JP2008269202A - Measurement data transmitter, meter reading system and simulation method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measurement data transmitter, a meter reading system and a simulation method, for accurately acquiring the measurement data of a meter. <P>SOLUTION: This measurement data transmitter using a personal computer 21 to which peripheral equipment can be connected through a universal serial bus is provided with: a meter 10 for transmitting measurement data acquired by measuring electric energy; and a USB reader 22 connected through the universal serial bus to the personal computer 21 for reading the measurement data from the meter 10, and for transmitting the measurement data to the personal computer 21. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a weighing data transmission device that reads measurement data from a measuring instrument that measures the amount of power, and a meter reading system and a simulation method using the transmission device.

  When the meter is, for example, a watt hour meter, the watt hour meter integrates and displays the amount of power used by the customer. When the predetermined meter reading date is reached, the meter reader of the electric power company visits the customer's house and reads the display value displayed on the electricity meter. Then, the electric power company calculates the amount of power used by the customer from the display value displayed by the watt-hour meter and the previous display value. Reading work by the meter reader needs to be performed regularly for each customer.

  There is a meter reading system that saves labor by reducing the reading work by such a meter reader (see, for example, Patent Document 1). According to this system, a customer visually reads a display value of a measuring instrument, operates an information processing apparatus connected to the Internet, and transmits the read display value to an electric power company.

Further, if this meter reading system is used, the customer reads the display value displayed on the measuring instrument and transmits it to the power company before the next meter reading date, for example, 10 days after the previous meter reading date. Based on the display value after 10 days, it is possible to simulate the amount of electricity used and the electricity bill for this month.
JP 2003-240597 A

  By the way, the meter reading system described above has the following problems. According to this system, a customer visually reads a display value displayed by a measuring instrument installed at home, but at this time, there is a possibility that a misreading of the display value occurs. In this case, the amount of electricity and electricity charges used in the previous month are calculated incorrectly. In addition, if a simulation is performed using a value that is misread, the result of the simulation also becomes an incorrect value.

  An object of the present invention is to provide a measurement data transmission device, a meter reading system, and a simulation method that can solve the above-described problems and can accurately obtain measurement data of a measuring instrument.

  In order to solve the above-mentioned problems, the invention of claim 1 is a weighing data transmission device using a computer capable of connecting peripheral devices by a universal serial bus, and obtained by weighing power etc. A weighing data transmission device, comprising: a weighing instrument capable of transmitting data; and a reader connected to the computer via a universal serial bus and reading weighing data from the weighing instrument and sending the weighing data to the computer. .

  According to the first aspect of the present invention, a reader is connected to the computer, and thereafter, the computer is operated, and the weighing data is taken into the computer from the measuring instrument via the reader.

  According to a second aspect of the present invention, in the weighing data transmission device according to the first aspect, the reader transmits identification information for identifying the measuring instrument when reading the measuring data from the measuring instrument. The weighing device stores the identification information of the weighing device in advance, and when receiving the identification information from the reader, transmits the weighing data when the identification information stored in advance matches the received identification information. Features.

  According to a third aspect of the present invention, there is provided the weighing data transmission apparatus according to the second aspect, wherein the reader is supplied with the identification information of the measuring instrument that is input at the time of initial setting for inputting the identification information of the user for the reader. Is stored.

  According to a fourth aspect of the present invention, in the weighing data transmission device according to any one of the first to third aspects, the measuring device stores an integrated value of the weighing data obtained by weighing every predetermined period, The reader reads each integrated value stored in the measuring instrument.

  According to a fifth aspect of the present invention, in the weighing data transmission device according to any one of the first to third aspects, the measuring instrument calculates an integrated value of the weighing data obtained by weighing at predetermined intervals during a predetermined period. It memorize | stores, respectively, The said reader reads each integrated value which the said measuring device has memorize | stored, It is characterized by the above-mentioned.

  Invention of Claim 6 is a meter-reading system using the measurement data transmission apparatus of Claim 4, Comprising: The integrated value for every said predetermined period is received from the said computer, This integrated value and the integrated value received last time And a server computer for calculating the integrated value of the previous predetermined period.

  In the invention of claim 6, when the computer receives the integrated value read by the reader and thereafter receives the integrated value from the computer, the server computer receives the integrated value from the integrated value received this time and the previous integrated value for the previous predetermined period. The integrated value of is calculated.

  The invention of claim 7 is a simulation method using the weighing data transmission apparatus according to claim 5, wherein each integrated value stored in the measuring instrument from the computer to the middle of the predetermined period is stored. The simulation method is characterized in that the integrated value of the measurement data from the beginning to the end of the predetermined period is simulated using the integrated value.

  According to the first aspect of the present invention, since the computer takes in the weighing data of the weighing device via the reader, it is not necessary to read the weighing data by visual observation, and accurate weighing data can be obtained. Further, since it is not necessary to read the weighing data by visual observation, the work for obtaining the weighing data can be simplified.

  According to the invention of claim 2, since the weighing instrument transmits the weighing data to the reader when the identification information received from the reader matches the identification information stored in advance, the weighing from another weighing instrument. Data can be prevented from being received by mistake.

  According to the invention of claim 3, since the reader stores the identification information of the measuring instrument at the time of initial setting for the reader, it is possible to save labor for the user to input the identification information of the measuring instrument.

  According to the inventions of claims 4 and 5, since the reader reads the integrated value for every predetermined period of the weighing data or the integrated value for every predetermined interval in the predetermined period, the scope of application of the present invention is expanded to a watt hour meter or the like. Make it possible.

  According to the invention of claim 6, since the integrated value of the previous predetermined period is calculated based on the integrated value for each predetermined period, for example, when the meter is a watt hour meter, the meter reading is automatically performed. enable.

  According to the invention of claim 7, since the integrated value of the measurement data from the beginning to the end of the predetermined period is simulated using each integrated value from the beginning to the middle of the predetermined period. In the case of a watt-hour meter, by reading each power amount from the watt-hour meter on the way from the meter reading date to the next meter reading date, the customer can know the amount of electricity used and the electricity bill for the current month. .

  Next, embodiments of the present invention will be described in detail with reference to the drawings. In the following embodiments, the case where the measuring device is the amount of electric power and the amount of electric power is read as the weighing data is taken as an example.

(Embodiment 1)
A meter reading system according to this embodiment is shown in FIG. This meter-reading system includes a watt-hour meter 10 and a reading device 20 at a customer's house, and a server computer 30 of an electric power company. The reading device 20 can be connected to a communication network NT that enables data communication, and the server computer 30 is connected to the communication network NT. In this embodiment, the watt-hour meter 10 and the reading device 20 form a weighing data transmission device.

  The electricity meter 10 is connected to a lead-in line 101 that supplies power to the customer's home. When the customer uses electric power, the watt-hour meter 10 detects and integrates the used electric power. The external appearance of the watt-hour meter 10 is shown in FIG. The watt-hour meter 10 of FIG. 2 includes a storage box 10A, and a terminal box 10B at the lower end thereof. A circuit portion of the watt hour meter 10 is attached to the storage box 10A. As shown in FIG. 3, the circuit portion includes a voltage input unit 11, a current input unit 12, a conversion unit 13, a processing unit 14, a storage unit 15, a display unit 16, and a communication unit 17.

  The voltage input unit 11 receives the detection voltage of the transformer 102 provided in the lead-in line 101, and the current input unit 12 receives the detection current of the current transformer 103 provided in the lead-in line 101. The connection between the transformer 102 and the voltage input unit 11 and the connection between the current transformer 103 and the current input unit 12 are performed via a terminal block (not shown) provided in the terminal box 10B. The conversion unit 13 generates a pulse signal proportional to the power used from the detection voltage of the voltage input unit 11 and the detection current of the current input unit 12 and sends the pulse signal to the processing unit 14. The storage unit 15 stores in advance a meter number that is identification information of the watt-hour meter 10. Moreover, the memory | storage part 15 has memorize | stored beforehand the meter-reading date which meter-reads the electric energy which is an integrated value of electric power. The display unit 16 includes a display panel 16A (FIG. 2) such as a liquid crystal display, and displays the amount of power on the display panel 16A under the control of the processing unit 14. The communication unit 17 performs communication using infrared rays under the control of the processing unit 14. The communication unit 17 includes an infrared unit 17A (FIG. 1) having both a transmitting element that outputs infrared rays and a light receiving element that receives infrared rays. Accordingly, the communication unit 17 performs bidirectional data communication with the reading device 20.

  The processing unit 14 is an arithmetic circuit such as a CPU (Central Processing Unit). The processing unit 14 has a calendar function for checking the date and a timer function for checking the time. When receiving the pulse signal from the conversion unit 13, the processing unit 14 counts the pulses of the pulse signal. In other words, the processing unit 14 calculates the amount of power by integrating the power used by the customer by counting pulses proportional to the power used by the customer. The processing unit 14 controls the display unit 16 to display the calculated power amount on the display panel 16A. Further, the processing unit 14 stores the number of pulses per predetermined time, that is, the amount of electric power per predetermined time in the storage unit 15 every day using a calendar function.

  The processing unit 14 checks the meter reading date using the meter reading date and the calendar function of the storage unit 15 and, when the meter reading date reaches a predetermined time, reads the amount of power displayed on the display unit 16 as meter reading data, and uses the timer function and the calendar. The meter reading data is accumulated in the storage unit 15 together with the meter reading date including the meter reading time examined from the function.

  When the processing unit 14 receives the simulation data transmission request and the instrument number from the reading device 20 via the communication unit 17, the processing unit 14 compares the instrument number stored in the storage unit 15 with the received instrument number. If the two match, the processing unit 14 reads the amount of power for each day from the meter reading day of the current month to the previous day, and reads the amount of power used every predetermined time from the storage unit 15 and controls the communication unit 17. The read power amounts are transmitted to the reading device 20 as simulation data. When the transmission of the simulation data is completed, the processing unit 14 controls the communication unit 17 to transmit a completion message indicating the completion of transmission to the reading device 20.

  When the two instrument numbers do not match, the processing unit 14 controls the communication unit 17 to transmit an error message indicating that the simulation data cannot be transmitted to the reading device 20.

  When the processing unit 14 receives the meter reading data transmission request and the instrument number from the reading device 20 via the communication unit 17, the processing unit 14 compares the instrument number stored in the storage unit 15 with the received instrument number. If the two match, the processing unit 14 adds the meter reading date and the meter reading time to the untransmitted meter reading data stored in the storage unit 15 and controls the communication unit 17 to read the meter reading data to the reading device 20. Send. When the transmission of meter reading data is completed, the processing unit 14 controls the communication unit 17 to transmit a completion message indicating the completion of transmission to the reading device 20.

  When the two instrument numbers do not match, the processing unit 14 controls the communication unit 17 to transmit an error message indicating that meter reading data cannot be transmitted to the reading device 20.

  As illustrated in FIG. 4, the reading device 20 includes a personal computer 21 that is a main body of the reading device 20 and a USB reader 22 that is a reading unit of the reading device 20.

The USB reader 22 is a device that reads the amount of electric power from the watt hour meter 10 during automatic metering and simulation of electricity bills. The USB (Universal Serial Bus) that enables peripheral devices to be connected is personal. Connection to the computer 21 is possible. The external appearance of the USB reader 22 is shown in FIG. The USB reader 22 in FIG. 5 includes a storage case 22A. A circuit portion is attached to the storage case 22A. The circuit portion, as shown in FIG. 6, the communication unit 22 _1, the operation unit 22 _2, the storage unit 22 _3, processing unit 22 _4, the display unit ₂₂ 5, USB interface ₂₂ 6, USB plug 22 ₇ and the power supply unit 22 ₈ is provided.

The communication unit 22 _1, the infrared control processing unit 22 ₄ performs communication unit 17 and the data communication of the power meter 10. The communication unit 22 ₁ is provided with a transmission device that outputs an infrared, infrared unit 22 1A with both the light receiving element for receiving infrared rays _(FIG. 5). Thus, the communication unit 22 ₁ performs communication of power meter 10 bidirectionally. Operation unit 22 ₂ is provided with a setting button _{22 2A} (Fig. 5). The setting button _222A is operated at the time of initial setting or the like. In other words, setting button 22 _2A is operated to store the meter number or the customer's account number of the power meter 10 in the storage unit 22 _3. In this embodiment, the instrument number is used as identification information of the watt-hour meter 10. Display unit 22 ₅ is provided with a display panel _{22 5A} (FIG. 5) such as a liquid crystal display, and displays various messages on the display panel _{22 5A} by the control processing unit 22 _4.

USB plug 22 ₇ is connected to a later-described USB connector 21K of the personal computer 21. USB interface 22 _6, the connection of the USB plug 22 ₇ and the personal computer 21, for transferring the personal computer 21 and the data in the control of the processing unit 22 _4. Power unit 22 ₈ is provided with a power switch _{22 8A} (FIG. 5). By turning on the power switch _{22 8A} when the USB plug 22 ₇ is connected to the personal computer 21, the power supply unit 22 _8, the DC power received from the personal computer 21 via the USB plug 22 _7, the communication unit ₂₂ 1, The operation unit 22 ₂ , the processing unit 22 _{4 to the} USB interface 22 ₆ are supplied. In FIG. 6, the power supply line is omitted.

Storage unit 22 _3, even without power supply from the power source portion 22 ₈ is a memory that can maintain the settings stored. Storage unit 22 ₃ is used to store the meter number and the customer number.

Processor 22 ₄ performs processing for reading the amount of power from the power meter 10. When the USB plug 22 ₇ for initial setting is connected to a computer (not shown) of power companies, the processing unit 22 _4, after the operation of the setting button 22 _2A of the operation unit 22 _2, the power from the computer Upon receiving the quantity meter 10 meter number and customer number, it stores the meter number and the customer number in the memory unit 22 _3.

USB reader 22 is passed to the customer, when the storage unit 22 ₃ is a state of storing meter number and customer number, the transmission request of the simulation data from the personal computer 21 via the USB plug 22 ₇ and the USB interface 22 ₆ If there is, the processing unit 22 ₄ reads the meter number from the storage unit 22 _3, and transmits the meter number by controlling the communication unit 22 ₁ is read and the transmission request of the simulation data to the power meter 10. Thereafter, processing unit 22 ₄ receives the simulation data of the electricity meter 10 from the communication unit 22 ₁ controls the display unit 22 ₅ displays a message "communicating". At the same time, the processing unit 22 _4, the customer number read from the storage unit 22 ₃ is added to the simulation data, and controls the USB interface 22 ₆ sends the simulation data from the USB plug 22 ₇ to the personal computer 21. Processor 22 ₄ and via the communication unit 22 ₁ receives the completion message from the power meter 10, and controls the display unit 22 ₅ displays a message "transmission completion". In addition, the processing unit 22 _4, when receiving the error message from the power meter 10, and controls the display unit 22 ₅ displays the message "unable to communicate".

Further, when there is a transmission request for meter reading data from the personal computer 21 via the USB plug 22 ₇ and the USB interface 22 _6, processing unit 22 ₄ reads the meter number from the storage unit 22 _3, and controls the communication unit 22 ₁ The meter reading data transmission request and the read meter number are transmitted to the watt-hour meter 10. Thereafter, processing unit 22 ₄ and via the communication unit 22 ₁ receives the meter reading data from the power meter 10, and controls the display unit 22 ₅ displays a message "communicating". At the same time, the processing unit 22 _4, the customer number read from the storage unit 22 ₃ is added to the meter reading data, and controls the USB interface 22 ₆ and sends the meter reading data from the USB plug 22 ₇ to the personal computer 21. Processor 22 ₄ and via the communication unit 22 ₁ receives the completion message from the power meter 10, and controls the display unit 22 ₅ displays a message "transmission completion". In addition, the processing unit 22 _4, when receiving the error message from the power meter 10, and controls the display unit 22 ₅ displays the message "unable to communicate".

  The personal computer 21 can be connected to the server computer 30 of the electric power company via the communication network NT. Further, the personal computer 21 performs a process of reading the electric energy from the watt-hour meter 10 by a customer operation. As shown in FIG. 7, the personal computer 21 includes a processing unit 21A, a storage unit 21B, an input unit 21C, interfaces 21D and 21G, a display control unit 21E, a display unit 21F, a communication unit 21H, a USB interface 21J, a USB connector 21K, A power supply unit 21L and a bus 21M are provided.

The input unit 21C of the personal computer 21 is connected to the bus 21M through an interface 21D. The input unit 21C is an input device such as a keyboard or a mouse. The display unit 21F includes a display panel 21F ₁ (FIG. 4) such as a liquid crystal display, and displays various data and the like on the display panel 21F _{1 under} the control of the display control unit 21E. The communication unit 21H is connected to the bus 21M by an interface 21G. The communication unit 21H performs data communication with the server computer 30 of the power company via the communication network NT under the control of the processing unit 21A. The power supply unit 21L generates and supplies various DC power supplies necessary for each circuit portion of the personal computer 21, and stops the power supply under the control of the processing unit 21A. The power supply unit 21L supplies a DC power supply having a predetermined voltage to the USB connector 21K. USB plug 22 ₇ USB reader 22 is connected to the USB connector 21K. The interface 21J connects the USB connector 21K to the bus 21M. That is, the USB interface 21J and the USB connector 21K exchange data with the USB reader 22 under the control of the processing unit 21A. The storage unit 21B is a storage device that stores various data and processing procedures.

  The processing unit 21A executes a simulation or automatic meter reading instruction input to the input unit 21C. When the processing unit 21A receives a simulation instruction from the input unit 21C via the interface 21D, the processing unit 21A performs a simulation data reading process. When the processing unit 21A starts the simulation data reading process, the processing unit 21A sends a simulation data transmission request to the USB reader 22 via the USB interface 21J and the USB connector 21K. At this time, the USB reader 22 is supplied with DC power from the power supply unit 21L through the USB connector 21K. Thereafter, when the processing unit 21A receives simulation data from the USB reader 22 via the USB connector 21K and the USB interface 21J, the processing unit 21A stores the simulation data in the storage unit 21B.

  After storing the simulation data, the communication network NT is connected to the communication unit 21H, the service provided by the server computer 30 is displayed on the display unit 21F, and when the simulation service is selected by the input unit 21C, the processing unit 21A In response to a transmission request from the server computer 30 of the electric power company, the simulation data is read from the storage unit 21B, the communication unit 21H is controlled via the interface 21G, and the simulation data is transmitted to the server computer 30. Thereafter, when the processing unit 21A receives the simulation result of the electricity bill by the server computer 30 of the power company, the processing unit 21A controls the display control unit 21E to display the simulation result on the display unit 21F.

  On the other hand, upon receiving an automatic meter reading instruction from the input unit 21C via the interface 21D, the processing unit 21A performs reading processing of meter reading data. When the processing unit 21A starts reading processing of meter reading data, the processing unit 21A sends a request for transmitting meter reading data to the USB reader 22 via the USB interface 21J and the USB connector 21K. At this time, the USB reader 22 is supplied with DC power from the power supply unit 21L through the USB connector 21K. Thereafter, when the processing unit 21A receives the meter reading data from the USB reader 22 via the USB connector 21K and the USB interface 21J, the processing unit 21A stores the meter reading data in the storage unit 21B.

  After storing the meter reading data, the communication network NT is connected to the communication unit 21H, the service provided by the server computer 30 is displayed on the display unit 21F, and the automatic meter reading service is selected by the input unit 21C, the processing unit 21A In response to a transmission request from the server computer 30 of the power company, the meter reading data is read from the storage unit 21B, the communication unit 21H is controlled via the interface 21G, and the meter reading data is transmitted to the server computer 30. After that, when the processing unit 21A receives a usage result representing the amount of electricity and electricity bill used in the previous month from the server computer 30 of the power company from the communication unit 21H via the interface 21G, the processing unit 21A controls the display control unit 21E to control the last month. The amount of electricity used and the electricity charge are displayed on the display unit 21F.

  The server computer 30 of the electric power company stores information about the customer and provides various services to the customer. The information stored by the server computer 30 includes a customer table for managing customers. An example of the customer table is shown in FIG. The customer table 301 in FIG. 8 includes “customer number”, “name” and “address” of the customer, “application date” of the contract, and “contract contents” indicating the type of contract as identification information for identifying the customer. Is stored. In the column “Contract Details”, there are stored fee menus such as “meter-rate lamp”, “low-voltage power”, “midnight power”, etc., which are selected by the customer.

  As a service provided by the server computer 30, there is an electricity bill simulation. When this service is selected by the customer's personal computer 21, the server computer 30 sends a simulation data transmission request to the personal computer 21. Thereafter, when the simulation data is received, the server computer 30 uses the customer table 301 to check the contract contents of the customer corresponding to the customer number attached to this data. Then, the server computer 30 estimates the amount of electric power and the electricity bill to be used this month from the simulation data and the contract contents.

  For example, as shown in FIG. 9, when the current month is October, and the meter reading date is midnight on October 1, the customer instructs the personal computer 21 to perform simulation at 10:00 on October 15; The server computer 30 receives the simulation data from October 14 of the previous day to the meter reading date from the personal computer 21. When the simulation data is the amount of power from October 1st to October 14th and consists of the amount of power used every hour, for example, when the customer's contract content is midnight power, that is, every day at 11 pm Server computer 30 is based on the amount of power used every hour from October 1st to October 14th. Thus, the amount of power in the late-night power hours from October 15 to October 31 and the amount of power in other time zones are estimated. Thereafter, the server computer 30 uses the power amount actually used from October 1 to October 14 and the estimated power amount from October 15 to October 31 in the current month. The amount of electric power and the electricity charge to be calculated are calculated and transmitted to the personal computer 21 as a simulation result.

  On the other hand, when the automatic meter reading service is selected by the customer's personal computer 21, the server computer 30 performs automatic meter reading. That is, the server computer 30 sends a meter reading data transmission request to the personal computer 21, receives the meter reading data, and records the meter reading data. Further, the server computer 30 calculates the amount of power used in the previous month from the received meter reading data and the meter reading data of the previous month, and calculates and records the electricity bill from this power amount.

  For example, when the reference meter reading date is midnight on the first day, as shown in FIG. 10A, when the current month is October, the customer uses the personal computer 21 to which the USB reader 22 is attached. Meter reading data is received from the electricity meter 10 at 10:00 on the first day of the month, and the meter reading data is transmitted to the server computer 30 of the power company. Since the received meter reading data is from midnight on October 1, the server computer 30 uses the meter reading data received this time and the meter reading data at midnight on September 1 as the previous meter reading data. Calculate the amount of power used in September, the previous month, calculate the electricity rate from this amount of electricity, record the calculated amount of electricity and electricity rate, and use the calculated amount of electricity and electricity rate for the previous month's usage results To the personal computer 21.

  As shown in FIG. 10B, when the current month is October, the customer receives meter reading data from the watt-hour meter 10 at 10 o'clock on October 2 using the personal computer 21 with the USB reader 22 attached. And this meter-reading data is transmitted to the server computer 30 of an electric power company. Since the received meter reading data is from midnight on October 1, the server computer 30 uses the meter reading data received this time and the meter reading data at midnight on September 1 as the previous meter reading data. , Calculating the amount of power used in September, calculating the electricity charge from this amount of electricity, recording the calculated amount of electricity and electricity, and using the calculated amount of electricity and electricity as a result of the previous month as a personal computer To 21.

  As shown in FIG. 10C, when the current month is November and the current meter reading date is, for example, midnight on November 2, the customer uses the personal computer 21 to which the USB reader 22 is attached. The meter reading data is received from the watt-hour meter 10 at 10:00 on November 1, and this meter reading data is transmitted to the server computer 30 of the power company. At this time, the server computer 30 transmits an error message to the personal computer 21 and disables automatic meter reading because the received meter reading data is from midnight on October 1 and not the current month.

  As shown in FIG. 10D, when the current month is November and the meter reading date of this month is, for example, midnight on November 2, the customer uses the personal computer 21 to which the USB reader 22 is attached. The meter reading data is received from the watt-hour meter 10 at 10:00 on November 2, and the meter reading data is transmitted to the server computer 30 of the power company. Since the received meter reading data is from midnight on November 2, the server computer 30 uses the meter reading data received this time and the meter reading data at midnight on October 1 as the previous meter reading data. Calculate the amount of power used in October, the previous month, calculate the electricity bill from this amount of electricity, record the calculated amount of electricity and the electricity fee, and use the calculated amount of electricity and the electricity fee as a result of the previous month's use To the personal computer 21.

Next, a meter reading method and a simulation method using the meter reading system according to this embodiment will be described. When a customer performs automatic meter reading or the like, the customer receives from the power company a USB reader 22 that stores in advance the meter number of the watt-hour meter 10 installed at the customer's home and the customer number of the customer. The instrument number and customer number are input by the initial setting for the USB reader 22. For example, in a state where USB reader 22 to the power company's computer is connected, after the operation of the setting button _{22 2A,} via USB plug 22 ₇ and the USB interface 22 _6, upon receiving an instrument number and a customer number from the computer the processing unit 22 ₄ of the USB reader 22 stores these numbers in the storage unit 22 _3.

  When the customer simulates the electricity bill, the USB reader 22 is connected to the personal computer 21. Thereafter, as shown in FIG. 11, when a simulation instruction is input to the personal computer 21 (step S1), the personal computer 21 sends a simulation data transmission request to the USB reader 22 (step S2). Upon receiving the simulation data transmission request, the USB reader 22 adds the instrument number to the transmission request and transmits it to the watt-hour meter 10 (step S3). When receiving the simulation data transmission request, the watt-hour meter 10 reads the simulation data when the instrument number is appropriate (step S4), and transmits this data to the USB reader 22 (step S5). Upon receiving the simulation data, the USB reader 22 adds a customer number to this data and sends it to the personal computer 21 (step S6). When receiving the simulation data, the personal computer 21 stores this data (step S7).

  Thereafter, the customer connects the personal computer 21 to the communication network NT and operates the personal computer 21 to connect to the server computer 30 of the power company. After the customer operates the personal computer 21 and selects a service for simulating electricity charges provided by the server computer 30 (step S8), the personal computer 21 performs a simulation in response to a transmission request from the server computer 30 (step S9). Data is transmitted (step S10). When the server computer 30 receives the simulation data, the server computer 30 simulates the electricity bill (step S11), and sends the simulation result to the personal computer 21 (step S12). Thereby, the personal computer 21 displays the simulation result (step S13).

  On the other hand, when the customer performs automatic meter reading, the customer connects the USB reader 22 to the personal computer 21. Thereafter, as shown in FIG. 12, when an instruction for automatic meter reading is input to the personal computer 21 (step S21), the personal computer 21 sends a request for transmitting meter reading data to the USB reader 22 (step S22). Upon receiving the meter reading data transmission request, the USB reader 22 adds a meter number to the transmission request and transmits it to the watt hour meter 10 (step S23). When receiving the meter reading data transmission request, the watt-hour meter 10 reads the meter reading data when the meter number is appropriate (step S24), and transmits this data to the USB reader 22 (step S25). Upon receiving the meter reading data, the USB reader 22 adds a customer number to this data and sends it to the personal computer 21 (step S26). When receiving the meter reading data, the personal computer 21 stores this data (step S27).

  Thereafter, the customer connects the personal computer 21 to the communication network NT and operates the personal computer 21 to connect to the server computer 30 of the power company. After the customer operates the personal computer 21 to select the automatic meter reading service provided by the server computer 30 (step S28), the personal computer 21 receives the meter reading data in response to the transmission request from the server computer 30 (step S29). Transmit (step S30). Upon receipt of the meter reading data, the server computer 30 records the meter reading data (step S31), calculates the amount of electricity and electricity used in the previous month (step S32), and uses the calculated amount of electricity and electricity as a result of use of the personal computer. 21 (step S33). Thereby, the personal computer 21 displays the use result (step S34).

  Thus, according to this embodiment, by using the reading device 20 including the personal computer 21 and the USB reader 22, it is possible to send the power amount that is the accumulated power of the power meter 10 to the server computer 30. At this time, it is not necessary to read the watt-hour meter 10 visually by the customer, so that an accurate amount of power can be sent. Further, according to this embodiment, when the customer performs simulation data or automatic meter reading, the USB reader 22 connected to the personal computer 21 may be used, so that a large-scale device is unnecessary. Furthermore, when the customer performs simulation data or automatic meter reading, the customer only has to operate the personal computer 21 that is familiar to him / her, so that the customer can easily execute the simulation data and automatic meter reading.

(Embodiment 2)
In this embodiment, the USB reader 22 has the calendar function and the timer function that the watt-hour meter 10 has in the first embodiment. Since the watt-hour meter 10 has only a timer function and no calendar function, the processing unit 14 of the watt-hour meter 10 stores the used power amount in the storage unit 15 every predetermined time by the timer function.

When performing a simulation, processor 22 ₄ of the USB reader 22 receives the data containing only the amount of power and time to be used from the power meter 10 for each simulation data, that the predetermined time. Thereafter, the USB reader 22 reverses the date using the time of each power amount of the received simulation data, the current month and day by the calendar function, and the time by the timer function, and each power of the simulation data. Give the quantity a date and generate new simulation data. The USB reader 22 sends the simulation data thus generated to the personal computer 21.

On the other hand, when performing automatic meter reading, processing unit 22 ₄ of the USB reader 22 receives the data composed only of electric energy and time for each meter reading data, i.e. a predetermined period after electricity meter 10, and the time of each meter reading data, The date is given to the meter reading data using the current month and date by the calendar function and the time by the timer function.

  Thus, according to this embodiment, it is unnecessary to add a calendar function to the watt-hour meter 10, and the structure of the watt-hour meter 10 can be simplified.

  The embodiment of the present invention has been described in detail above, but the specific configuration is not limited to each embodiment, and even if there is a design change or the like without departing from the gist of the present invention, Included in the invention. For example, in Embodiments 1 and 2, a personal computer is used as the main body of the reading apparatus, but a personal digital assistant (PDA) capable of USB connection can be used in place of the personal computer. In the first and second embodiments, data transmission / reception between the watt-hour meter 10 and the reading device 20 is performed using infrared rays. However, communication using radio waves may be used. In the first and second embodiments, the watt-hour meter 10 is identified using the instrument number. However, if there is no other watt-hour meter in the communication range between the watt-hour meter 10 and the reading device 20, a simulation is performed. Since erroneous reception of data and meter reading data does not occur, the identification process of the watt hour meter 10 using the meter number can be omitted. Further, in the first and second embodiments, the watt-hour meter is used as the meter, but the meter is not limited to this, and the present invention can be applied to a gas meter or the like.

(Embodiment 3)
In this embodiment, the use of the personal computer 21 is not necessary when receiving simulation data and meter reading data from the watt-hour meter 10. For this, a battery (not shown) to the USB reader 22 power supply unit 22 ₈ in FIG. After being operated power switch _{22 8A} of the operation unit 22 _2, according to the operation of the setting button _{22 2A,} processor 22 ₄ reads the meter number from the storage unit 22 _3, and controls the communication unit 22 ₁ Then, the transmission request of the simulation data or meter reading data and the read meter number are transmitted to the watt hour meter 10 and the process for reading the power amount from the watt hour meter 10 is performed. Processor 22 _4, and thereafter, when receiving the simulation data or meter reading data from the power meter 10, and stores the received data in the storage unit 22 _3. The processing unit 22 ₄ receives the simulation data and meter reading data, and controls the display unit 22 _5, and displays these data.

  Next, a meter reading method and a simulation method using the meter reading system according to this embodiment will be described. When a customer performs automatic meter reading or the like, the customer receives from the power company a USB reader 22 that stores in advance the meter number of the watt-hour meter 10 installed at the customer's home and the customer number of the customer. Input of the instrument number and customer number is the same as in the first embodiment.

When the customer simulates the electricity bill, he / she goes to the place where the watt hour meter 10 is installed with the USB reader 22. Thereafter, as shown in FIG. 13, and operates the setting button _{22 2A} after the power switch _{22 8A} of the USB reader 22 (step S41), USB reader 22, the transmission request of the simulation data and the meter number Is transmitted to the electricity meter 10 (step S42). When receiving the simulation data transmission request, the watt-hour meter 10 reads the simulation data when the meter number is appropriate (step S43), and transmits this data to the USB reader 22 (step S44). USB reader 22 receives the simulation data, and stores the data in the storage unit 22 ₃ (step S45).

Thereafter, the customer connects the USB reader 22 to the personal computer 21, connects the personal computer 21 to the communication network NT, operates the personal computer 21, and connects to the server computer 30 of the power company. After the customer operates the personal computer 21 and selects the electricity price simulation service provided by the server computer 30 (step S46), in response to the transmission request from the server computer 30 (step S47), the personal computer 21 is connected to the USB. A request for simulation data is sent to the reader 22 (step S48). Thereafter, when the personal computer 21 receives the simulation data to which the customer number is added from the USB reader 22 (step S49), the simulation data is transmitted to the server computer 30 (step S50). When the server computer 30 receives the simulation data, the server computer 30 performs simulation of the electricity bill (step S51), and sends the simulation result to the personal computer 21 (step S52). Thereby, the personal computer 21 displays the simulation result (step S53). Thereafter, the personal computer 21 sends a simulation result in the USB reader 22 (step S54), USB reader 22 stores the simulation result in the storage unit 22 ₃ (step S55), also the simulation results as needed Displayed on the display panel _225A .

On the other hand, when the customer performs automatic meter reading, he / she goes to the installation place of the watt-hour meter 10 with the USB reader 22. Thereafter, as shown in FIG. 14, and operates the setting button _{22 2A} after the power switch _{22 8A} of the USB reader 22 (step S61), USB reader 22, a transmission request and the meter number meter reading data It transmits to the watt-hour meter 10 (step S62). When receiving the meter reading data transmission request, the watt-hour meter 10 reads the meter reading data when the meter number is appropriate (step S63), and transmits this data to the USB reader 22 (step S64). USB reader 22 receives the meter reading data, and stores the data in the storage unit 22 ₃ (step S65).

Thereafter, the customer connects the personal computer 21 to the communication network NT and operates the personal computer 21 to connect to the server computer 30 of the power company. After the customer operates the personal computer 21 to select the automatic meter reading service provided by the server computer 30 (step S66), the personal computer 21 responds to the transmission request from the server computer 30 (step S67). A request for meter reading data is sent to 22 (step S68). Thereafter, when the personal computer 21 receives the meter reading data with the customer number added from the USB reader 22 (step S69), the meter reading data is transmitted to the server computer 30 (step S70). Upon receipt of the meter reading data, the server computer 30 records the meter reading data (step S71), calculates the amount of electricity and electricity used in the previous month (step S72), and uses the calculated amount of electricity and electricity as a result of use of the personal computer. 21 (step S73). Thereby, the personal computer 21 displays the use result (step S74). Thereafter, the personal computer 21 sends the results using the USB reader 22 (step S75), USB reader 22 stores the results used in the storage unit 22 ₃ (step S76), also the results used as needed Displayed on the display panel _225A .

  Thus, according to this embodiment, by using the reading device 20 including the personal computer 21 and the USB reader 22, it is possible to send the power amount that is the accumulated power of the power meter 10 to the server computer 30. At this time, since the customer only needs to bring the USB reader 22 of the reading device 20 to the installation place of the watt-hour meter 10, the data can be easily read.

  In this embodiment, the personal computer 21 is used for transmission with the server computer 30, but the present invention is not limited to this, and a portable terminal such as a PDA (Personal Digital Assistant) can be used.

It is a block diagram which shows the meter-reading system by Embodiment 1 of this invention. It is a front view which shows an example of the external appearance of a watt-hour meter. It is a block diagram which shows an example of the circuit part of a watt-hour meter. It is a front view which shows an example of a reader. It is a figure which shows an example of the external appearance of a USB reader, and Fig.5 (a) is a front view of a USB reader. FIG. 5B is a rear view of the USB reader. It is a block diagram which shows an example of the circuit part of a USB reader. It is a block diagram which shows an example of a personal computer. It is a figure which shows an example of a customer table. It is explanatory drawing explaining a simulation. FIG. 10A is an explanatory diagram for explaining meter reading, FIG. 10A is a diagram for explaining how meter reading data is received on the same day as the meter reading date, and FIG. 10B is a diagram showing how meter reading data is received after the meter reading date. FIG. 10C is a diagram for explaining how meter reading data is received on the day before the next meter reading date, and FIG. 10D is a diagram for explaining how meter reading data is received on the same day as the next meter reading date. It is. It is a time chart which shows an example of simulation. It is a time chart which shows an example of an automatic meter-reading. It is a time chart which shows the other example of simulation. It is a time chart which shows the other example of an automatic meter-reading.

Explanation of symbols

10 Electricity meter (metering data transmission device)
10A Storage box 10B Terminal box 11 Voltage input unit 12 Current input unit 13 Conversion unit 14 Processing unit 15 Storage unit 16 Display unit 16A Display panel 17 Communication unit 17A Infrared unit 20 Reading device (measurement data transmission device)
21 personal computer 21A processor 21B storing unit 21C input unit 21D, 21G interface 21E display control unit 21F display unit 21F ₁ display panel 21H communication unit 21J USB interface 21K USB connector 21L power unit 21M bus 22 USB reader 22A housing case 22 ₁ Communication unit 22 _1A infrared unit 22 ₂ operation unit 22 _2A setting button 22 ₃ storage unit 22 ₄ processing unit 22 ₅ display unit 22 _5A display panel 22 ₆ USB interface 22 ₇ USB plug 22 ₈ power supply unit 22 _8A power switch 30 server computer

Claims (7)

A weighing data transmission device using a computer capable of connecting peripheral devices via a universal serial bus,
A measuring instrument capable of transmitting measurement data obtained by measuring electric energy,
A reader connected to the computer by a universal serial bus, reading out the weighing data from the weighing instrument and sending it to the computer;
A weighing data transmission device comprising: The reader transmits identification information for identifying the weighing instrument when reading the weighing data from the weighing instrument,
The weighing device stores the identification information of the weighing device in advance, and when receiving the identification information from the reader, transmits the weighing data when the identification information stored in advance matches the received identification information. The weighing data transmission device according to claim 1.   3. The weighing data transmission device according to claim 2, wherein the reader stores the input identification information of the measuring instrument at the time of initial setting for inputting the identification information of the user for the reader. The weighing device stores the integrated value of the weighing data obtained by weighing every predetermined period,
The weighing data transmission device according to claim 1, wherein the reader reads each integrated value stored in the measuring instrument. The weighing device stores the integrated value of the weighing data obtained by weighing at predetermined intervals during a predetermined period,
The weighing data transmission device according to claim 1, wherein the reader reads each integrated value stored in the measuring instrument. A meter-reading system using the weighing data transmission device according to claim 4,
A meter-reading system comprising a server computer that receives an integrated value for each predetermined period from the computer and calculates an integrated value for a previous predetermined period from the integrated value and the previously received integrated value. A simulation method using the weighing data transmission device according to claim 5,
From the computer, each integrated value stored by the measuring instrument from the beginning to the middle of the predetermined period is received,
Using this integrated value, the integrated value of the weighing data from the beginning to the end of this predetermined period is simulated,
A simulation method characterized by that.

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