JP6004387B2 - Optical fiber closure and power measurement system using the closure - Google Patents

Description

  The present invention relates to an optical fiber closure for measuring the amount of electric power sold and sold by a customer, and an electric energy measurement system using the closure.

  Increasingly, customers who use electricity install solar power generators at home and sell the electricity generated by these devices to power companies. In this case, the power company needs to measure the amount of power used by the customer and the amount of power sold by the customer to the power company. Normally, for this purpose, a meter reader visits a customer's home, and the customer purchases the amount of power purchased from the power company (hereinafter referred to as “the amount of power purchased”) with a watt-hour meter for power purchase, and the customer sells it to the power company. The amount of electric power (hereinafter referred to as “the amount of power sold”) is checked with a watt-hour meter for selling power. Such meter reading requires time and effort.

  Various automatic meter reading systems have been proposed in order to reduce time and labor by the meter reader (see, for example, Patent Document 1). An example of this automatic meter reading system is shown in FIG. In this system, electronic watt-hour meters 101 and 102 that are installed at customer A and customer B and provided with a communication function and the like can transmit and receive data to and from the aggregation device 110 wirelessly. The aggregation device 110 is suspended by a tool or the like on a messenger wire 130 that is bridged between the utility poles 120. The aggregating device 110 operates by using the electricity from the power line 160 connected to the low voltage transformer 150 as the power source, which is the voltage obtained by stepping down the voltage of the low voltage distribution line 140 with the low voltage transformer 150.

  The aggregation device 110 receives measurement data representing the amount of power purchased from the customer A or the customer B, that is, meter-reading data from the energy meters 101 and 102. The aggregation device 110 converts the received meter reading data into an optical signal, and sends the meter reading data to the optical closure 170 via the optical fiber 181. The optical closure 170 sends the meter-reading data converted into the optical signal to the information center via the optical fiber cable 180 which is a trunk cable composed of a large number of optical fibers. Similarly, when the customer A or the customer B has installed the solar power generation device, the aggregation device 110 receives meter reading data representing the amount of electric power sold from the customer A or the customer B from the electronic watt-hour meter. These meter reading data are sent to the information center via the optical closure 170.

  The information center calculates the amount of electric power purchased and the amount of electric power sold by the customer A and the customer B based on the received meter reading data. In addition, the information center estimates the amount of power generated by the solar power generation device from the measurement data of the solar radiation meter 190 installed in each district for customers who plan to introduce the solar power generation device.

JP-A-11-304842

  By the way, the system of FIG. 9 described above has the following problems. In this system, it is necessary to suspend the aggregation device 110 in addition to the light closure 170 on the messenger wire 130 spanned between the utility poles. Further, in this system, in order to supply power to the aggregation device 110, it is necessary to connect the aggregation device 110 and the low-voltage transformer 150 with a power line 160. Furthermore, in this system, in order to send the meter reading data from the aggregation device 110 to the optical closure 170, it is necessary to connect the aggregation device 110 and the optical closure 170 with an optical fiber 181.

  That is, in the conventional system, it is necessary to suspend the aggregation device 110 from the messenger wire 130, and it is also necessary to route the power supply line 160 and the optical fiber 181.

  An object of the present invention is to provide an optical fiber closure capable of solving the above-described problems and making it unnecessary to hang a messenger wire and to route a power supply line or an optical fiber, and an electric energy measurement system using the closure. There is.

In order to solve the above-mentioned problems, the invention of claim 1 is characterized in that a storage case fixed to a messenger wire spanned between utility poles , and a branching optical fiber cable provided in the storage case and serving as a trunk line. An optical connection tray to which an optical fiber is connected, a solar power generation unit that is provided outside the storage case and converts sunlight into electricity, and a storage battery that is provided in the storage case and stores electricity of the solar power generation unit And a wireless communication unit that is provided in the storage case, operates by electricity of the storage battery, and communicates wirelessly with an electronic watt-hour meter installed in a customer's house, and is provided in the storage case, An optical communication unit that operates by electricity of a storage battery, converts the data of the electronic watt-hour meter received by the wireless communication unit into an optical signal, and sends the optical signal to the optical fiber for branching. It is an optical fiber closure according to claim.

In the invention of claim 1, the storage battery stores electricity of the solar power generation unit provided outside the storage case. And a radio | wireless communication part and an optical communication part operate | move with the electricity of a storage battery. In this state, the wireless communication unit communicates wirelessly with an electronic watt-hour meter installed at the customer's house, and the optical communication unit converts the electronic watt-hour meter data received by the wireless communication unit into an optical signal. The optical signal is converted and sent to a branching optical fiber. An optical fiber closure having these functions is fixed to a messenger wire by a storage case.

  A second aspect of the invention is the optical fiber closure according to the first aspect, further comprising an analog / digital conversion unit that converts the voltage output from the solar power generation unit and corresponding to the amount of solar radiation into output data. The unit converts the output data output from the analog / digital conversion unit into an optical signal and sends the optical signal to the branching optical fiber.

  The invention of claim 3 is an electric energy measuring system using the optical fiber closure according to claim 1, wherein an optical signal is connected to the optical fiber cable to which the branching optical fiber is connected. When the electronic watt-hour meter is a watt-hour meter for power purchase, the center-side device receives the data of the watt-hour meter for power purchase from the optical fiber cable. When the electronic watt-hour meter is a watt-hour meter for power sale, the data of the watt-hour meter for power sale is received from the optical fiber cable. The power amount measuring system is characterized by checking the amount of power sold by the customer.

  The invention of claim 3 is an electric energy measuring system using the optical fiber closure according to claim 1, wherein the center side device is connected to the optical fiber cable to which the optical fiber closure is connected so that an optical signal can be received. ing. If the electronic watt-hour meter is for power purchase, the center-side device, when receiving data for the power purchase watt-hour meter from the optical fiber cable, checks the customer's power purchase amount based on this data. In addition, when the electronic watt-hour meter is for power sale, the center-side device, when receiving data for the power watt-hour meter from the optical fiber cable, checks the customer's power sale amount based on this data.

According to a fourth aspect of the present invention, there is provided an electric energy measuring system using the optical fiber closure according to the second aspect, wherein an optical signal is connected to the optical fiber cable to which the branching optical fiber is connected. And when the electronic watt-hour meter is a watt-hour meter for power sale, the center-side device receives the data of the watt-hour meter for power sale from the optical fiber cable. The amount of power sold by the customer is checked based on the optical fiber cable, and when the output data of the optical fiber closure is received from the optical fiber cable, the amount of power generated by the photovoltaic power generation unit of the optical fiber cable is checked based on this output data. energy measurement system characterized based on the power amount and power generation amount, detects a failure of the solar power generator, that.

The invention of claim 4 is an electric energy measuring system using the optical fiber closure according to claim 2, and the center side device is connected to the optical fiber cable to which the optical fiber closure is connected so that an optical signal can be received. ing. In the case where the electronic watt-hour meter is a watt-hour meter for power sale, the center-side device, when receiving the data of the watt-hour meter for power sale from the optical fiber cable, checks the customer's power sale amount based on this data. In addition, when the center side device receives the output data of the optical fiber closure from the optical fiber cable, the center side device checks the power generation amount of the solar power generation unit of the optical fiber cable based on the output data. The center side apparatus, based on the power generation amount and these power sale power quantity, to detect a failure of the solar power generator.

  According to the invention of claim 1, since the wireless communication unit and the optical communication unit provided in the storage case are operated by electricity generated by the solar power generation unit, an external power supply free function can be realized. And an automatic meter-reading function is realizable by the wireless communication part which communicates by electronic electric energy and wirelessly.

According to the invention of claim 2, the voltage of the solar power generation unit is output as output data, and since this data corresponds to the amount of solar radiation, the solar radiation meter required for examining the power generation amount of the solar power generation unit is provided. It can be made unnecessary.
According to the third aspect of the present invention, it is possible to perform meter reading of the amount of electric power purchased and the amount of electric power sold by each customer without using power supply and remotely.

  According to the invention of claim 4, failure detection of the photovoltaic power generation unit provided in the optical fiber closure can be performed remotely.

It is a figure which shows an example of the optical fiber closure by Embodiment 1, FIG. 1 (a) is a perspective view of an optical fiber closure, FIG.1 (b) is a top view of an optical fiber closure. It is a perspective view which shows the state which opened the storage case of the optical fiber closure. It is a block diagram which shows the structure of an optical fiber closure. It is a block diagram which shows the structure of the electric energy measurement system using an optical fiber closure. It is a figure which shows an example of customer data. It is a figure which shows an example of apparatus list data. It is a flowchart which shows an example of an electric power generation amount confirmation process. It is a flowchart which shows an example of an electric power generation amount confirmation process. It is a figure which shows an example of the conventional automatic meter-reading system.

  Next, embodiments of the present invention will be described in detail with reference to the drawings. In each embodiment, members that are the same as or the same as those in FIG. 9 described above are given the same reference numerals, and descriptions thereof are omitted.

(Embodiment 1)
An optical fiber closure according to Embodiment 1 is shown in FIG. FIG. 1A is a perspective view of an optical fiber closure, and FIG. 1B is a plan view of the optical fiber closure viewed from above (in the direction of arrow A). The optical fiber closure 10 of FIG. 1 is used by being attached to an optical fiber cable 180. In addition, although illustration is abbreviate | omitted, the optical fiber closure 10 is suspended by the messenger wire. The optical fiber closure 10 includes a storage case 11, and photovoltaic power generation (PV) panels 12 and 13 provided in the storage case 11. In FIG. 1A, the description of the solar power generation panel 13 is omitted for convenience of drawing.

The storage case 11 includes a fixing portion 11A and an opening / closing portion 11B, and the opening / closing portion 11B is attached to the fixing portion 11A so as to be openable and closable as shown in FIG. FIG. 1A shows a state where the opening / closing part 11B is closed, and FIG. 2 shows a state where the opening / closing part 11B is opened. Although not shown, the fixing portion 11A is fixed to the messenger wire by a fixing tool or the like. Fixing portion 11A includes an upper plate portion 11A ₁ and the lower plate portion 11A ₂ of the plate, the side plate portion _11A 3 semicircular, 11A ₄ and is to form a frame body, are integrally connected to each other ing. So as to close the opening portion of the semicircular shape of the frame, is provided integrally with the side plates 11A ₅ and the frame body.

Similarly, switching unit 11B includes an upper plate portion 11B ₁ and lower plate portions 11B ₂ of the plate, so that the side plate portions _11B 3, 11B ₄ of the semicircular form the frame body, integral with one another Connected. So as to close the opening portion of the semicircular shape of the frame, it is provided integrally with the side plate 11B ₅ and the frame body.

As I mentioned earlier, although the opening and closing portion 11B is opened and closed with respect to the fixed portion 11A, which is an upper plate portion of the frame of the upper plate portion 11A ₁ of the end closing portion 11B of the frame of the fixed portion 11A It becomes possible by attaching to the end part of 11B _{1 so} that opening and closing is possible.

The photovoltaic power generation panels 12 and 13 convert sunlight energy into electricity, and are provided outside the storage case 11. That is, photovoltaic panels 12, fixed to the outside of the side plate 11B ₅ of the opening and closing portion 11B, photovoltaic panel 13 is fixed to the upper plate portion 11B ₁ of the opening and closing portion 11B. Since the photovoltaic power generation panel 12 is provided on the side plate 11B ₅ having a large area, it has a large area and generates large electric power. Furthermore, photovoltaic panels 13 are provided on the upper plate portion 11B _1, Day, the photovoltaic panel 13, so that the sunlight is irradiated. That is, the photovoltaic power generation panel 13 generates electric power according to the state of solar radiation at that time.

In this embodiment, provided with a photovoltaic panel 12 on the side plate 11B ₅ of the opening and closing portion 11B of the housing case 11, provided with a photovoltaic panel 13 on the top plate portion 11B ₁ of the opening portion 11B of the housing case 11 but provided solar panels 12 to the side plates 11A ₅ of the opening and closing portion 11A of the housing case 11 may be provided with a photovoltaic panel 13 on the upper plate portion 11A ₁ of the opening portion 11A of the housing case 11, also, the sun The photovoltaic panels 12 and 13 may be provided on both the fixed part 11A and the opening / closing part 11B.

The frame and the side plate 11B ₅ of the frame and the side plates 11A ₅ and the fixed portion 11B of the fixing portion 11A, the storage space is formed in the housing case 11. The fixed portion 11A includes an optical connection tray 14, a storage battery 15A, a wireless unit 15B, a hub (HUB) 15C, a media converter (MC) 15D, and AD (analog / digital) conversion so as to fit in the storage space. A container 15E is provided.

  The optical connection tray 14 is originally provided in the optical fiber closure 10. For example, the optical fiber closure 10 is used to pull an optical fiber from the optical fiber cable 180 in order to connect the optical fiber to a customer's home. The optical connection tray 14 also stores extra length of each optical fiber.

  The storage batteries 15 </ b> A to AD converter 15 </ b> E are provided in order to realize a multi-function, in addition to the original function of the optical fiber closure 10, such as dropping of an optical fiber. That is, the storage battery 15A to AD converter 15E realize an automatic meter reading function, a solar radiation amount measuring function, and an external power source free function. The storage batteries 15A to AD converter 15E that realize these functions will be specifically described with reference to FIG.

  The storage battery 15 </ b> A stores electricity generated by the solar power generation panel 12 provided on the side of the storage case 11 and the solar power generation panel 13 provided on the upper side of the storage case 11 with solar energy. . Then, the storage battery 15A supplies the stored electricity as a power source to the wireless unit 15B to the media converter 15D. That is, the storage battery 15A stores the electricity generated by the energy of sunlight and supplies the stored electricity to the wireless unit 15B to the media converter 15D regardless of day or night, thereby realizing an external power source free function.

  The AD converter 15E operates using electricity from the storage battery 15A as a power source. The AD converter 15E converts an analog electric signal into a digital electric signal. In this embodiment, the AD converter 15E converts the voltage value of electricity generated by the photovoltaic power generation panel 13 into a digital voltage value. That is, the digital electric signal output from the AD converter 15E is a digital voltage value.

As mentioned earlier, photovoltaic panel 13 is a top of the housing case 11, the upper plate portion 11B ₁ of the opening portion 11B, are fixed. For this reason, the solar power generation panel 13 is irradiated with sunlight in the daytime. That is, the photovoltaic power generation panel 13 generates electric power according to the state of the amount of solar radiation at the installation point of the optical fiber closure 10. That is, the amount of power generated by the solar power generation panel 13 is proportional to the amount of solar radiation. As a result, for example, when the amount of solar radiation decreases, the power generated by the solar power generation panel 13 decreases, and the voltage of the solar power generation panel 13 decreases accordingly.

  As described above, the digital voltage value output from the AD converter 15 </ b> E corresponds to the amount of solar radiation applied to the solar power generation panel 13. The AD converter 15E sends a digital electric signal to the hub 15C as output data. In this embodiment, the AD converter 15E sends output data to the hub 15C at the timing when the wireless unit 15B described below receives the meter reading data.

  Thus, since the solar power generation panel 13 charges the storage battery 15A, the solar power generation panel 12 realizes an external power source free function, and the AD converter 15E and the solar radiation amount measurement at the installation point of the optical fiber closure 10 Realize the function.

  The wireless unit 15B operates using electricity from the storage battery 15A as a power source. The radio unit 15B receives radio waves from an electronic watt-hour meter that can transmit digital meter reading data and the like wirelessly. In addition to the amount of power purchased by the customer, the meter reading data includes the amount of power sold by the customer to the power company. Further, the meter reading data includes a meter number of an electronic watt-hour meter as identification information. The wireless unit 15B receives meter reading data from the electronic watt-hour meter every predetermined time. The wireless unit 15B converts digital meter reading data received by radio waves into an electrical signal and sends it to the hub 15C. The wireless unit 15B realizes an automatic meter reading function that collects meter reading data for N houses.

  The hub 15C operates using electricity from the storage battery 15A as a power source. The hub 15C is a line concentrator used in the network. That is, meter reading data that is an electrical signal from the wireless unit 15B and output data that is an electrical signal from the AD converter 15E are sent to the signal line 16A via the hub 15C.

  The media converter 15D operates using electricity from the storage battery 15A as a power source. The media converter 15D is a conversion device that receives an electrical signal for a network from the hub 15C via the signal line 16A and converts the electrical signal into an optical signal. Then, the media converter 15D sends the optical signal generated by the conversion to the optical connection tray 14 via the branching optical fiber 16B. Since the branching optical fiber 16B is connected to the optical fiber cable 180, which is a trunk line, by the optical connection tray 14, the optical signal is sent to the information center (not shown) by the optical fiber cable 180.

  The configuration and operation of the electric energy measurement system using the optical fiber closure 10 having such a configuration will be described with reference to FIG. In this electric energy measurement system, the optical fiber closure 10 is suspended from a messenger wire 130 spanned between utility poles 120 by an instrument or the like. The wireless unit 15B of the optical fiber closure 10 periodically receives meter reading data by wireless communication from a predetermined number of electronic watt-hour meters including the electronic watt-hour meters 101 and 102 installed in the customer A and the customer B. To do.

  At the same time, the photovoltaic power generation panels 12 and 13 of the optical fiber closure 10 convert sunlight energy into electricity. The energy of sunlight converted into electricity is stored in the storage battery 15A. And the radio | wireless unit 15B-media converter 15D operate | move regardless of day and night by the electricity of 15 A of storage batteries.

In this state, photovoltaic panels 13 provided in the upper plate portion 11B ₁ of the housing case 11 of the optical fiber closure 10, generates a voltage corresponding to the amount of solar radiation by sunlight at the installation point of the optical fiber closure 10 This voltage is output from the hub 15C to the media converter 15D as output data via the AD converter 15E. The hub 15C outputs meter reading data from the wireless unit 15B to the media converter 15D. These output data and meter reading data are converted into optical signals by the media converter 15D, and transmitted to the information center via the optical connection tray 14.

  The information center receives the output data and meter reading data converted into optical signals by the management device 20. The management device 20 performs various processes based on the received meter reading data.

  Such a management device 20 includes a communication device 21, a management computer 22, a database 23, and a management terminal 24. The communication device 21, the management terminal 24, and the management computer 22 are in a state in which data communication can be performed with each other via an in-house network LAN.

  The communication device 21 enables data communication between the media converter 15 </ b> D installed in the optical fiber closure 10, the management terminal 24, and the management computer 22. For this purpose, the communication device 21 has various functions necessary for communication, such as a media converter that converts an optical signal into an electrical signal. The management terminal 24 is a management-dedicated computer operated by a person in charge at the information center. The management terminal 24 performs, for example, registration of a customer who newly introduces a solar power generation device by the operation of the person in charge.

  The management computer 22 stores various data in the database 23. Data stored in the database 23 includes customer data. Customer data is data for managing customers of electric power companies, and an example thereof is shown in FIG. In the customer data of FIG. 5, the contract number, the customer's name, contact information, and address when the electric power company makes a contract for electricity supply with the customer are recorded. Customer data includes the electronic watt-hour meter number installed at the customer's home, whether or not a solar power generation device is installed, and an electronic watt-hour meter for selling power to customers who have installed the solar power generation device. Instrument number (hereinafter referred to as “photovoltaic power generation instrument number”). Thereby, the solar power generation devices 201 and 202 installed in the customers A and B, for example, are registered.

  Data stored in the database 23 includes device list data. In the device list data, specifications of the solar power generation device installed in the customer's house are recorded, and an example thereof is shown in FIG. In the apparatus list data of FIG. 6, the customer contract number, the customer name, and the photovoltaic power generation instrument number are recorded. In the device list data, the ratings of modules forming the solar array (solar panel) of the photovoltaic power generation device, the shape of the module, the conversion efficiency of the module, the number of modules, the maximum output of the device by the solar array, and the like are recorded. .

  The management computer 22 performs various processes necessary for the management apparatus 20. When the management device 20 receives the output data and meter reading data converted into the optical signal, the management computer 22 passes through the communication device 21 from the electronic wattmeters 101 and 102 for purchasing power of the customers A and B. The meter reading data for every predetermined time is received, and the electric energy for every predetermined time represented by the meter reading data for power purchase is recorded. Then, the management computer 22 calculates and records the power amount and the electricity bill used by the customers A and B, for example, for one month from the recorded power amount at every predetermined time.

  Moreover, the management computer 22 receives the output data of the photovoltaic power generation panel 13 of the optical fiber closure 10 via the communication device 21 every predetermined time, converts the output data, that is, the voltage of the photovoltaic power generation panel 13 into the amount of solar radiation, Based on this amount of solar radiation, the amount of solar radiation integrated for a predetermined time is calculated. Then, the management computer 22 records the amount of solar radiation accumulated every predetermined time. Furthermore, the management computer 22 accumulates the amount of solar radiation in units of one day. Thereby, the management computer 22 records the daily solar radiation amount.

  Furthermore, the management computer 22 receives the meter-reading data for every predetermined time from the electronic watt-hour meters 103 and 104 for power sale installed in the customers A and B via the communication device 21. The electric energy for every predetermined time represented by the meter reading data for use is recorded. At this time, the management computer 22 accumulates the electric energy in units of one day. Thereby, the management computer 22 records the amount of power sold to the power company every day. Thereafter, the management computer 22 performs a power generation amount confirmation process for investigating whether or not there is an abnormality in the generated power amount when a record of the power amount for a predetermined number of days is accumulated. This power generation amount confirmation processing is shown in FIGS. When the management computer 22 starts the power generation amount confirmation process, the management computer 22 selects the first survey target from among the solar power generation devices of each customer (step S1).

  When step S1 ends, the management computer 22 selects the first day of the predetermined number of days (step S2). When step S2 ends, the management computer 22 reads the daily solar radiation amount from the record (step S3). When step S3 ends, the management computer 22 calculates the daily power generation amount by the solar power generation device selected in step S1 from the solar radiation amount of the corresponding day (step S4). In step S4, the management computer 22 refers to the device list data, and examines the size of the solar array from the shape and the number of modules of the photovoltaic power generation device selected in step S1. And the energy of the sunlight irradiated to this solar array is investigated from the amount of solar radiation of the day, and the amount of power generation of the day by the photovoltaic power generation apparatus selected in step S1 is examined based on the conversion efficiency.

  Thereafter, the management computer 22 reads from the record the amount of power sold by the solar power generation device on the corresponding day (step S5). Thereafter, the management computer 22 compares the amount of power sold and the power generation amount calculated in step S4 (step S6), and determines whether the power generation amount is abnormal (step S7). In step S7, the management computer 22 determines whether there is an abnormality as follows. The management computer 22 preliminarily checks and records the correlation between the amount of solar radiation and the amount of power from the amount of power sold in the past and the amount of solar radiation at that time. Moreover, the management computer 22 calculates the power generation amount by each solar radiation amount. Then, the management computer 22 calculates the error range of the calculated power generation amount from the calculated power generation amount on the current day and the power amount sold on the current day, that is, the tolerance Check the range and record it. In step S7, the management computer 22 reads the allowable range from the record, and determines that the power generation amount is normal if the power generation amount calculated in step S4 and the power sale power amount read in step S5 are within the error range. When the error range is exceeded, it is determined as abnormal.

  If there is an abnormality such as a decrease in the amount of power generation in step S7, the management computer 22 refers to the customer data, and sends the meter number where the abnormality has occurred to the management terminal 24 together with the name of the selected customer to be investigated. Notification is made (step S8). Note that, in step S8, the management terminal 24 displays the solar power generation device in which a malfunction such as a decrease in the amount of power generation has occurred. Thereby, for example, the person in charge can notify the customer of the malfunction of the solar power generation device.

  Thereafter, the management computer 22 determines whether there is an unprocessed day in the predetermined number of days (step S9). If there is an unprocessed day, the management computer 22 selects an unprocessed day (step S10), and returns the process to step S3. By such steps, it is possible to investigate the abnormality of the solar power generation device in all the predetermined days.

  On the other hand, if there is no unprocessed day in step S9, the management computer 22 determines whether there is an unprocessed solar power generation device (step S11). If there is an unprocessed solar power generation device, the management computer 22 selects an unprocessed solar power generation device (step S12), and returns the process to step S2. By such steps, it is possible to investigate abnormality of all the photovoltaic power generation devices.

  Thus, according to the optical fiber closure 10 according to this embodiment, in addition to the original function of the optical fiber closure such as the dropping of the optical fiber, the radio units 15B to AD converter 15E are generated by the electricity generated by the photovoltaic power generation panels 12 and 13. However, since it operates day and night, an external power supply free function can be realized. Moreover, since the optical fiber closure 10 is equipped with the solar power generation panel 13 irradiated with sunlight in the daytime, and thereby the solar radiation amount at the installation point of the optical fiber closure 10 is investigated, the solar radiation amount measurement without the solar radiation meter is required. Function can be realized. That is, the solar radiation amount measurement function can be realized by the solar power generation panel 13 that realizes the external power source free function together with the solar power generation panel 12. Furthermore, since the optical fiber closure 10 includes the wireless unit 15B to the media converter 15D, it can communicate with an electronic watt-hour meter to realize an automatic meter reading function.

  In addition, in order to realize these functions, it is possible to eliminate the conventional aggregation device and solar radiation meter, and also eliminate the need for wiring between the low-voltage transformer and the aggregation device used for power supply. it can. That is, since the respective functions are integrated into the optical fiber closure 10, it is possible to eliminate the need for a new suspension with respect to the messenger wire 130 and the routing of the power supply line and the optical fiber cable.

  Furthermore, according to the electric energy measurement system according to this embodiment, it is possible to remotely check the malfunction of the solar power generation device from the power generation amount of the solar power generation device installed at each customer's house.

(Embodiment 2)
In the first embodiment, the abnormalities of the solar power generation apparatuses 201 and 202 installed in the customers A and B were examined. In this embodiment, the solar power generation panel 13 installed in the optical fiber closure 10 is checked. Check for abnormalities. For this purpose, the information center management computer 22 performs the following.

  In the first embodiment, the management computer 22 converts the output data, that is, the voltage of the photovoltaic power generation panel 13 into the amount of solar radiation, calculates the amount of solar radiation integrated every predetermined time from the calculated amount of solar radiation, and finally Record the amount of solar radiation accumulated per day. In this embodiment, the management computer 22 calculates the power generated by the solar power generation panel 13 based on the voltage of the solar power generation panel 13 as output data, and calculates the power generation amount for a predetermined time based on this power. calculate. Then, the management computer 22 records the calculated power generation amount.

The management computer 22, for example, examines the power sale power quantity for each predetermined time customer A which is installed in the vicinity of the optical fiber closure 10, the correlation between the power generation amount for each predetermined time by solar panels 13 in advance Is recorded. In this embodiment, the management computer 22, as proportional to the amount of power generation power sale power quantity, examining the degree of proportionality as a correlation coefficient. Furthermore, the management computer 22 examines and records a specified value representing a range in which the correlation coefficient is normal, for example, based on each correlation coefficient examined during a predetermined period.

In such a state, for example, when examining the failure of the optical fiber closure 10, the management computer 22 reads the power generation amount by the optical fiber closure 10 every predetermined time from the record. The management computer 22 according to customer A close to the optical fiber closure 10, reads the power sale power quantity for each predetermined time from the recording. Thereafter, the management computer 22 calculates the correlation coefficient between the power sale power amount and power generation amount, the correlation coefficient is checked whether the prescribed value. If the correlation coefficient is within the specified value, the management computer 22 determines that the solar power generation panel 13 is normal, and if the correlation coefficient is outside the specified value, the solar power generation panel 13 is in failure. judge.

Thus, according to this embodiment, a failure of the photovoltaic power generation panel 13 provided in the optical fiber closure 10 can be detected remotely. Further, since only performs the processing of comparing the power sale power amount and power generation amount for each predetermined time, to allow for failure detection of the photovoltaic panel 13 by a simple method.

  In addition, by taking out the output of the photovoltaic power generation panel 12, a failure of the photovoltaic power generation panel 12 can be detected in the same manner as the photovoltaic power generation panel 13.

(Embodiment 3)
In this embodiment, the power generation amount due to the introduction of the apparatus is estimated for a customer who plans to introduce the solar power generation apparatus. In this embodiment, components that are the same as or the same as those in the first embodiment described above are denoted by the same reference numerals, and description thereof is omitted.

  The person in charge of the electric power company selects the optical fiber closure installed near the customer's house and the date to be estimated, and inputs the selection information to the management terminal 24. In addition, the person in charge inputs the specifications of the photovoltaic power generation apparatus to be introduced, that is, the rating of the module forming the solar array, the shape of the module, the conversion efficiency of the module, the number of modules, and the like to the management terminal 24. . The management terminal 24 sends the input selection information, the specifications of the solar power generation device, and an instruction for estimating the power generation amount to the management computer 22.

  When the management computer 22 receives the selection information, the specifications of the solar power generation device, and the instruction for estimating the power generation amount, the management computer 22 reads the solar radiation amount on the designated day of the corresponding optical fiber closure from the record and inputs the input solar power generation Based on the specification of the device, that is, the configuration of the solar array, the amount of power generated by the photovoltaic power generation device on the day is estimated. Then, the management computer 22 sends the estimation result to the management terminal 24. Upon receiving the estimation result, the management terminal 24 displays the estimation result.

  Thus, according to the power amount measurement system of this embodiment, the power generation amount by the solar power generation apparatus that the customer plans to introduce can be remotely estimated and presented to the customer. And since the solar radiation amount used as the basis of estimation was measured by the optical fiber closure provided in the vicinity of the customer's house, the amount of power can be estimated with high accuracy.

DESCRIPTION OF SYMBOLS 10 Optical fiber closure 11 Storage case 11A Fixing part 11B Opening / closing part 12, 13 Solar power generation panel (solar power generation part)
14 Optical connection tray 15A Storage battery 15B Wireless unit (wireless communication unit)
15C hub (optical communication part)
15D Media Converter (Optical Communication Department)
15E AD converter (analog / digital converter)
16A Signal line 16B Optical fiber 20 Management device (center side device)
21 Communication Device 22 Management Computer 23 Database 24 Management Terminal 180 Optical Fiber Cable

Claims (4)

A storage case fixed to a messenger wire spanned between utility poles;
Provided in the housing case, the optical connection tray fiber for branching the optical fiber cable is connected is trunk,
A solar power generation unit that is provided outside the storage case and converts sunlight into electricity;
A storage battery that is provided in the storage case and stores electricity of the solar power generation unit;
A wireless communication unit that is provided in the storage case, operates by electricity of the storage battery, and communicates wirelessly with an electronic watt-hour meter installed in a customer's house;
Light that is provided in the storage case, operates by electricity of the storage battery, converts data of the electronic watt-hour meter received by the wireless communication unit into an optical signal, and sends the optical signal to the branching optical fiber A communication department;
An optical fiber closure characterized by comprising: An analog-digital conversion unit that converts the voltage corresponding to the amount of solar radiation output to the output data while the solar power generation unit outputs,
The optical communication unit converts the output data output from the analog-digital conversion unit into an optical signal, and sends the optical signal to the branching optical fiber.
The optical fiber closure according to claim 1. An electric energy measurement system using the optical fiber closure according to claim 1,
With respect to the optical fiber cable to which the optical fiber for branching is connected, a center side device is connected so that an optical signal can be received,
When the electronic watt-hour meter receives power data from the optical fiber cable when the electronic watt-hour meter is the power meter for power purchase, the center side device receives the power purchased by the customer based on this data. When the electronic watt-hour meter is a watt-hour meter for power sale, when the data of the watt-hour meter for power sale is received from the optical fiber cable, the customer's power sale amount is determined based on this data. Looking up,
An electric energy measurement system characterized by An electric energy measurement system using the optical fiber closure according to claim 2,
With respect to the optical fiber cable to which the optical fiber for branching is connected, a center side device is connected so that an optical signal can be received,
When the electronic watt-hour meter is a power-selling watt-hour meter, the center-side device receives the data of the power-selling watt-hour meter from the optical fiber cable. examine the amount, when receiving the output data of the optical fiber closure of the fiber optic cable, based on the output data, examines the amount of power generated by the photovoltaic power generation portion of said optical fiber cable, and a power generation amount and these power sale power quantity An electric energy measurement system characterized by detecting a failure of the photovoltaic power generation unit.

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