JP6194479B2 - Secular change evaluation system - Google Patents

Description

  The present invention relates to a system for periodically acquiring and accumulating data related to characteristic values of a gas meter and evaluating secular changes based on the analysis result of the data.

  2. Description of the Related Art Conventionally, as a method for determining a secular change of a flow meter, one that monitors a minimum flow rate value and performs zero point correction is known (see, for example, Patent Document 1).

  FIG. 4 is a block diagram of the flow meter described in Patent Document 1.

  As shown in FIG. 4, the flow meter includes a measurement tube 101 through which a fluid flows, a flow rate measurement unit 102, a flow rate storage unit 103, a minimum flow rate value update unit 104, an operation unit 105, and a secular change determination unit 106. , And a zero point correction unit 107.

  The flow rate measurement unit 102 measures the flow rate of the fluid flowing through the measurement tube 101 at a predetermined cycle. The flow rate storage unit 103 stores the flow rate value measured by the flow rate measurement unit 102 and the lowest value of the flow rate values. When the flow rate of the fluid is measured by the flow rate measurement unit 102, the minimum flow rate value update unit 104 compares the latest flow rate value with the minimum flow rate value stored in the flow rate storage unit 103, and the latest flow rate value is more recent than the minimum flow rate value. When the flow rate value is smaller, the latest flow rate value is updated as the minimum flow rate value.

  The operation unit 105 includes means such as operation keys. The staff using the flow meter is configured to set the start / end of the storage period of the flow rate by operating the operation unit 105. The secular change determination unit 106 determines that there is no aging change in the flow meter if the minimum flow rate value in the predetermined period is zero, and determines that there is an aging change if the minimum flow rate value is other than zero. The zero point correction unit 107 corrects the zero point of the flow rate value measured by the flow rate measurement unit 102 when it is determined that there is a secular change.

JP 2012-194096 Gazette

  However, the above-described conventional configuration has a problem that only a characteristic value is updated when a secular change occurs in a single flowmeter, and the trend of the characteristic value over time is not monitored. It was. In addition, there is a problem that it is not possible to grasp a secular change trend that arises from the same population, such as a secular trend in a lot unit of production.

  The present invention solves the above-mentioned conventional problems, and can grasp a secular change tendency of a predetermined characteristic value and can grasp a secular change tendency generated from the same population.

In order to solve the conventional problems, an aging evaluation system of the present invention includes a plurality of gas meters each having a transmission / reception device, and an analysis evaluation system including a transmission / reception device that receives data transmitted from the transmission / reception device; given more becomes, the analytical evaluation system, the comprising: a storage device for storing data, an analysis evaluation device for analyzing evaluate the data stored in the storage device, the data is composed of each of a plurality of the gas meter Including an identification code assigned to each group and a predetermined characteristic value of the gas meter, and the analysis and evaluation system includes an initial value of the predetermined characteristic value and a predetermined value measured at the time of inspection for each group based on the identification code. The characteristic group is used to evaluate the secular change of the predetermined group.

  The secular change evaluation system of the present invention is configured to accumulate periodic inspection data from a plurality of gas meters in a storage device of a data collection center, and by evaluating and analyzing the accumulated data, the secular change tendency of gas meter characteristics is grasped. It is also possible to grasp the secular trends that arise from the same population.

Configuration diagram of secular change evaluation system in Embodiment 1 of the present invention The graph which shows the secular change data of the characteristic value in Embodiment 1 of this invention The flowchart which shows the progress of the analysis evaluation in Embodiment 1 of this invention Block diagram of a conventional flow meter that performs aging judgment

A first invention includes a plurality of gas meters each having a transmission / reception device, and an analysis / evaluation system including a transmission / reception device that receives data transmitted from the transmission / reception device. The analysis / evaluation system stores the data a storage device for, with the analytical evaluation device for analyzing evaluate the data stored in the storage device, the data includes identification codes, each of which is assigned to each predetermined group comprising a plurality of said gas meter, the gas meter The analysis evaluation system includes a predetermined characteristic value, and the analysis evaluation system evaluates the secular change of the predetermined group using the initial value of the predetermined characteristic value and the predetermined characteristic value measured at the time of inspection for each group unit based on the identification code. It is characterized by doing.

In a second aspect of the invention, the identification code is assigned as a group for each same production lot.

The third invention is characterized in that the identification code is assigned as a group for each same region.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
Embodiment 1 of the present invention will be described below with reference to FIGS.

  FIG. 1 is a configuration diagram of the secular change evaluation system in Embodiment 1 of the present invention.

  1, gas meters 2a, 2b,... Installed in each of a plurality of homes 1a, 1b,... Have transmission / reception devices 3a, 3b,.

  The data collection center 4 is provided with a transmission / reception device 5, and an analysis / evaluation system 6 is connected to the transmission / reception device 5. The analysis evaluation system 6 includes a storage device 7 and an analysis evaluation device 8.

  The aging change evaluation system 9 is constructed by the gas meters 2a, 2b... Of each home 1a, 1b..., The transmission / reception device 5 of the data collection center 4 and the analysis evaluation system 6.

  A sample graph of aging data analyzed and evaluated by the aging evaluation system 9 is shown in FIG.

  First, the characteristic value (initial value) of the gas meter is measured at the time of installation. After that, at each periodic inspection, the characteristic value of the gas meter is measured and recorded. For example, if the flow rate is measured using the propagation time of ultrasonic waves, the characteristic value of the gas meter changes with time, such as the propagation time when the flow rate is zero and the battery voltage used as the supply source. This is an expected value.

  In this way, the solid line portion described in this graph is filled with the records up to the second inspection.

  As shown in the graph of FIG. 2, a threshold value is set in advance for this characteristic value, and the situation where the threshold value is not exceeded in both the A group and the B group has not yet been reached.

  The group A and group B described here are units determined as a population having the same attribute, for example, for each production lot or for each region, and are classified by an identification code assigned in advance to the group. I try to do it.

  As can be seen from FIG. 2, when the graph results to some extent in the measurement results up to the second time, the third prediction can be performed. In the case of FIG. 2, it is expected that the group B exceeds the threshold in the third periodic inspection. Based on this expectation, a warning can be issued in advance and preparations can be made for the lot of Group B.

  As a specific period of the periodic inspection, for example, 8 years may be used for a long period of time, and for the purpose of finding an initial failure, it may be a unit of one month. It can be set arbitrarily.

  In order to enable the analysis as described above, it is necessary to store the initial values of the gas meters 2a, 2b,.

  As a procedure, first, it is determined whether or not the data in the individual gas meters 2a, 2b,... Will be performed.

  FIG. 3 is a flowchart showing a process of analysis evaluation in Embodiment 1 of the present invention.

  Next, the operation of the analysis evaluation system will be described with reference to FIGS. 1 and 3.

  In step S1, an initial value measurement signal for measuring an initial value of a predetermined characteristic and transmitting data is transmitted from the transmission / reception device 5 to a newly installed gas meter, for example, the gas meter 2a.

  The gas meter 2a that has received the initial value measurement signal from the transmission / reception device 5 measures the initial value of the predetermined characteristic value, and transmits data of the predetermined characteristic value from the transmission / reception device 3a to the data collection center 4. In addition to the measured predetermined characteristic value, a unique identification code individually assigned to the gas meter or a group identification code previously assigned to each meter is simultaneously transmitted to the data transmitted from the gas meter 2a.

  In step S <b> 2, data from the gas meter 2 a is received by the transmission / reception device 5, and the data is taken into the analysis evaluation system 6 and stored in the storage device 7.

  In step S3, it is determined whether or not the gas meter 2a is in a periodic inspection period. If it is not the periodic inspection time, the process proceeds to step S4. In step S4, a predetermined interval is set for the next measurement time of the predetermined characteristic value of the gas meter 2a and stored in the storage device 7. The interval here is, for example, every 8 years for the long term and every month for the short term, and is set according to the purpose of use of the predetermined characteristic value.

  The storage device 7 stores the measurement times of the predetermined characteristic values of the gas meters 2a, 2b,... In step S5, if there is a gas meter that has reached the periodic inspection time, for example, the gas meter 2a, the gas meter 2a On the other hand, a periodic inspection measurement signal for measuring an initial value of a predetermined characteristic and transmitting data is transmitted from the transmission / reception device 5.

  The gas meter 2a that has received the periodic inspection measurement signal measures a predetermined characteristic value and transmits data of the predetermined characteristic value. The data transmitted from the gas meter 2a includes, in addition to the measured predetermined characteristic value, a unique identification code individually assigned to the gas meter, and, if necessary, in advance as in the case of transmitting the initial value measurement location data. The group identification code assigned to each meter is also transmitted simultaneously.

  In step S <b> 6, data from the gas meter 2 a is received by the transmission / reception device 5, and the data is taken into the analysis evaluation system 6 and stored in the storage device 7.

  Next, in step S7, it is determined whether or not a predetermined characteristic value at the time of periodic inspection of the gas meter 2a exceeds a threshold value. If it exceeds the threshold value, it is determined that a secular change has occurred, and step S8 is performed. , Warn that the secular change has occurred in the gas meter 2a.

  In step S7, when the predetermined characteristic value at the time of the periodic inspection does not exceed the threshold value, the secular change tendency of the gas meter 2a itself as a single item is analyzed in step S9.

Based on the analysis result in step S9, it is determined in step S10 whether or not there is an aging tendency. If there is no aging tendency, the process proceeds to step S3 and waits for the next periodic inspection time.

  In step S10, when there is an aging tendency, it is determined in step S11 whether there is an aging tendency of the group unit to which the gas meter 2a belongs.

  In the group unit analysis, the data of the gas meters 2a, 2b,... Of the group to which the gas meter 2a stored in the storage device 7 belongs is referred to. In this case, a group of data based on the identification code assigned to each group or the unique identification code assigned to each meter is used as an analysis target.

  In step S11, when there is no aging change tendency of the group unit, the process proceeds to step S3 and waits for the next periodic inspection time.

  In step S11, if there is an aging trend in units of groups, a warning is given in step S12 that a aging trend has occurred in the group to which the gas meter 2a belongs.

  As described above, the analysis and evaluation system 6 can grasp the secular change tendency of the gas meter characteristic and can grasp the secular change tendency generated from the same population.

  As described above, the secular change evaluation system according to the present invention can evaluate the secular change tendency of the characteristics for each group using the periodic inspection data of a plurality of devices. Therefore, not only the gas meter but also the water meter and the power meter are installed. It can be applied to a wide range of applications, such as the ability to grasp the aging trends of various measuring instruments.

2a Gas meter 2b Gas meter 3a Transmission / reception device 3b Transmission / reception device 5 Transmission / reception device 7 Storage device 8 Analysis evaluation device 9 Secular change evaluation system

Claims (3)

A plurality of gas meters each having a transmitting and receiving device, and an analysis and evaluation system including a transmitting and receiving device that receives data transmitted from the transmitting and receiving device,
The analysis evaluation system includes a storage device for storing the data, and an analysis evaluation device for analyzing and evaluating the data stored in the storage device,
Wherein the data includes identification codes, each of which is assigned to each predetermined group comprising a plurality of the gas meter includes a predetermined characteristic value of the gas meter,
The analysis evaluation system performs aging evaluation of the predetermined group using the initial value of the predetermined characteristic value and the predetermined characteristic value measured at the time of inspection for each group unit based on the identification code. Secular change evaluation system.  The secular change evaluation system according to claim 1, wherein the identification code is assigned as a group for each same production lot. The secular change evaluation system according to claim 1, wherein the identification code is assigned as a group for each region.

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