KR102013580B1 - Automatic setting system of electronic power meter - Google Patents

Abstract

The present invention relates to an automatic setting system of an electronic electricity meter, which comprises: a rack unit storing a plurality of electricity meters each implemented in various types in accordance with a metering method; and a control device unit determining a target electricity meter to be provided to a customer from among the plurality of electricity meters stored in the rack unit based on contract information of the customer received from the user, providing the user with one or more programs to be applied to the determined target electricity meter as a list, and setting a parameter of a program selected by the user from the programs included in the list to perform a function setting for the target electricity meter.

Description

Automatic setting system of electronic electricity meter {AUTOMATIC SETTING SYSTEM OF ELECTRONIC POWER METER}

The present invention relates to an automatic setting system of an electronic electricity meter, and more particularly, to an automatic setting system of an electronic electricity meter for setting a function provided by the electronic electricity meter.

A wattmeter is a device that measures electricity usage. It must be installed where electricity is used as well as the general home, and electricity charges are charged based on the electricity usage measured by the electricity meter.

The electricity meter is classified into an electronic electricity meter and an inductive electricity meter according to its operation method. Electronic meters and inductive meters have the same function in that they are installed in homes and industrial sites to measure electricity usage.However, unlike those of induction meters, electronic meters can measure various power-related values. There is.

The electronic electricity meter has various functions built into it, so it is essential to set (set) each function before use. The function of the electronic electricity meter is gradually diversified, and the setting process is also complicated by introducing a method of inputting an external program through a PC or the like in addition to the method of setting an internal program by pressing a button of the electricity meter. However, due to the absence of a dedicated system for performing a function setting task, there are many problems such as excessive work processing time, serious work inefficiency, and safety accident risk.

In the following, the function setting process before the use of the electronic electricity meter is outlined. First, when the target electricity meter is selected, the internal battery is removed after the upper cover is removed and the power line is connected after removing the lower cover to store the internal memory data. Subsequently, the function setting is performed by inputting a meter program based on a button operation on the top of the electricity meter or a communication connection with a PC. After removing the power line and the communication line, the upper and lower covers are connected, and the upper cover is sealed to record after dispensing.

In the conventional electronic electricity meter function setting method, since only one operator can perform the function setting of one electricity meter, excessive time is required in the function setting process, and the type of the electricity meter is selected, the function setting value is determined, and the function setting is performed. There is a problem that the error is likely to occur due to the complexity of the overall process and the performance depending on the capability of 100% users. For example, the power supply position is different for each type of electricity meter, the setting method is different for each metering type, the meter type (7 types), metering type (3 types), power transmission (2 types), meter reading date (20) Branch) and the additional signal?, Etc., the number of cases of the setting method is at least 840 or more, and thus there is a problem that the presetting is impossible and the function setting of the electricity meter is impossible for the beginner. In addition, there is a problem that the user is exposed to the risk of electric shock accident by directly operating a commercial power supply without any equipment in the power line connection process.

The above-mentioned problem is caused by the absence of a dedicated business processing system for setting the function of the electronic electricity meter, and therefore, a situation in which a system capable of safely performing the function setting of the electronic electricity meter with higher reliability is required.

Background art of the present invention is disclosed in Republic of Korea Patent Publication No. 10-2014-0119537 (2014.10.10.).

The present invention has been made to solve the above-mentioned problems, an object according to an aspect of the present invention is to solve the work complexity and risk in setting the function of the electronic electricity meter, reduce the work time, and at the same time a plurality of function setting operation It is to provide an automatic setting system of an electronic electricity meter for improving the work convenience on the function setting of the electronic electricity meter by setting the function of a large electronic electricity meter.

An automatic setting system of an electronic electricity meter according to an aspect of the present invention includes a rack unit for storing a plurality of electricity meters implemented in various types according to a metering method, and the rack unit based on contract information of a customer input from a user. Determining a target wattmeter to be provided to the customer among a plurality of wattmeters stored in the list, and providing the user with a list of one or more programs to be applied to the determined target wattmeter, and selecting a program selected by the user from among the programs included in the list. And a control device configured to set a parameter to the target wattmeter to perform a function setting for the target wattmeter.

In the present invention, the rack unit is characterized in that it comprises a plurality of housing units are each formed with a first power supply terminal for receiving each of the electricity meter and supplying power to the stored electricity meter.

The present invention provides an intermediate module unit including a plurality of intermediate modules respectively coupled to the respective electricity meters to guide the storage of the electricity meters to the respective storage units, wherein each intermediate module is a first power source formed in each of the storage units. And an intermediate module unit in which a second power supply terminal connected to the terminal and a third power supply terminal connected to the electric power meter are respectively formed.

In the present invention, each of the accommodating unit, characterized in that each having a separate power switch for interrupting the power supplied to the respective electricity meter and a separate current fuse for overcurrent protection.

The present invention further includes a communication connection unit including a communication converter unit for a 1: N (N is a natural number) communication connection between the control device and the rack unit, and a cable unit for communication connection between each storage unit and each electricity meter. It is characterized by.

In the present invention, the control device unit, the first mode for performing the function setting operation for each of the electricity meter housed in the rack unit, and a second for providing the function setting state of each of the electricity meter housed in the rack unit It operates according to the mode.

In the present invention, the control device unit, in the second mode, characterized in that the operating program for setting the function for each of the electricity meter for each of the electricity meter to provide to the user.

In the present invention, when determining the target wattmeter, the control device unit determines the target wattmeter based on the contract information, whether or not the initial energization is performed, and the number of wattmeters set for the function, wherein the contract information is a power supply method, It characterized in that it comprises one or more of information on the type of contract, contract power, meter reading date, whether or not for embroidery, and the offsetting transaction.

According to an aspect of the present invention, the present invention employs a predetermined rack structure capable of accommodating a plurality of electronic strategic meter and supplying driving power to communicate with the outside, thereby setting the function of the electronic electricity meter through a control device. By doing so, the work complexity on the function setting of the electronic electricity meter can be eliminated, the work reliability can be improved, and safety accidents such as electric shock accidents can be prevented, and the work time can be dramatically changed by setting the functions of a plurality of electronic electricity meters in one function setting operation. It can be shortened.

1 is a block diagram illustrating an automatic setting system of an electronic watt-hour meter according to an embodiment of the present invention.
2 is an exemplary view illustrating a structure in which a plurality of electronic electricity meters are stored in a rack in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.
3 to 6 are exemplary diagrams for explaining the rack of the automatic setting system of the electronic electricity meter according to an embodiment of the present invention.
7 to 10 are exemplary diagrams for explaining an intermediate module of an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.
11 and 12 are exemplary diagrams for describing a power supply unit of an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.
13 to 15 are exemplary diagrams for describing a communication connection unit of an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.
16 is an exemplary diagram illustrating a parameter of a program applied to a target electricity meter in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.
17 and 18 are exemplary diagrams illustrating an example of an algorithm in which a control device determines a target electricity meter in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.
19 to 22 are exemplary diagrams for describing a function setting operation according to a first mode in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.
23 to 27 are exemplary diagrams for describing a function setting operation according to a second mode in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of an automatic setting system of an electronic electricity meter according to the present invention. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, the definitions of these terms should be made based on the contents throughout the specification.

1 is a block diagram illustrating an automatic setting system of an electronic electricity meter according to an embodiment of the present invention, and FIG. 2 illustrates a rack portion of a plurality of electronic electricity meters in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention. 3 to 6 are exemplary diagrams for explaining a rack portion of an automatic setting system of an electronic electricity meter according to an embodiment of the present invention, and FIGS. 7 to 10 are one example of the present invention. Exemplary diagrams for describing an intermediate module of an automatic setting system of an electronic electricity meter according to an embodiment, and FIGS. 11 and 12 are exemplary views for explaining a power supply unit of an automatic setting system of an electronic electricity meter according to an embodiment of the present invention. 13 and 15 are exemplary views for explaining a communication connection unit of an automatic setting system of an electronic electricity meter according to an embodiment of the present invention. 16 is an exemplary diagram illustrating a parameter of a program applied to a target electricity meter in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention, and FIGS. 17 and 18 are diagrams of an electronic electricity meter according to an embodiment of the present invention. FIG. 19 is a diagram illustrating an example of an algorithm in which a control device determines a target electricity meter in an automatic setting system, and FIGS. 19 to 22 are functions set according to a first mode in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention. 23 to 27 are exemplary diagrams for describing a function setting operation according to a second mode in an automatic setting system of an electronic electricity meter according to an embodiment of the present invention.

Referring to FIG. 1, an automatic setting system of an electronic electricity meter according to an embodiment of the present invention includes a rack unit 200, an intermediate module unit 300, a power supply unit 400, a communication connection unit 500, and a control device unit 600. ) May be included. 2 illustrates a structure in which the plurality of electronic electricity meters 100 are accommodated in the rack 200 to be described later.

Hereinafter, the electronic wattmeter will be described as a concept including a low voltage electronic wattmeter or a high voltage electronic wattmeter.

The rack unit may accommodate a plurality of electricity meters 100 each implemented in various types according to a metering method, that is, the rack unit 200 is illustrated in FIG. 3 to set functions for the plurality of electricity meters 100. As described above, the power meter 100 may be fixedly housed.

The rack 200 may include a plurality of accommodating parts 210 for accommodating a plurality of power meters, respectively, and the number of accommodating parts 210 may be variously selected according to a designer's intention. An example in which two accommodating parts 210 are provided is shown. In order to prevent the stored power meter from falling forward, each storage unit 210 may be designed to have a predetermined inclination angle with respect to the ground as shown in FIG. 4. In addition, each accommodating part 210 may have a first power supply terminal (eg, a bottom) provided with a first power supply terminal for supplying driving power to each electricity meter stored as shown in FIG. 5. In addition, each accommodating part 210 may be provided with a separate power switch for interrupting the power supplied to each power meter and an overcurrent protection, respectively, as shown in FIG. 6. Furthermore, each accommodating unit 210 may include an individual communication port (eg, an RS-485 communication port), a USB port for connecting a high-voltage electronic electricity meter to which optical communication is applied, to mediate communication between the control device and each meter to be described later, and LEDs for displaying the operating state of each storage unit 210 may be provided respectively.

Here, when the type of the electronic electricity meter according to the metering method is described in detail, the electronic meter may be classified into seven types according to the power supply method and the contract power with the customer as shown in Table 1 below. Classification according to the method) can be divided into three types as shown in Table 2 below. Meanwhile, in Table 1, the 3P3W method with low utilization is excluded.

division Power supply method Contract power (kW) Advanced E-type (AE-type) Single phase 2-wire 1 to 10 G-Type, 1P2W, 100 (10) A Single phase 2-wire 11 to 19 G-Type, 1P2W, 120 (10) A Single phase 2-wire 20 to 23 G-Type, 1P2W, 5 (2.5) A Single phase 2-wire 24 to 199 G-Type, 3P4W, 100 (10) A 3-phase 4-wire 1 to 59 G-Type, 3P4W, 120 (10) A 3-phase 4-wire 60 to 71 G-Type, 3P4W, 5 (2.5) A 3-phase 4-wire 72-499

division Breakdown Type 1 Weigh electricity consumption in a single time without dividing the weighing time zone 2 types Measure electricity consumption by dividing the weighing time zone into two time zones 3 types Electricity is measured by dividing the weighing time zone into three time zones

As will be described later, the control device unit 600 according to the present embodiment has various types as described above, and a target to be provided to the customer based on the contract information of the customer received from the user among the plurality of power meters stored in the rack unit 200. By determining the electricity meter, it is possible to eliminate the long working time for the user to directly determine the target electricity meter and to improve the work reliability.

The intermediate module unit 300 may include a plurality of intermediate modules 310 which are respectively coupled to each electricity meter and guide the storage of each electricity meter to each storage unit 210. In other words, each intermediate module 310 included in the intermediate module 300 may be fixedly coupled to each electronic power meter to be fixedly accommodated in each storage unit 210. 7 shows an example of each intermediate module 310.

Each intermediate module 310 included in the intermediate module 300 includes a second power supply terminal connected to a first power supply terminal formed in each storage unit 210 of the rack unit 200, and a third power supply terminal connected to a power meter. Each may be formed. Accordingly, the power supplied from the power supply to be described later may be supplied to each power meter through the first power terminal, the second power terminal, and the third power terminal. The second power terminal may be installed below the intermediate module 310 so as to be connected to the first power terminal, and the third power terminal may be installed above the second power terminal so as to be connected to the wattmeter. As shown in FIG. 8, the power supply terminal may be implemented to include an elastic member (eg, a spring) therein to facilitate attachment of a wattmeter. Meanwhile, the second and third power terminals have terminal thicknesses and terminal-to-terminal spacings according to the types of low-voltage electric power meters or high-voltage electric power meters applied to the present embodiment in order to prevent contact between power lines due to different types of power meters. This may be predesigned. In addition, the intermediate module 310 may be provided with a guide unit for preventing the coupling with the heterogeneous electricity meter, and to prevent the tilt of the combined electricity meter. FIG. 9 illustrates a process in which the electricity meter is coupled to the intermediate module 310. As shown in FIG. 9, it can be seen that the electricity meter is designed to be powered without removing the lower terminal cover of the electricity meter. . FIG. 10 illustrates that the electricity meter is coupled to the intermediate module 310 and received in the accommodating part 210.

The power supply unit 400 may receive the commercial power 220V and supply the rack unit 200. At this time, the power supply unit 400 may include a transformer for transforming the power supplied to the rack unit 200, thereby allowing the user to select any one of the commercial power 220V and the transformed power 110V. have. In addition, the power supply unit 400 may include a high-sensitivity earth leakage circuit breaker for blocking supply of commercial power to the rack unit 200. FIG. 11 illustrates a main power switch and a transformer switch of the power supply unit 400, and FIG. 12 illustrates an earth leakage breaker and a transformer.

Here, summarized the features employed in the present embodiment in order to prevent safety accidents such as electric shock or short circuit accident, this embodiment is a high-sensitivity earth leakage breaker installed in the power supply unit 400, the individual provided in the accommodating unit 210 This embodiment is based on an intermediate module 310, which is designed for each type of electronic wattmeter to prevent the power switch and the individual current fuse, the 110V voltage supply through the transformer, and the coupling with heterogeneous wattmeters and to prevent the occurrence of contact between power lines. Eliminate the electrical hazards that existed when power was connected to the meter.

The communication connection unit 500 is a configuration for communication between the control device and the electricity meter. Specifically, the communication converter unit 510 for 1: N (N is a natural number) communication connection between the control device and the rack unit 200, and each number It may include a cable unit 530 for communication connection between the payment 210 and each meter.

The communication converter unit 510 performs 1: N communication simultaneous connection between the control device unit 600 and the rack unit 200, where N may be a natural number and may have a value less than or equal to the number of the storage units 210. That is, as shown in FIG. 13, the communication converter unit 510 connects one communication port of the control device unit 600 and individual communication ports of the respective storage units 210 to N control device units 600 and N wattmeters. It is possible to perform simultaneous communication (RS-485 communication) between (up to eight in this embodiment). And, as shown in FIG. 14, the communication connection between each housing unit 210 and each electricity meter may be made by the cable unit 530.

Meanwhile, when the cable unit 530 is connected to the electricity meter, the G-type electricity meter may be designed to be connected by using the upper modem connection pin as shown in FIG. 15 instead of removing the lower terminal cover as in the prior art. For this purpose, a separate gender may be used to facilitate the connection. Since the top cover of the G-type meter needs to be removed to connect the battery built in the meter, by performing the cable connection during the battery connection process, the hassle of having to detach the lower terminal cover can be removed. have.

The control device 600 determines a target electricity meter to be provided to the customer among the plurality of electricity meters stored in the rack 200 based on the contract information of the customer received from the user, and lists one or more programs to be applied to the determined target electricity meter. It provides to the user, and by setting the parameters of the program selected by the user among the programs included in the list to the target electricity meter can perform the function setting for the target electricity meter. The control device unit 600 may be implemented to include a conventional personal computer (PC), an input device such as a keyboard, and an output device such as a monitor. Accordingly, the control device unit 600 may perform the above-described function setting based on a dedicated function setting program installed in the PC to perform the function setting. On the other hand, FIG. 16 shows an example of a parameter of a program set in the target wattmeter. 25 parameters are illustrated by using the G-type electricity meter as an example, and the parameters may vary according to the type of the electricity meter (31 parameters exist in the case of the AE-type electricity meter).

When the operation of the control device unit 600 is described in more detail, the control device unit 600 may determine a target power meter to be provided to the customer among the plurality of power meters stored in the rack unit 200 based on the contract information of the customer. have. Here, the contract information, power supply method, contract type, contract power, meter reading date, whether or not for embroidery (that is, whether or not for embroidery / ESS (Energy Storage System) / EVC (Electric Vehicle Charger)), and the offsetting transaction It may include one or more of the information about. The six pieces of information are essential information for determining a target electricity meter to be provided to the customer among the contracts of the customer, and the control device 600 may determine the target electricity meter based on the contract information and output the same to the user. have. Further, the control device unit 600 may further determine the target wattmeter in consideration of whether the initial energization is implemented and the number of the wattmeters that are set to the function (that is, the desired quantity of function setting), and FIGS. 17 and 18 illustrate the control device unit 600. Shows an example of an algorithm for determining a target electricity meter. In this case, the control device unit 600 may automatically recognize the type of the electricity meter and recognize the type thereof so that the function setting for the target electricity meter can be performed by the desired quantity among the electricity meters stored in the rack unit 200. .

In the present exemplary embodiment, the control device unit 600 provides a user with a first mode for performing a function setting operation on each of the electricity meters stored in the rack unit 200, and a function setting state of each of the electricity meters stored in the rack unit 200. Operate according to the second mode provided.

That is, in the present embodiment, since only one operator can perform the function setting of one electricity meter, excessive time is required in the function setting process, and the process of selecting the type of electricity meter, determining the function setting value, and overall function setting is complicated. And it is a technical problem to solve the problem of high error occurrence by performing depending on the capability of the user 100%, for this purpose, the present embodiment is a first mode that the function setting operation is performed by a simple selection method of the user ( For example, the function setting operation is divided into a second mode (eg, expert mode) in which a function setting operation is performed in a manner of providing a user with a function setting state of each of the electricity meters stored in the rack unit 200. Adopt a configuration to perform.

The operation of setting the function according to the first mode will be described in detail with reference to FIGS. 19 to 22. The control device unit 600 provides the above-mentioned six pieces of contract information, whether or not the initial energization is performed, and the number of power meters for which the function is set. After receiving the input ('setting' of FIG. 19), the target electricity meter is determined and provided to the user ('confirmation' of FIG. 19), and one or more programs to be applied to the determined target electricity meter are provided to the user as a list, and among the programs included in the list. The parameter of the program selected by the user may be set in the target electricity meter and the setting result may be provided to the user ('result' of FIG. 19).

That is, as shown in FIG. 20, the user inputs six types of contract information, whether or not the initial energization is performed, and the number of electricity meters set as functions in the 'setting' window (combo box (contract type) or keypad ( Contract power), etc.) When the application button is pressed, the control device unit 600 determines the target electricity meter based on the input information and selects one or more programs to be applied to the target electricity meter as shown in FIG. 21. The list is provided to the user through the 'confirmation' window. When the user selects one of the programs included in the list, the control device 600 sets the parameter of the selected program to the target power meter and sets the setting result as shown in FIG. Through the user.

As described above, in the first mode, a function setting operation is performed by a user's simple selection method, and together with the first mode, the control device unit 600 provides the second mode, so that each of the electricity meters stored in the rack unit 200 is provided. It provides the function setting status of the user and allows the user to select a separate configuration file and set it on the target electricity meter.

23 to 26, the function setting operation according to the second mode will be described in detail. As illustrated in FIG. 23, the control device unit 600 has a function setting state of each of the electricity meters housed in the rack unit 200. Can be provided to the user. In this case, the control device unit 600 may provide a user with a function setting state of all the electricity meters stored in the rack unit 200 ('meter reading (all)' of FIG. 23), and the user's selection among all the electricity meters provided. It is also possible to provide the current function setting state separately accordingly (Fig. 24).

In addition, the control device 600 may provide a function setting state of the target wattmeter corresponding to the meter type selected by the user ('setting' of FIG. 23). Further, a program to be applied to the target meter corresponding to the selected meter type may be selected by the user, and the parameter of the selected program may be set in the target meter. 25 and 26 illustrate an example in which a user selects a meter type and a program to be applied to a target electricity meter.

In addition, as shown in FIG. 27, the control device unit 600 may provide an operation program for setting the function of each electricity meter to the user by interworking with each electricity meter. That is, in addition to the operation of setting the parameter of the program according to the present embodiment, when the setting for other additional functions is required, the operation program for providing the additional function is provided to the user by interlocking with each electricity meter for each setting for other additional functions. You can also do

As described above, the present embodiment adopts a predetermined rack structure capable of accommodating a plurality of electronic strategic meter and supplying driving power to communicate with the outside, thereby performing the function setting of the electronic electricity meter through a control device, thereby providing an electronic electricity meter. It is possible to reduce the work complexity in the function setting of, to improve the reliability of work and to prevent safety accidents such as electric shock accidents, and to shorten the working time drastically by setting the functions of a plurality of electronic electricity meters in one function setting operation.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

100: power meter
200: rack
210: storage
300: intermediate module
310: intermediate module
400: power supply
500: communication connection
510: communication converter unit
530: cable section
600: control device unit

Claims (8)

A rack unit accommodating a plurality of power meters each implemented in various types according to a metering method; And
Determining a target wattmeter to be provided to the customer from among a plurality of wattmeters received in the rack unit based on the contract information of the customer received from the user, and provides the user with a list of one or more programs to be applied to the determined target wattmeter, A control device unit configured to set a parameter of the program selected by the user among the programs included in the list in the target wattmeter to perform a function setting for the target wattmeter;
Including,
The rack unit includes a plurality of housing units each receiving the respective electricity meters and each having a first power terminal for supplying power to the stored electricity meters.
An intermediate module unit coupled to each of the electricity meters, each of the intermediate meters including a plurality of intermediate modules for guiding the storage of the electricity meters into the respective storage units, wherein each of the intermediate modules is connected to a first power terminal formed in each of the storage units; And an intermediate module unit having a second power supply terminal and a third power supply terminal connected to the electric power meter, respectively,
Each accommodating unit includes an individual power switch for interrupting power supplied to the respective electricity meters and an individual current fuse for preventing overcurrent,
And a communication connection unit including a 1: N (N is a natural number) communication converter unit for communication control between the control device unit and the rack unit, and a cable unit for communication connection between the respective storage units and the respective electricity meters. Automatic setting system of electronic electricity meter characterized by.
delete delete delete delete The method of claim 1,
The control device unit may operate according to a first mode of performing the function setting operation on each of the electricity meters stored in the rack unit, and a second mode of providing a function setting state of each of the electricity meters stored in the rack unit to the user. Automatic setting system of the electronic electricity meter, characterized in that.
The method of claim 6,
The control device unit, in the second mode, the automatic setting system of the electronic electricity meter, characterized in that for operating the program for setting the function for each electricity meter for each of the electricity meter to provide to the user.
The method of claim 1,
The control device unit, when determining the target wattmeter, determines the target wattmeter based on the contract information, whether or not the initial energization is performed, and the number of wattmeters set for the function, wherein the contract information is a power supply method, a contract type, a contract. Automatic setting system of the electronic electricity meter, characterized in that it comprises one or more of information on the power, meter reading date, whether or not for embroidery, and the offsetting transaction.

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