JP6013385B2 - Electricity meter and watt-hour meter verification system - Google Patents

Description

  The present invention relates to a watt-hour meter suitable for replacement work of a watt-hour meter and a watt-hour meter verification system.

Conventionally, inductive watt-hour meters installed in general homes are replaced in 10 years as the expiration date specified in accordance with the Measurement Law. Since a power failure occurs when the watt-hour meter is replaced, the construction company carries out replacement work on the premise that the expiration date expires on a human system after negotiating with the customer in advance.
Conventional inductive watt hour meters require special equipment for uninterruptible meter replacement, and the replacement work requires time and labor. You may not be able to set up a schedule as your company thinks.
In addition, since construction companies that carry out periodic replacements also perform human replacements, depending on the convenience of the customer and the role of the workers, there is a risk of reliable replacement until the expiration date.
In the future, smart meters, which are expected to spread in place of inductive watt hour meters, have been supplied up to now when measuring units for measuring the amount of electric power and when power supply is stopped or metered units are replaced. It is expected to be composed of an open / close unit that can automatically stop the power.

  In Patent Document 1, as an electronic watt-hour meter, a voltage input from a voltage supply facility to a voltage terminal via a distribution line is converted into a digital voltage signal. Similarly, a current input to a current terminal is It is converted into a digital current signal and held in the power calculator. When a voltage signal and a current signal are received from the power calculation unit, the integrated value is calculated by accumulating the pulses included in the received pulse signal, stored in the memory. In the self-diagnosis process, the power calculation unit compares the operation conditions stored in the storage unit with the setting by the setting device and the diagnostic signals (voltage signal and current signal) that are captured and stored inside A technique for executing a self-diagnosis, determining whether the result of the self-diagnosis is appropriate, and displaying the result is disclosed.

JP 2004-279120 A

However, replacement of the unit installed in the smart meter is based on the premise of human work, and although the power outage negotiation with the construction company with the customer is labor-saving, the replacement operation of the unit The reduction of personnel involved in the measurement is not taken into consideration, so the fundamental improvement of the act of periodic replacement of measuring instruments is not considered.
However, since the measuring unit needs to be replaced, there has been a problem that the periodic replacement of the measuring instrument is very expensive.
On the other hand, in the technique described in Patent Document 1, a diagnosis process is performed on the power calculation unit. Moreover, although the diagnosis result about an electric power calculating part is displayed, since it is not alert | reported to an electric power company, the meter-reader needed to confirm the diagnosis result visually. In addition, in the case of poor results, it was inefficient because it was necessary to request a replacement from the construction company after receiving a report from the meter reader, and to adjust the construction schedule between the customer and the construction company. .
Further, when the expiration date of the smart meter has passed, there has been a problem that labor costs related to the replacement work of the weighing unit are necessarily generated by replacing the weighing unit of the smart meter.
Therefore, even if the expiry date of the smart meter has passed, it is eagerly desired to reduce labor costs related to the replacement work of the weighing unit by continuing to use the weighing unit if the test result is good. .
The present invention has been made in view of the above, and an object thereof is to provide a smart meter capable of displaying a test result of a weighing unit and notifying the power company of the test result.

In order to solve the above-mentioned problem, the invention according to claim 1 is connected between a distribution line from a commercial power source and an indoor wiring from a distribution board provided on the customer side, A watt-hour meter that measures power consumed in a device and transmits the measured value to a power company server disposed in a power company via a network, and is supplied from the commercial power source side to the consumer side A measuring means for measuring a voltage value and a current value, a power calculating means for calculating a power value by multiplying the voltage value and the current value, and integrating a power value supplied from the power calculating means. weigh the amount of power, a metering unit for displaying the weight value in response to a test request signal from the power company server, and a test controller for testing the said metering unit, said test control means, before As a test for the weighing unit, a simulated power value composed of a predetermined voltage value, a predetermined current value, and a predetermined power factor value is sent to the weighing unit, and the measured power value by the weighing unit is detected. An error test is performed in which a difference between an assumed reference power consumption and a measurement value by the measurement unit is calculated, and whether or not the difference value exceeds a predetermined reference value is determined. And controlling the measurement unit to display the verification result on the weighing unit and transmitting the verification result to the power company server.

  According to the present invention, since the test result for the weighing unit is displayed on the weighing unit, the test result can be visually confirmed. In addition, since the verification result is transmitted to the power company server, the power company can also check the verification result.

It is a block diagram which shows the structure of the verification system of the watt-hour meter which concerns on embodiment of this invention. It is a block diagram of the electric power smart meter shown in FIG. It is a flowchart showing the process of the electric power company server shown in FIG. It is a figure which shows a test result list list. It is a figure which shows a replacement list. It is a flowchart showing the process of the electric power smart meter shown in FIG. It is a sequence diagram which shows the content of the data communication between each apparatus with which the test | inspection system of a watt-hour meter is equipped. It is a figure which shows the text of the replacement request message transmitted from construction company PC to customer PC.

<First Embodiment>
Embodiments of the present invention will be described with reference to the drawings.
With reference to the block diagram shown in FIG. 1, the structure of the watt-hour meter verification system 1 according to the embodiment of the present invention will be described.
An electricity meter verification system 1 is connected between a distribution line from a commercial power source (for example, AC 100 V) of an electric power company and a distribution line from a distribution board 5 provided in a customer's house 3. The electric power consumed in an electric device (not shown) provided in the house is measured. The watt-hour meter verification system 1 includes a power smart meter 20 that transmits a measurement result to the power company server 10 disposed in the power company via the Internet N.
In addition, the electric power company is a power that fits one of the following types: general electric utility, wholesale electric utility, independent power generator, small-scale power generator, specific electric utility, or specific electric utility It may be a company.
The consumer's house is provided with a plurality of electrical devices (not shown) via a distribution board, and the power consumption consumed by the plurality of electrical devices is measured by the power smart meter 20 and the measurement result. Is displayed on the display unit 21 as a multi-digit numerical value.
The measurement result measured in the power smart meter 20 is transmitted from the power smart meter 20 to the power company server 10 via the mobile phone base station 6, the mobile phone network 7, and the Internet N. Alternatively, the measurement result measured in the power smart meter 20 is transmitted from the power smart meter 20 to the power company server 10 via the access point 8, the public wireless LAN network 9, and the Internet N.

In the power company server 10, the measurement result received by the communication unit 11 from the power smart meter 20 via the Internet N is stored in the database DB 13 by the control unit 12.
The certification management unit 14 of the power company server 10 stores all of the certification results received from the power smart meter 20 in the database DB 13.
The abnormality monitoring unit 15 identifies “No” data among the pass / fail judgments acquired from the database DB 13 and stores the result flag in the database DB 13 using “OK” / “NG” codes. When the result flag is “OK”, the determination is good, and when it is “NG”, the determination is negative.
The abnormality monitoring unit 15 detects the “No” data, and transmits an e-mail including a replacement request message to the e-mail address of the sales office PC 55.

With reference to the block diagram of the power smart meter 20 shown in FIG. 2, the configuration of each unit will be described.
A power measuring unit 24 connected between the inlet 22 connected to the distribution line (AC100V) of the electric power company and the outlet connected to the distribution board 5 on the customer side is provided.
The power measurement unit 24 includes a voltage detection transformer VT for detecting the voltage of the distribution line connected to the outlet 23, a current detection transformer CT for detecting a current flowing through the distribution line, a voltage detection transformer VT, An A / D converter 24a that inputs a voltage signal and a current signal detected by the current detection transformer CT and converts them into digital values at each sampling period, and voltage data and current converted to digital values by the A / D converter 24a. Data is output to the power calculation unit 25.
The power supply circuit unit 26 includes a switching power supply, and switches AC power supplied from the power company via the inlet 22 by an IC circuit provided in the switching power supply to supply DC power to each unit.

The power company server 10 selects the URL code of the customer-side power smart meter 20 that is the verification destination from the database DB 13 and transmits a verification request signal to the power smart meter 20 indicated by the URL code.
The first communication unit 27 includes a first transmission circuit 27 a and a first reception circuit 27 b connected to the public wireless LAN network 9 via the access point 8, and the first transmission circuit 27 a is a communication input from the control unit 30. Data is transmitted to the public wireless LAN network 9. The first receiving circuit 27 b outputs communication data received from the public wireless LAN network 9 to the control unit 30.
The second communication unit 28 includes a second transmission circuit 28 a and a second reception circuit 28 b connected to the mobile phone base station 6 via a connector 29, and the second transmission circuit 28 a is communication data input from the control unit 30. Is transmitted to the mobile phone network 7. The second receiving circuit 28 b outputs the communication data received from the mobile phone network 7 to the control unit 30.

The control unit 30 includes a CPU, a ROM, a RAM, and a timer. The control unit 30 includes a meter control unit 31, a cooperation control unit 32, a power calculation unit 25, and a verification control unit 33 that are executed by software modules developed on the RAM. doing. The control unit 30 includes a ROM (Read Only Memory), a RAM (Random Access Memory), and a CPU (Central Processing Unit). The control unit 30 reads the operating system OS from the ROM, expands it on the RAM, and starts the OS. . Further, the control unit 30 reads a program (processing module) from the ROM and executes various processes under OS management.
The meter control unit 31 controls the operation of each unit of the power smart meter 20 during normal times.
The cooperation control unit 32 detects an output destination change command, outputs a permission signal to the input / output buffer circuit 30a for outputting power data to the auxiliary weighing unit 41, and further outputs a switching completion signal to the test control unit 33. To do.
The power calculation unit 25 multiplies the voltage data and current data input from the power measurement unit 24 and outputs power data for each sampling period. At normal time, power data output from the power calculation unit 25 is output to the weighing unit 42, and at verification time, power data output from the power calculation unit 25 is input to the auxiliary weighing unit 41 via the input / output buffer circuit 30a. Is output.
The verification control unit 33 controls each unit and each unit provided in the power smart meter 20 during the verification by executing verification application software (hereinafter referred to as a verification application).

The memory unit 43 includes a nonvolatile RAM, and a verification application is installed in the nonvolatile RAM, and the verification application is executed under the management of the verification control unit 33.
The power switching unit 44 stops the power supplied to the electronic circuit built in the weighing unit 42 when the weighing unit 42 is replaced in response to a switch operation by a worker of the construction company.
The auxiliary weighing unit 41 measures the amount of power by integrating (cumulative calculation) the power data output from the power calculation unit 25 when the weighing unit is under verification.
The weighing unit 42 is detachably connected to the main body case of the power smart meter 20, and includes a central control unit 42, a display unit 21 for displaying a measured value, a connector 42b detachably connected to the auxiliary weighing unit 41, and a control. A connector 42c that is detachably connected to the unit 30 is provided. The power data output from the power calculation unit 25 is integrated (cumulative calculation) to measure the amount of power, and the measurement value representing the measurement result is displayed on the display unit 21. To do.
The central control unit 42 has a ROM, a RAM, and a CPU inside. The central control unit 42 reads the operating system OS from the ROM, expands it on the RAM, and starts the OS. Under OS management, programs (processing modules) are read from the ROM. The amount of power is measured by reading and integrating the power value, and the measured value is displayed.

Next, the operation of the power company server 10 will be described with reference to FIG. FIG. 3 is a flowchart showing processing of the power company server 10.
First, in step S5, the control unit 12 provided in the power company server 10 sets the process number #k to 1 as an initialization process.
Next, in step S10, the control unit 10 reads the unique URL code of the process number #k from the database DB 13 via the test management unit 14 and sets it as the test destination.
Table 1 shows the process number #k, URL code, and customer number stored for each record in the database DS.
Here, the URL (Uniform Resource Locator) code indicates the location of information resources (documents, images, etc.) existing on the Internet, and is usually configured in the format of “protocol: // domain name / directory path name / file name”. Is done.

次いで、ステップＳ１５では、制御部１２は、設定した検定先である処理番号＃ｋのＵＲＬコードを通信部１１に設定し、当該ＵＲＬコードを有する電力スマートメータ２０へインターネットＮを介して、電力スマートメータ２０の検定を要求する旨の検定要求信号を送信する。
これに対して、当該ＵＲＬコードを有する電力スマートメータ２０が検定要求信号を受信した場合には、電力スマートメータ２０の検定を実行する旨の検定応答信号をインターネットＮを介して電力会社サーバ１０へ送信する。一方、当該ＵＲＬコードを有する電力スマートメータ２０が存在しない場合は、検定応答信号が送信されない。

Next, in step S15, the control unit 12 sets the URL code of the processing number #k, which is the set verification destination, in the communication unit 11, and connects the power smart meter 20 having the URL code to the power smart meter via the Internet N. A test request signal for requesting the test of the meter 20 is transmitted.
On the other hand, when the power smart meter 20 having the URL code receives the test request signal, a test response signal for executing the test of the power smart meter 20 is sent to the power company server 10 via the Internet N. Send. On the other hand, when the power smart meter 20 having the URL code does not exist, the test response signal is not transmitted.

Next, in step S20, the control unit 12 determines whether or not a test response signal is received from the power smart meter 20 having the URL code. When the verification response signal is received from the power smart meter 20 having the URL code, the process proceeds to step S30. On the other hand, if the verification response signal cannot be received from the power smart meter 20 having the URL code, the process proceeds to step S25.
In step S25, the control unit 12 increments the process number #k by adding 1, sets the value as a new process number #k, and returns to step S10.
On the other hand, in step S30, the control unit 12 determines whether or not a test result signal is received from the power smart meter 20 having the URL code. When the test result signal is received from the power smart meter 20 having the URL code, the process proceeds to step S45. On the other hand, if the verification result signal cannot be received from the power smart meter 20 having the URL code, the process proceeds to step S35.
In step S35, the control unit 12 transmits a retransmission request signal for requesting the result of the test again to the power smart meter 20 having the URL code via the Internet N.

Next, in step S40, the control unit 12 determines whether or not a test result signal is received from the power smart meter 20 having the URL code. When the test result signal is received from the power smart meter 20 having the URL code, the process proceeds to step S43. On the other hand, if the verification result signal cannot be received from the power smart meter 20 having the URL code, the process proceeds to step S25.
Next, in step S43, the control unit 12 determines whether or not a test end signal has been received from the power smart meter 20 having the URL code. When the verification end signal is received from the power smart meter 20 having the URL code, the process proceeds to step S45. On the other hand, if the test end signal has not been received, the process returns to step S435.

Next, in step S45, the control unit 12 outputs the test result signal received from the power smart meter 20 to the test management unit.
Here, the certification management unit searches the database DS (Table 1) using the process number k as a key, extracts the customer No having the process number k, and records the customer No. stored in the database DB. The test result flag is updated for. When the power smart meter 20 is out of order, the verification result flag is NG, and when it is normal, it is OK. As a result, as shown in FIG. 4, the customer number, address, customer name, instrument number, latent test flag, start test flag, measurement test flag, and error test flag are stored in the database for each record as a test result list. Stored in DB13.

Next, in step S50, the control unit 12 sends an abnormality monitoring instruction signal to the abnormality monitoring unit 15 in order to cause the abnormality monitoring unit 15 to perform abnormality monitoring processing for monitoring that at least one test result flag is abnormal. Output.
Here, the abnormality monitoring unit 15 reads four test result flags for each record from the database DB, and generates a replacement list when at least one test result flag is abnormal, and stores it in the database DB 13. . As a result, as shown in FIG. 5, the customer No., address, customer name, instrument No., customer PC 50 or e-mail address of the mobile phone is stored in the database DB 13 for each record as a replacement list.
Next, in step S55, the control unit 12 determines whether or not the current process number #k has reached #k _max . If the current process number #k has reached #k _max , the process proceeds to step S5. On the other hand, if the current process number #k has not reached #k _max , the process proceeds to step S25.

Next, the operation of the power smart meter 20 will be described with reference to FIG. FIG. 6 is a flowchart showing processing of the power smart meter 20.
First, the first communication unit 27 of the power smart meter 20 receives the verification request signal from the power company server 10. The first communication unit 27 transfers the received test request signal to the control unit 30.
In step S105, the control unit 30 determines whether or not a test request signal has been received, and proceeds to step S107 if a test request signal has been received.
Next, in step S107, since the control unit 30 has received the verification request signal, it transmits a verification response signal to the power company server 10.

Next, in step S110, when the control unit 30 receives the test request signal, the control unit 30 passes the control right to the test control unit 33, and starts preparing the test for the weighing unit 42.
In other words, the verification control unit 33 changes the output destination of the power data output from the power calculation unit 25 to the auxiliary weighing unit 41 in order to cause the auxiliary weighing unit 41 to perform actual weighing during the period during the verification. The command is output to the cooperation control unit 32.
Immediately before testing the weighing unit 42, the verification control unit 33 controls the auxiliary weighing unit 41 to send the weighing value measured by the weighing unit 42 to the auxiliary weighing unit 41 and integrate it from the measured value.
The cooperation control unit 32 outputs a permission signal to the input / output buffer circuit 30 a for outputting power data to the auxiliary weighing unit 41, and further outputs a switching completion signal to the test control unit 33.
As a result, the power data output from the power calculation unit 25 is output to the input / output buffer circuit 30a, and the power data from the input / output buffer circuit 30a is input to the auxiliary weighing unit 41.
When the verification control unit 33 receives the switching completion signal from the cooperation control unit 32, the verification process of the weighing unit 42 becomes possible.

The test control unit 33 executes a test application installed in the memory. The test control unit 33 executes all test processes in the order of the latent test process, the start test process, the metric test process, and the error test process as the test process.
In step S115, in the latent test process, it is monitored that the counter of the weighing unit 42 does not operate in an unloaded state, a pass / fail determination is performed, and the determination result is stored in a result table. In the latent motion verification process, a simulated power value constituted by a value of 110% (110 V), which is an upper limit voltage value of the rated voltage (100 V) held in the program of the verification application, according to a command from the verification control unit 33. Is sent to the weighing unit 42, and the test control unit 33 detects whether or not to measure.
Here, the verification control unit 33 sends a simulation signal to the weighing unit 42, and when the measurement is not performed, the determination is negative, and when the measurement is measured, the determination is good.

Next, in step S120, in the start verification process, the verification control unit 33 transmits small power to the weighing unit 42 according to an instruction from the application through the control unit. The weighing unit 42 monitors whether the power data can be metered (counted), makes a pass / fail judgment, and stores the judgment result in a result table provided on the RAM.
In the starting verification process, in accordance with a command from the verification control unit 33, a current value representing a value of 1/375, which is a lower limit current value of the rated current, and a rated voltage (100V) held in the program by the verification application. The test control unit 33 detects whether or not the weighing unit 42 measures the power data, which is a simulated power value obtained by multiplication, to the weighing unit 42. By executing this start verification process, it is confirmed that the power smart meter 20 measures even if a small amount of power is consumed.

Here, the verification control unit 33 sends the power data to the weighing unit 42 and makes a good judgment when it is weighed, and makes a bad judgment when it is not weighed.
Next, in step S125, in the metric test process, the test control unit 33 detects whether the central control unit in the measurement unit 42 outputs the metric data in conjunction with the start-up test process. By executing this measurement test process, it is confirmed whether the display mechanism in the measurement unit 42 operates correctly.
Here, the verification control unit 33 makes a good determination when the central control unit 42a in the weighing unit 42 outputs the weighing data, and makes a negative determination when it does not output the weighing data.

Next, in step S130, in the error verification process, in response to an instruction from the verification application through the control unit 30, the power data is output from the verification control unit 33 to the weighing unit 42, and the reference data (current value and time stored in the verification application) is stored. Measure the measurement error.
In the error test process, the test control unit 33 sends a simulation signal to the weighing unit 42 according to a command from the test control unit 33, and the test control unit 33 detects the measured value. The test application uses reference power consumption data (for example, voltage (100V) × current (1A) ×) that is a simulated power value composed of a predetermined voltage value, a predetermined current value, a predetermined power factor value, and a predetermined time as data in the program. Power factor (80%) × integrated time (10 seconds)) is held, and the difference between the reference power consumption data and the measurement value detected by the measurement unit 42 is calculated, and the difference value exceeds a predetermined reference value. Is determined by determining whether or not, and the determination result is stored in the result table.
Here, the test control unit 33 makes a good determination if the difference value does not exceed the predetermined reference value, and determines a negative determination if the difference value exceeds the predetermined reference value.

By executing this error test process, it is confirmed whether or not the error is within the range of the test tolerance.
As described above, by executing the verification application, the verification of the weighing unit 42 of the power smart meter 20 can be performed with the weighing unit 42 attached, and a result table as shown in Table 2 is generated. .
Table 2 shows the result flags of the latent test process, the start test process, the metric test process, and the error test process stored in the result table. In Table 2, the good judgment is “OK” and the negative judgment is “NG”.

Next, in step S135, the test control unit 33 reads the test result data from the result table stored in the RAM and outputs the test result data to the first communication unit 27, so that the first communication unit 27 transmits the test result data to the Internet N Is transmitted to the electric power company server 10.
Next, in step S140, the test control unit 33 reads the test result data from the result table stored in the RAM, and when all the test result data is OK, a test for displaying a “test good” mark. A good signal is output to the weighing unit 42. The weighing unit 42 that has received the verification good signal digitally displays a “valid verification” mark on the display unit 21b, as shown in FIG.
On the other hand, when at least one test result data is NG, a test reject signal for displaying a “test reject” mark is output to the weighing unit 42. The weighing unit 42 that has received the test reject signal digitally displays the “test reject” mark on the display unit 21b.
Next, in step S145, the verification control unit 33 determines whether or not a retransmission request signal regarding the verification result has been received via the first communication unit 27. When the retransmission request signal is received, the process returns to step S135, and the test result data is transmitted to the power company server 10 via the first communication unit 27. On the other hand, if the retransmission request signal has not been received, the process proceeds to step S150.

After the verification of the weighing unit 42 is finished, in step S150, the verification control unit 33 issues an output destination change command for changing the output destination of the power data output from the power calculation unit 25 to the weighing unit 42. To 32.
The cooperation control unit 32 detects an output destination change command, outputs a permission signal to the input / output buffer circuit 30b for outputting power data to the weighing unit 42, and further outputs a switching completion signal to the test control unit 33. .
As a result, when the verification for the weighing unit 42 is completed, the verification control unit 33 sends the measurement value measured by the auxiliary measurement unit 41 to the measurement unit 42 and causes the measurement unit 42 to integrate from the measurement value. To control.
As a result, the power data output from the power calculator 25 is input to the weighing unit 42 via the input / output buffer circuit 30b.
When the verification control unit 33 receives the switching completion signal from the cooperation control unit 32, the weighing unit 42 returns to the normal operation state.
Next, in step S155, the verification control unit 33 transmits a verification end signal to the power company server 10 via the first communication unit 27.
As a result, the verification application is distributed from the power company server to the smart meter, and the determination unit (latency test, start-up verification, measurement verification, error verification) is performed by the verification application. By sending the pass / fail result to the pass / fail result, it is possible to check the pass / fail of the weighing unit provided in the smart meter located at a remote location based on the pass / fail result, contributing to the efficiency of the replacement work of the weighing unit. be able to.

Next, referring to FIG. 7, data communication in the watt-hour meter verification system will be described. FIG. 7 is a sequence diagram showing the contents of data communication between the devices provided in the watt-hour meter verification system.
First, in sequence Se5, the power company server 10 distributes the verification application software from the communication unit 11 to the power smart meter 20 on the customer side via the Internet N.
In sequence Se10, the electric power company server 10 transmits a verification request signal for periodically performing verification of the measuring instrument to the power smart meter 20 on the consumer side.
Next, in sequence Se15, the power smart meter 20 has received the verification request signal, and therefore transmits a verification response signal to the power company server 10.
The verification application installed in the power smart meter 20 activates the verification application program in response to a verification request signal from the power company server 10 to perform verification processing.

Next, in sequence Se <b> 20, the martometer transmits to the electric power company server 10 the test result data (pass / fail judgment) by the program of the test application.
The power company server 10 registers the test result (good / bad determination) from the power smart meter 20 in the database DB.
Next, in sequence Se <b> 25, the mart meter transmits a test end signal to the power company server 10 because the test by the program of the test application is completed.
Here, when the verification result is “good”, the power company server 10 does not transmit a verification execution instruction to the customer side until the next verification time.

On the other hand, when the verification result is “No”, the power company server 10 proceeds to the following procedure.
Next, in sequence Se26, the electric power company server 10 transmits the replacement list of the verification result “No” read from the database DB13 to the mail address of the sales office PC55.
Next, in sequence Se30, the electric power company server 10 transmits a replacement request message indicating a replacement request for the weighing unit 42 to the mail address of the construction company PC 60 together with the replacement list.
Next, in sequence Se35, the construction company PC 60, based on the replacement request message from the power company server 10, visits the visit permission request message indicating that a visit is made to replace the weighing unit 42 addressed to the mail address of the customer PC 50. 65 (no power outage, request permission to enter and exit the site) (see FIG. 8) is sent by e-mail.
The contents of the e-mail shown in FIG. 8 indicate the e-mail in the HTML format, and the font color, character size, background color, etc. can be changed. And “Necessity: Call” button 69 is provided at the bottom of the document. When this e-mail is received and opened by the mailer software on the customer PC 50, when the “acknowledge button” 67 is clicked, an e-mail with a message indicating the approval is automatically constructed. It is transmitted to the company PC 60. When the “Necessity: Call” button 69 is clicked, an e-mail containing a message indicating that the construction company requests a telephone call from the customer is automatically sent to the construction company PC 60. The

Next, in the sequence Se40, the customer PC replies (visit permission message) to the electronic mail received from the construction company PC, thereby confirming the replacement date and time.
The construction company PC60 refers to the construction date and time described in the reply mail received from the customer PC50, and the construction company performs replacement work of the weighing unit 42.
Next, in sequence Se45, the construction company transmits an e-mail with a completion report message to the e-mail address of the sales office PC after the replacement of the weighing unit on the customer side is completed.
Next, in the sequence Se50, the sales office PC55 registers in the replacement list the fact that the weighing unit replacement work for the customer has been completed, based on the completion report message from the construction company PC60. The sales office PC 55 transmits a completion report list to the mail address of the power company server 10.

In the power company, the detailed data (what test is bad) about the test result “no” of each power smart meter 20 accumulated in the database DB 13 of the power company server 10 is classified into the content of which test. It can be confirmed whether there are many defects. As a result, the power smart meter 20 can be used for failure trend analysis.
Further, the power usage amount in each power smart meter 20 and the causal relationship when the measuring unit 42 becomes defective may be stored in the database DB (the failure rate increases when the usage amount increases).
Furthermore, the endurance time that can be expressed in the period from when the weighing unit 42 is attached to when a defect occurs may be calculated.
Further, as shown in FIG. 4, an address database of a place where the power smart meter 20 is arranged is stored in the test result list. For this reason, by calculating the defect rate for each area such as the city name and town name indicated in the address data and mapping it on the map, it is possible to compare the defect rate for each city name and town name on the map. Thereby, the point that moisture, temperature, and salt damage state differ for every area can be analyzed according to area.
As a result, the product quality of the weighing unit 42 can be improved by accumulating and utilizing the analysis data in the database DB13.

In addition, since it is possible to drastically reduce the number of roles required for regular replacement work of the power smart meter 20 and power failure notification, the cost (replacement cost) associated with the replacement of the weighing unit 42 can be significantly reduced. Can do.
Furthermore, since it is limited to the replacement of only the weighing unit 42 in which the power smart meter 20 has become defective, it is possible to drastically reduce the number of personnel required for periodic replacement work and power outage notification, so that the business Can be made more efficient.
Conventionally, an indoor power failure was performed when replacing the watt hour meter, but according to this embodiment, the burden on the consumer can be reduced by eliminating the need for the indoor power failure, and the satisfaction of the customer Can be improved.

<Examples of Embodiments and Effects of the Present Invention>
<First aspect>
The electric power smart meter 20 of this aspect is connected between a distribution line from a commercial power source and an indoor wiring from a distribution board 5 provided on the customer side, and uses the electric power consumed in the electric device on the customer side. A power smart meter that measures and transmits a measured value to the power company server 10 disposed in the power company via the network N, and measures a voltage value and a current value supplied from the commercial power supply side to the consumer side The power measurement unit 24, the power calculation unit 25 that calculates the power value by multiplying the voltage value and the current value, and the power value supplied from the power calculation unit 25 is integrated to measure the amount of power, The weighing unit 42 for displaying the measured value, and a test control unit 33 for testing the weighing unit 42 in response to a test request signal from the electric power company server 10. The assay results with displays on the metering unit 42 for Tsu bets 42, and controls to transmit the test result to the power company server 10.
According to this aspect, since the test result for the weighing unit 42 is displayed on the weighing unit 42, the test result can be visually confirmed. Further, since the verification result is transmitted to the power company server 10, the power company can also check the verification result.

<Second aspect>
The power smart meter 20 of this aspect includes an auxiliary weighing unit 41 that integrates the power value supplied from the power calculation unit 25, and the verification control unit 33 receives the verification request signal from the power company server 10, Control is performed so that the power value output from the calculation unit 25 is sent to the auxiliary weighing unit 41 and accumulated in the auxiliary weighing unit 41.
According to this aspect, even when the measuring unit 42 is being verified, it is possible to measure the power that is actually consumed by the electrical equipment on the consumer side.

<Third aspect>
Immediately before testing the weighing unit 41, the test control unit 33 according to this embodiment controls the auxiliary weighing unit 41 to send the weighing value weighed by the weighing unit 41 and cause the auxiliary weighing unit 41 to accumulate from the measured value. .
According to this aspect, it is possible to measure with the auxiliary weighing unit 41 from the electric power actually consumed by the consumer-side electrical equipment until just before the weighing unit 42 is verified.
<4th aspect>
When the verification for the weighing unit 42 is completed, the verification control unit 33 according to this aspect causes the weighing value weighed by the auxiliary weighing unit 41 to be sent to the weighing unit 42 so that the weighing unit 42 accumulates the measured value. To control.
According to this aspect, when the verification with respect to the weighing unit 42 is completed, the weighing value weighed by the auxiliary weighing unit 41 is sent to the weighing unit 42, and the weighing unit 42 is controlled to be integrated from the weighing value. Therefore, after the test is completed, the weighing unit 42 can be integrated from the measured value.

<5th aspect>
The verification control unit 33 according to the present embodiment sends a simulated power value composed of the upper limit voltage value of the rated voltage of the commercial power supply to the weighing unit 42 as a test for the weighing unit 42, so that the weighing unit 42 has the simulated power value. By sending to the weighing unit 42 a simulated power value obtained by multiplying the lower limit current value of the rated current supplied from the commercial power source and the rated voltage. It is detected whether the unit 42 outputs a measured value based on the simulated power value, which is a measurement result, in conjunction with the start verification for detecting whether or not the unit 42 measures the simulated power value. A metric test or a simulated power value composed of a predetermined voltage value, a predetermined current value, and a predetermined power factor value is sent to the measuring unit 42, and the measured value by the measuring unit 42 is detected. Thus, the pass / fail judgment is performed by calculating the difference between the reference power consumption that can be assumed by the simulated power value and the measured value by the weighing unit 42, and determining whether the difference value exceeds a predetermined reference value. Control to perform at least one of error tests.
According to this aspect, control is performed so that at least one of the latent motion test, the start test, the metric test, and the error test is executed as the test process, so that the test process for the weighing unit 42 can be performed.

<Sixth aspect>
The verification system 1 according to this aspect includes a power smart meter 20 and a power company server 10, and the power company server 10 stores a verification result received from the power smart meter 20 and a verification result acquired from the database 13. If at least one test result is NO, the measuring unit 42 provided in the power smart meter 20 is determined to be defective, and includes the contact information of the customer where the watt-hour meter is arranged. An abnormality monitoring unit 15 that generates a list, and a communication unit 11 that transmits an e-mail to which a message indicating a replacement instruction of the power smart meter 20 is added to the list to a mail address of a construction company.
According to this aspect, when at least one test result among the test results received from the power smart meter 20 is negative, it is determined that the weighing unit 42 provided in the power smart meter 20 is defective, Since a list including the contact information of the customer where the power smart meter 20 is arranged is generated, and an e-mail with a message indicating a replacement instruction for the power smart meter 20 added to the list is sent to the mail address of the construction company. When the measuring unit 42 provided in the power smart meter 20 is defective, a message indicating a replacement instruction for the power smart meter 20 can be notified to the construction company.
<Seventh aspect>
The verification system 1 of this aspect is arranged at a construction company and a construction company PC 60 that communicates electronic mail with the power company server 20; a consumer PC 50 that is arranged at the consumer side and communicates electronic mail with the construction company PC; The construction company PC 60 sends the power smart meter 20 to the mail address of the customer PC 50 based on the list added to the email received from the power company server 10 and the message indicating the replacement instruction of the power smart meter 20. Send a message indicating the replacement work for.
According to this aspect, the construction company PC 60 transmits a message indicating the replacement work of the power smart meter 20 to the mail address of the customer PC 50 based on the message indicating the replacement instruction of the power smart meter 20. A message indicating the replacement work of the power smart meter 20 can be notified to the mail address of the customer PC 50.

  DESCRIPTION OF SYMBOLS 1 ... Test | inspection system, 3 ... House, 5 ... Distribution board, 6 ... Mobile telephone base station, 7 ... Mobile telephone network, 8 ... Access point, 9 ... Public wireless LAN network, 10 ... Electric power company server, 11 ... Communication part , 12 ... Control unit, 13 ... Database DB, 14 ... Test management unit, 15 ... Abnormality monitoring unit, 20 ... Electric power smart meter, 21 ... Display unit, 22 ... Inlet, 24 ... Power measurement unit, 23 ... Outlet, 25 ... Power calculation unit, 26 ... power supply circuit unit, 27 ... first communication unit, 30 ... control unit, 28 ... second communication unit, 29 ... connector, 31 ... meter control unit, 32 ... cooperation control unit, 33 ... verification control unit , 41 ... auxiliary weighing unit, 42 ... weighing unit, 43 ... memory unit 44 ... power supply switching unit, 42 ... central control unit, 50 ... consumer PC, 55 ... sales office PC, 60 ... construction company PC, 65 ... visit permission Request me Sage, 69 ... button

Claims (7)

It is connected between the distribution line from the commercial power source and the indoor wiring from the distribution board provided on the customer side, and measures the power consumed in the electric device on the customer side and also sends the measured value to the network A watt-hour meter that transmits to a power company server located in the power company via
Measuring means for measuring a voltage value and a current value supplied from the commercial power supply side to the consumer side;
Power calculating means for calculating a power value by multiplying the voltage value and the current value;
A weighing unit that measures the amount of power by integrating the power value supplied from the power calculating means, and displays the measured value;
In response to a verification request signal from the electric power company server, verification control means for verifying the weighing unit,
The verification control means sends a simulated power value composed of a predetermined voltage value, a predetermined current value, and a predetermined power factor value to the measuring unit as a verification for the measuring unit, and detects the measured value by the measuring unit. The pass / fail judgment is performed by calculating the difference between the reference power consumption that can be assumed by the simulated power value and the measured value by the weighing unit, and determining whether the difference value exceeds a predetermined reference value. An watt-hour meter that is controlled to execute an error test , displays a test result for the weighing unit on the weighing unit, and transmits the test result to the power company server. An auxiliary weighing unit for integrating the power value supplied from the power calculation means,
When the verification request signal is received from the electric power company server, the verification control unit controls the power value output from the power calculation unit to be sent to the auxiliary weighing unit and integrated in the auxiliary weighing unit. The watt-hour meter according to claim 1.   The verification control means controls to send the measurement value weighed by the measurement unit to the auxiliary measurement unit and to allow the auxiliary measurement unit to integrate from the measurement value immediately before verifying the measurement unit. The watt-hour meter according to claim 2.   The verification control unit controls the measurement unit to send the measurement value measured by the auxiliary measurement unit to the measurement unit and to integrate the measurement unit based on the measurement value when the measurement unit completes the verification. The watt-hour meter according to claim 3. The test control means includes
As a test for the weighing unit,
A latency test for detecting whether or not the weighing unit measures the simulated power value by sending a simulated power value constituted by the upper limit voltage value of the rated voltage of the commercial power supply to the weighing unit,
Alternatively, whether or not the weighing unit measures the simulated power value by sending a simulated power value obtained by multiplying the lower limit current value of the rated current supplied from the commercial power source and the rated voltage to the weighing unit. Starting verification to detect
Alternatively, in conjunction with the start-up test, a measurement test for detecting whether the weighing unit outputs a measured value based on the simulated power value that is a measurement result,
Or the error test, the power meter of claim 1, wherein the controller controls to perform at least one of. A watt-hour meter verification system comprising the watt-hour meter according to any one of claims 1 to 5 and the power company server,
The power company server is
Storage means for storing the test result received from the watt-hour meter;
When at least one test result of the test results acquired from the storage means is NO, it is determined that the metering unit provided in the watt hour meter is defective, and the watt hour meter is disposed. A list generation means for generating a list including contact information of a customer
A watt-hour meter verification system, comprising: a transmission unit configured to send an e-mail in which a message indicating a replacement instruction for the watt-hour meter is added to the list to a mail address of a construction company. A construction company terminal that is located in the construction company and communicates an email with the power company server;
A customer terminal that is arranged on the customer side and communicates an e-mail with the construction company terminal; and
The construction company terminal, based on the list added to the e-mail received from the power company server and a message indicating the replacement instruction of the watt-hour meter, The watt-hour meter verification system according to claim 6, wherein a message indicating replacement work is transmitted.

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