentioned above, it can be considered that the amount increased at the time of rising of the gas flow rate is used as the flow rate of the gas appliance 11 that has started use. For example, when it is determined that the gas appliance A is being used after the gas flow rate increases from 0, the increase in the gas flow rate at the start of use is determined as the flow rate of the gas appliance A, and “ Find the integrated value of “usage time x gas flow rate”. Thereafter, when it is determined that the gas flow rate has increased again and a new gas appliance B has started to be used, the increased amount at that time is determined as the flow rate of the gas appliance B, and “use time × gas flow rate” of the gas appliance B Find the integrated value. For example, if it is determined that the gas flow rate of the gas appliance A is 120 L, and the gas flow rate detected by the flow sensor after the start of use of the gas appliance B is 300 L, then 300 L−120 L = 180 L is determined as the gas flow rate of the gas appliance B. To do. The above-described method for determining the amount of use for each gas appliance is merely an example. For example, for each gas appliance described in JP-A-2001-289684, JP-A-2002-71421, JP-A-2004-340603, JP-A-9-318407, and the like. A method of determining the amount of use may be used.

  Moreover, in embodiment mentioned above, although the usage time classified by gas appliance was transmitted to the centralized monitoring apparatus 3 through the communication part 17, this invention is not limited to this. The meter reader may use the handy terminal to read the usage time for each gas appliance 11 from the gas meter 2, carry it to the central monitoring device 3, and read it into the central monitoring device 3.

  In the above-described embodiment, the “usage time × gas flow rate” for each gas appliance 11 is transmitted from the gas meter 2 to the centralized monitoring device 3 or the portable terminal 25. However, the present invention is not limited to this. Absent. For example, the usage time for each gas appliance 11 and the gas flow rate for each gas appliance 11 may be separately transmitted from the gas meter 2 to the centralized monitoring device 3 or the portable terminal 25. Further, the maintenance information of the gas appliance 11 determined by the centralized monitoring device 3 may be transmitted to a mobile phone by e-mail or read out by a mobile phone via the Internet web.

  Further, the above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

It is a block diagram which shows one Embodiment of the centralized monitoring system of this invention. It is a block diagram which shows an example of the gas supply equipment incorporating the gas meter shown in FIG. It is a flowchart which shows the flow volume integration processing procedure of CPU which comprises the gas meter of FIG. It is a flowchart which shows the usage-time detection process procedure according to apparatus of CPU which comprises the gas meter of FIG. It is a time chart of the gas flow rate for explaining the flow rate increase accompanying the start of use of the gas appliance. It is a flowchart which shows the inspection / exchange instruction | indication process procedure of CPU which comprises the centralized monitoring apparatus or portable terminal of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Centralized monitoring system 2 Gas meter 3 Centralized monitoring apparatus 12A CPU (Flow rate integration means, use time detection means for each instrument, first external output means, second inspection notification means)
14 Flow rate sensor (flow rate detection means)
17 Communication unit (second input means)
19A CPU (inspection determination means, inspection availability / non-permission means, first inspection notification means, replacement determination means, replacement notification means, second external output means)
23 Communication unit (first input means)
25 Mobile devices

Claims (7)

In a gas meter having flow rate detection means for detecting a gas flow rate supplied to a gas appliance, and flow rate integration means for integrating the gas flow rate detected by the flow rate detection means to obtain an integrated flow rate,
A device-specific use time detection means for detecting a use time for each gas device from the gas flow rate detected by the flow rate detection means;
A first external output means for outputting the usage time for each gas appliance detected by the appliance usage time detection means or a value corresponding to the usage time to the outside;
A gas meter characterized by comprising: An instrument-specific flow rate detection means for detecting a gas flow rate for each gas instrument from the gas flow rate detected by the flow rate detection means; and
The first external output means includes both the usage time for each gas appliance detected by the usage time detection means for each appliance and the gas flow rate for each gas appliance detected by the flow rate detection means for each appliance. The gas meter according to claim 1, wherein the gas meter is set so as to output a value corresponding to the two. A portable terminal that communicates with the gas meter according to claim 1 or 2,
First input means for inputting a use time for each gas appliance output from the first external output means of the gas meter, or a value corresponding to the use time;
Whenever the usage time for each gas appliance input by the first input means or the value corresponding to the usage time exceeds a threshold value for inspection determined for each part of the gas appliance, An inspection determination means for determining that inspection of a part of the gas appliance corresponding to the inspection threshold value exceeding is necessary;
First inspection notification means for notifying parts of gas appliances determined to be inspected by the inspection determination means;
A portable terminal characterized by comprising: When the usage time for each gas appliance or the value corresponding to the usage time exceeds the lifetime threshold determined for each part of the gas appliance, the gas appliance exceeds the lifetime threshold. Replacement determination means for determining that it is necessary to replace,
Exchange notification means for informing the gas appliance determined to be exchanged by the exchange judgment means;
The mobile terminal according to claim 3, further comprising: A gas meter according to claim 1 or 2,
A centralized monitoring device installed outside the gas meter, and
The central monitoring device is configured to input a use time for each gas appliance output by the first external output means of the gas meter, or a value corresponding to the use time; Each time the usage time for each gas appliance input by the first input means or the value corresponding to the usage time exceeds the inspection threshold value determined corresponding to each part of the gas appliance, it exceeds the threshold. And a check judging means for judging that the inspection of the parts of the gas appliance corresponding to the threshold for inspection is necessary, and a first for informing the parts of the gas appliance judged to be inspected by the inspection judging means. A centralized monitoring system comprising: an inspection notification means. When the centralized monitoring device exceeds the life threshold value determined for each part of the gas appliance, the usage time for each gas appliance or the value corresponding to the usage time exceeds the threshold value for the lifetime Replacement determination means for determining that the gas appliance exceeding the limit needs to be replaced;
The centralized monitoring system according to claim 5, further comprising: a replacement notification unit that notifies a gas appliance that is determined to be replaced by the replacement determination unit. The first check notification means determines whether or not the part of the gas appliance that is determined to be inspected is a part that can be inspected by the user, and gas that can be inspected by the user. A second external output means for outputting the gas appliance part to the gas meter when the part is an instrument part; and
The gas meter is inputted by the second input means for inputting a part of the gas appliance determined to be inspected and outputted from the second external output means, and inputted by the second input means. The centralized monitoring system according to claim 5, further comprising: a second inspection notification unit that notifies a part of the gas appliance that is determined to be inspected.

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