KR101739545B1 - Remote meter reading system for load balancing and low voltage remote metering method of using this method - Google Patents

Abstract

A remote inspection load distributing system of the present invention comprises: an electrical power meter for measuring an electricity usage amount of each of consumers; a PLC modem for obtaining and storing electricity data with respect to the consumers measured by the electrical power meter; a data central unit (DCU) for obtaining and storing the electricity data from the PLC modem, and transmitting the electricity data stored through a network when there is a request from the outside; and an NMS inspection server for receiving electricity data from the DCU, storing the same in a normalized form, monitoring a power line communications (PLC) network state, and managing a state of the PLC modem.

Description

TECHNICAL FIELD [0001] The present invention relates to a remote meter reading load distribution system and a low pressure remote meter reading method using the remote meter reading load distribution system and a low pressure remote meter reading method using the same.

The present invention relates to a remote meter reading load distribution system and a low pressure remote meter reading method using the same, and more particularly to a PLC modem for acquiring and storing power data for a customer measured by a power meter, And a data concentrator (DCU) for acquiring and storing power data from the PLC modem by sequentially performing the meter reading in accordance with the set cycle and operating the data concentrator in a data redundancy manner. The PLC modem, the data concentrator (DCU) By using the SNMP protocol for power data transmission between the meter server and the server, it is possible to distribute the concentrated load to the data concentrator (DCU) during the meter reading work and reduce the data load of the PLC network, A remote meter reading load distribution system and a low pressure remote meter reading room using the same It is about the law.

In general, PLC (Power Line Communication) is also referred to as power line communication. When a power line is plugged into a socket of a home or an office, it can use voice, data, and the Internet at high speed. It is possible to connect home network to connect devices.

When this technology is realized, the complicated data transmission path to the cable television network, the telephone line, and the optical communication network has been reduced to one power line. Installation is also simple because it requires only a separate device such as a modem or system that divides power and communication data.

In addition to Internet service and network construction, remote control of electric power line based intelligent home appliances, remote meter reading of meters and remote control of various electric machines are possible. There are still problems such as the limitation of the speed due to sending data in the power line and the interference phenomenon of the power network itself, but it is expected to be put into practical use soon.

Remote meter reading means collecting customer's usage from a remote location after providing utility service by energy utilities such as electricity and gas.

FIG. 1 shows the configuration of a conventional meter reading system according to the prior art.

Referring to FIG. 1, a conventional remote meter reading system 100 includes a power data acquisition unit 110, a data concentrator 120, and a server unit 130.

The power data acquisition unit 110 includes a first power meter 111-1 to an Nth power meter 111-N and a first PLC modem 112-1 to an N-th PLC modem 112-N .

The first power meter 111-1 to the Nth power meter 111-N are installed in respective receptacles to measure and store the energy consumption of the customer, and the measured first to Nth power data are transmitted to the first power meter (PLC) through the first PLC modem 112-1 to the N-th PLC modem 112-N installed in the first to Nth power meters 111-1 to 111-N, And is transmitted to the concentration device 120.

In this case, the first electric power meter 111-1 to the Nth electric power meter 111-N may use a standard watt hour meter or an E-type watt hour meter, and the first PLC modem 112-1 to the Nth PLC meter 112-N have a slave relationship with the data concentrator 120 which is a master. When the power is turned on, the data concentrator 120-N communicates with a data concentrator (DCU) .

The data concentrator 120 periodically receives the first power data to the Nth power data from the first PLC modem 112-1 to the Nth PLC modem 112-N and stores them in an internal memory, And transmits the stored first power data to Nth power data through the network 10 when the server unit 130 makes a request.

The server unit 130 includes an FEP server 131 and a DB server 132.

In this case, the FEP (Front-End Processor) server 131 periodically collects the first power data to the Nth power data stored in the data concentrator (DCU) 120, .

2 shows a low pressure remote meter reading operation using a conventional remote meter reading system.

Referring to FIG. 2, a data concentrator (DCU) 120 firstly has a first process (A10) for requesting power data to the PLC modem 112.

Next, the PLC modem 112 has a second process (A20) for requesting the power meter 111 again for the power data.

Next, the power meter 111 has a third step (A30) of transmitting the power data acquired in each of the customers to the PLC modem 112. [

Next, the PLC modem 112 has a fourth step (A40) of transmitting the requested power data to the data concentrator (DCU) 120.

In this case, data transmission / reception between the data concentrator (DCU) 120 and the PLC modem 112 and between the power meter 111 and the PLC modem 112 are performed through a DLMS (Device Language Message Specification) protocol.

Next, the data concentrator (DCU) 120 has a fifth step (A50) of storing the received power data in an internal storage device.

Next, the FEP meter reading server 131 has a sixth step (A60) of requesting the data concentrator (DCU) 120 for the power data stored in the internal storage device.

Next, the data concentrator (DCU) 120 has a seventh process (A70) for transmitting the requested power data to the FEP survey server 131.

Lastly, finally, the FEP meter reading server 131 has an eighth step (A80) of storing the received meter reading data in the DB server 132. [

In this case, data exchange between the data concentrator (DCU) 120 and the FEP meter reading server 131 is performed through the FEP (Front-End Processor) protocol.

However, the conventional low-pressure remote meter reading method using the remote meter reading system has the following problems.

First, in the prior art, a PLC modem located between a data concentrator (DCU) and a power meter only serves as a physical path for communication, so that most of the functions for meter reading are concentrated in the data concentrator (DCU) There has been a problem that meter reading data is missing when a load is excessively generated in the data concentration unit (DCU).

Second, the conventional technology uses a data concentrator (DCU) as a meter reading protocol, a DLMS protocol as an international standard in a power meter interval, and an FEP protocol established by KEPCO between a data concentrator (DCU) and an FEP meter server. The data is transmitted in a 1: 1 manner in response to a request. Therefore, when the size of the system is increased due to continuous expansion of the service, it is difficult to cope with the load of the increased power data, thereby failing to provide reliable meter reading data .

Thirdly, there is a problem in that the conventional technology is complex in structure and frequency of error occurrence because it is diverged into an FEP server responsible for the meter reading task, an NMS server for monitoring PLC network status and PLC modem status.

Korean Patent Publication No. 10-2014-0106067

The present invention is directed to a PLC modem for acquiring and storing power data for a customer measured by a power meter and a meter reading period for each PLC modem, The data concentrator (DCU) that acquires and stores power data from the modem is provided and operates using the data duplication method. The SNMP protocol is used to transmit the power data between the PLC modem, the data concentrator (DCU) and the NMS meter reading server A remote meter reading load balancing system capable of improving reliability of data by minimizing the risk due to dropping of meter reading by distributing the load concentrated in the data concentrator (DCU) during the meter reading and reducing the data load of the PLC network, and And to provide a low pressure remote meter reading method.

According to an aspect of the present invention, there is provided a remote meter reading load distribution system comprising: a power meter for measuring a power consumption of each user; A PLC modem for acquiring and storing power data for the customer measured by the power meter; A data concentrator (DCU) for acquiring and storing the power data from the PLC modem and transmitting the stored power data over a network in response to an external request; And an NMS metering server for receiving power data from the data concentrator (DCU), storing the data in a standardized form, monitoring the PLC network status, and managing the status of the PLC modem.

According to another aspect of the present invention, there is provided a low pressure remote meter reading method using a remote meter reading load distribution system, comprising: a first step of a PLC modem requesting power data for each of a plurality of customers using a power meter; A second step of transmitting the power data to the PLC modem in response to the request; A third step of storing the received power data in the internal memory; A fourth step of requesting power data stored in the internal storage device by the PLC modem; A fifth step of the PLC modem transmitting power data to the data concentrator in response to a request; And the data concentrator (DCU) stores the received power data in an internal storage device.

Disclosure of Invention Technical Problem [10] The present invention has a technical effect of improving data reliability by minimizing the risk of omitting the meter reading by reducing the data load on the PLC network by distributing loads concentrated in the data concentrator (DCU)

FIG. 1 shows the configuration of a conventional meter reading system according to the prior art.
2 shows a low pressure remote meter reading operation using a conventional remote meter reading system.
FIG. 3 shows a configuration of a remote meter reading load distribution system according to the present invention.
FIG. 4 shows a low pressure remote meter reading operation using the remote meter reading load distribution system of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 3 shows a configuration of a remote meter reading load distribution system according to the present invention.

3, the remote meter reading load distribution system 200 according to the present invention includes a power data acquisition unit 210, a data concentrator 220, and a comprehensive server unit 230.

The power data acquisition unit 210 includes a first power meter 211-1 to an Nth power meter 211-N and a first PLC modem 212-1 to an N-th PLC modem 212-N .

The first power meter 211-1 to the Nth power meter 211-N are installed in respective receptacles to measure and store the energy consumption of the customer, and the measured first power data to Nth power data are stored in the first power N are transmitted to the first PLC modem 212-1 to the Nth PLC modem 212-N installed in the meters 211-1 to 211-N, respectively, and the respective first PLC modems 212 -1) to the N-th PLC modem 212-N.

Thus, the PLC modems lower than the data concentrator (DCU) perform the meter reading primarily, and the load concentrated on the data concentrator (DCU) is distributed, so that the meter reading can be performed more smoothly.

In this case, examples of the storage device include a flash memory, a magnetic random access memory (MRAM), a ferroelectric RAM (FeRAM), a phase change RAM (PRAM), a resistance RAM (ReRAM), a polymer RAM (PoRAM) Nano floating gate memory) can be used.

In this case, the first power meter 211-1 to the Nth power meter 211-N can use a standard watt-hour meter or an E-type watt-hour meter, and the first PLC modem 212-1 to the N-th PLC meter 212-N has a slave relationship with a data concentrator (DCU) 220 as a master. When the power is turned on, power line communication with a data concentrator 220 Communication, PLC).

The data concentrator (DCU) 220 separately sets the measurement period for each of the first PLC modem 212-1 to the N-th PLC modem 212-N, and sequentially performs the measurement according to the set period, N-th power data stored in the storage devices of the first PLC modem 212-1 to the N-th PLC modem 212-N of the first PLC modem 212-1 to the N-th PLC modem 212- And is stored in the storage device of the data concentrator (DCU) 220.

This makes it possible to distribute the concentrated load of the data concentrator (DCU) 220 compared to the conventional method of collective meter reading (for example, 15 minutes, 30 minutes, 45 minutes, 60 minutes).

In this case, examples of the storage device include a flash memory, a magnetic random access memory (MRAM), a ferroelectric RAM (FeRAM), a phase change RAM (PRAM), a resistance RAM (ReRAM), a polymer RAM (PoRAM) Nano floating gate memory) can be used.

The comprehensive server unit 230 includes an NMS metering server 231 and a DB server 232.

In this case, the NMS (Meta Management System) meter reading server 231 reads data from each data concentrator (DCU, 220) in accordance with a distributed and set cycle for each data concentrator (DCU, 220) 220 via the network 20 and stores the acquired metering data in the database server 232 in an SNMP MIB (Management Information Base) manner.

Hereinafter, the principle of reducing the data load of the PLC network when using the SNMP protocol will be briefly described as compared with the case of using the FEP protocol.

The FEP protocol is a self-polling protocol used by KEPCO for low pressure remote meter reading.

In other words, the server sends a data request frame to the DCU in order to acquire the specific meter reading data from the DCU, and the DCU transmits the meter reading data to the server in response thereto.

However, the SNMP protocol is not a method of individually requesting data, but can be obtained by periodically GET commanding the entire data held by the DCU.

Therefore, when the server obtains the same DCU data, the data load can be reduced considerably when using the SNMP protocol compared to the FEP protocol.

 In addition, a method of ensuring compatibility between systems by standardizing the control of power data between different modems, DCUs, and servers by an SNMP MIB method will be described below.

The MIB is a set of hierarchically organized information, ie, an information database that an administrator can query or set, and serves as an information repository that the SNMP protocol basically adopts.

The MIB manages information and statistics of devices using hierarchical naming schemes. It is standardized by ISO and ITU-T. Each object has a unit for managing information and is distinguished by OID (Object Identifier).

For example, if the user inquires the data of the enterprises term, the SNMP program inquires the data in order of iso-> org-> dod-> internet-> private-> enterprises, which is internally called [1.3.6.1.4.1] .

The NMS metering server 231 serves as a network management system. In the present invention, the NMS metering server 231 monitors the state of the PLC network and the status of the PLC modems 212-1 to 212-N Function.

In this case, the NMS metering server 231 can acquire not only the meter reading data of the meter but also the PLC modem and the PLC network status using the SNMP protocol. Since the SNMP protocol is a standard method, It is possible to collect various types of information as well as the meter reading data.

In this case, the network 20 can use, for example, a Wide Area Network (WAN), 3G, 4G, LTE, LTE-A, Wireless Broadband Internet, WiFi,

FIG. 4 shows a low pressure remote meter reading operation using the remote meter reading load distribution system of the present invention.

3 and 4, the operation of the low pressure remote meter reading using the remote meter reading load distribution system of the present invention will be described in detail.

First, the PLC modem 212 has a first step B10 for requesting the power meter 211 for power data.

Next, the power meter 211 has a second process (B20) for transmitting the power data acquired in each customer to the PLC modem 212. [

Next, the PLC modem 212 has a third step (B30) of storing the received power data in its own storage device.

In this case, data transmission / reception between the power meter 211 and the PLC modem 212 is performed through a DLMS (Device Language Message Specification) protocol.

Next, the data concentrator (DCU) 220 has a fourth step (B40) of requesting the PLC modem 212 for the power data stored in the storage device of the PLC modem 212. [

Next, the PLC modem 212 has a fifth step (B50) of transmitting the requested power data to the data concentrator (DCU, 220).

In this case, data transmission / reception between the PLC modem 212 and the data concentrator (DCU) 220 is performed through a Simple Network Management Protocol (SNMP) protocol.

That is, the data concentrator 220 of the present invention obtains power data from the PLC modem 212 through the SNMP protocol through the fourth process (B40) and the fifth process (B50) , The data concentrator (DCU) 120 acquires the power data from the power meter 111 through the DLMS protocol through the first process (A10) to the fourth process (A40) as shown in FIG. 2, .

In other words, the present invention uses the SNMP protocol from the PLC modem 212 to the NMS metering server 231, thereby facilitating the application of the system, reducing the data load on the network, , It is possible to distribute the load on the acquired data by applying the cycle of information acquisition to the individual items due to the nature of the SNMP protocol.

In addition, since the present invention uses the standard method of the MIB, which has been proven as described above, it is superior to the conventional system in terms of stable operation. In the conventional system, by using its own storage method (such as file storage method) It is the improvement of difficult operation.

Next, the data concentrator (DCU) 220 has a sixth step (B60) of storing the received power data in an internal storage device.

Next, the NMS survey server 231 has a seventh process (B70) for requesting power data stored in an internal storage device by the data concentrator (DCU, 220).

Next, the data concentrator (DCU) 220 has an eighth process (B80) of transmitting the requested power data to the NMS survey server 231. [

In this case, data exchange between the data concentrator (DCU) 220 and the NMS metering server 231 is performed through a simple network management protocol (SNMP) protocol.

Lastly, the NMS metering server 231 standardizes the received metering data by using an SNMP MIB (management information base) storing method.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention.

210: Power data acquisition unit
211-1 to 211-N: First power meter to Nth power meter
212-1 to 212-N: First PLC modem to Nth PLC modem
220: Data Concentrator (DCU)
230:
231: NMS Meter Reading Server
232: DB server
20: Network

Claims (11)

Power meters for measuring the power consumption of each of the receivers;
PLC modems for acquiring and storing power data for the customer measured from the power meters;
A data concentrator (DCU) for acquiring and storing the power data from the PLC modems and transmitting the stored power data over a network in response to an external request; And
And an NMS metering server for receiving power data from the data concentrator and storing the data in a standardized form and monitoring the state of the PLC network and the status of the PLC modems,
The data concentrator (DCU)
Separately setting a measurement period for each of the PLC modems, sequentially reading the measured data according to a set period to acquire the power data,
The power data transmission method between the PLC modems and the data concentrator (DCU) uses a Simple Network Management Protocol (SNMP) protocol,
Wherein the power data transmission method between the data concentrator and the NMS metering server uses a Simple Network Management Protocol (SNMP) protocol. delete delete 2. The method of claim 1,
The power data may be stored in a flash memory, a magnetic random access memory (MRAM), a ferroelectric RAM (FeRAM), a phase change RAM (PRAM), a resistance RAM (ReRAM), a polymer RAM (PoRAM), a nano floating gate memory ), And the stored information is stored by using any one of the following methods. delete A first process in which PLC modems request power data for respective receptacles with power meters;
The power meters sending power data to PLC modems in response to a request;
The PLC modems storing the received power data in an internal memory;
The data concentrator DCU requests power data stored in the internal memory to the PLC modems;
The PLC modems transmitting power data to the data concentrator in response to a request;
A sixth step of storing the received power data in an internal storage device;
A seventh step of the NMS metering server requesting the power data stored in the internal storage device by the data concentrator;
An eighth step of transmitting the requested power data to the NMS meter server; And
The NMS metering server includes a ninth step of storing the received metering data in a standardized form,
The data concentrator (DCU)
Separately setting a measurement period for each of the PLC modems, sequentially performing meter reading according to a set period to request the power data,
The power data transmission method between the PLC modems and the data concentrator (DCU) uses a Simple Network Management Protocol (SNMP) protocol,
Wherein the power data transmission method between the data concentrator and the NMS metering server uses a Simple Network Management Protocol (SNMP) protocol. 7. The method according to claim 6, wherein in the third step,
A flash memory, a magnetic random access memory (MRAM), a ferroelectric RAM (FeRAM), a phase change RAM (PRAM), a resistance RAM (ReRAM), a polymer RAM (PoRAM), and a nano floating gate memory Wherein the low-pressure remote meter reading method using the remote meter reading load distribution system is used. delete delete delete delete

Images