KR101723359B1 - Power line communication method of advanced metering infrastruncture system - Google Patents

Abstract

The present invention relates to a technique for reducing a time required for reading a meter by appropriately setting communications conditions between a data concentration device and a power line communications modem according to a power line communications environment when the data concentration device reads an electronic watt-hour meter located at a remote place through power line communications in a low voltage remote meter reading system (AMI). To this end, according to one embodiment of the present invention, the number of power line communications modems communicating simultaneously is appropriately set according to an environment of the power line communications and an electronic watt-hour meter is read through the power line communications modems. According to another embodiment of the present invention, a communications sequence is set according to the number of watt-hour meters connected to the power line communications modems, and the electronic watt-hour meter is read through corresponding power line communications modems according to the communications sequence.

Description

TECHNICAL FIELD [0001] The present invention relates to a power line communication method for a low-voltage remote meter reading system,

[0001] The present invention relates to a technology for measuring an electronic watt-hour meter at a remote place through a power line communication in a low-pressure remote meter-reading (AMI) system, and more particularly, The present invention relates to a power line communication method for a low-voltage remote meter-reading system capable of shortening the meter reading time.

The Advanced Metering Infrastruncture (AMI) system is an infrastructure system for bi-directional exchange of information between a power producer and a consumer. The meter reading data of an electronic watt-hour meter installed in a customer is referred to as a power line communication (PLC) And automatically collects, analyzes, and processes the data, and then provides it to the customer.

Generally, when measuring the power consumption using the AMI system, the power producer (for example, KEPCO) requires a certain level of remote meter reading performance for the company that operates the intelligent AMI system. For example, according to the purchase specification (GS-5895-0026) of KEPCO, an AMI Data Concentration Unit (DCU) can meter more than 200 electronic watt-hour meters within 15 minutes .

In this case, the DCU must complete the meter reading within a maximum of 8 minutes. The reason for this is that the DCU is used for sorting data for meter reading data, communication for transmitting meter reading data to FEP server of KEPCO, electronic watt hour meter status management (time synchronization, missing LP data collection, ID scan, etc.) (PLC) modem management, and so on.

Ultimately, the fact that a low-voltage remote meter reading (AMI) data concentrator (DCU) should meter more than 200 electronic wattmeters in 15 minutes means that the meter reading time can not exceed about five minutes.

However, when the DCU communicates with all the power line communication modem at the same time in order to reduce the meter reading time, communication overload may occur in the PLC line, and data may be broken. However, if the DCU communicates with the powerline communication modem one-to-one, there is a problem that the communication time takes too much.

Also, according to the type of electronic watt-hour meter, the power line communication modem (PLC) modem is distinguished into the built-in type and the external type. In the case of the standard type meter (S-Type), the power line modem is built- ) Modem and RS-485 can be connected up to 30, G-Type meter can be used both internal and external.

Therefore, the number of power line communication (PLC) modems may be smaller than the number of electronic watt meters connected depending on the type of wattmeter, so that the electronic watt hour meter and the power line communication (PLC) modem are not connected one by one. To reduce the time it takes to meter to less than 5 minutes.

As an example of the meter reading time, the meter reading time for the standard type meter is about 10 seconds, the reading time for the E-type meter is about 6 seconds, and the reading time for the G-Type meter is about 7 seconds .

When 200 units of such a standard meter are connected, 10200 = 2000 seconds and 33 minutes are required, and since one E-type meter is connected to one external modem, 630 = 180 seconds is required. In this case, DCU and external modem It is difficult to complete the meter reading within 5 minutes because the meter must be read for each of the 30 E-Type meters.

In the conventional meter reading system of the low pressure remote meter reading system, since the number of communicating modems and the communication order of the watt hour meter connected to the modem are fixed, it is difficult to reduce the meter reading time of the watt hour meter under a given condition.

A problem to be solved by the present invention is to appropriately set the number of power line communication modems communicating simultaneously according to the environment of the power line communication and to meter the electronic wattmeter through the power line communication modems.

Another problem to be solved by the present invention is to set a communication order according to the number of watt-hour meters connected to a power line communication modem, and meter the electronic watt-hour meter through corresponding power line communication modems according to the communication order.

According to an aspect of the present invention, there is provided a power line communication method for a low-voltage remote meter-reading system, comprising the steps of: (a) transmitting power to a plurality of slave modems connected to an electronic watt- As an object to be inspected; (b) the data concentrator simultaneously initiating a power meter reading operation for the N slave modems; (c) registering the next slave modem as a slave modem to be searched each time the power meter reading operation through any one slave modem is completed; And (d) repeating the power meter reading operation and the new registration operation to end the power meter reading operation when the power meter reading operation for the electronic watt-hour meter is completed through the last slave modem .

According to another aspect of the present invention, there is provided a power line communication method for a low-voltage remote meter-reading system, comprising the steps of: (a) confirming a quantity of a watt-hour meter connected to a plurality of slave modems by a data concentrator; (b) arranging the plurality of slave modems in the order in which the data concentrator is connected to the plurality of watt-hour meters; And (c) performing the meter reading on the electronic watt hour meter through the slave modem according to the sorted order of the data concentrator.

According to the present invention, the number of power line communication modems communicating at the same time in accordance with the environment of power line communication is appropriately set, the electronic watt hour meter is inspected, the communication order is set according to the number of watt hour meters connected to the power line communication modem, .

First, even if an electronic watt hour meter in which the power line communication is not smooth occurs, it is possible to normally perform the meter reading of the electronic watt hour meter.

Secondly, even if an electronic watt hour meter in which power line communication is not smooth is generated, it is possible to complete the meter reading within a target time.

Third, communication is performed in an optimal power line communication environment, and the meter reading time can be shortened as much as possible.

1 is a block diagram of a low pressure remote meter reading system to which a power line communication method according to the present invention is applied.
2 is a control flowchart of a power line communication method according to an embodiment of the present invention.
3 is a control flowchart of a power line communication method according to another embodiment of the present invention.

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

1 is a block diagram of a low pressure remote meter reading system to which a power line communication method according to the present invention is applied. As shown in FIG. 1, a data concentrator (DCU) 21 having an AMI server 10, a master modem (PLC modem) A plurality of slave modems 32 connected to the E-type electronic watt hour meter 42 and a plurality of slave modem 32 connected to the E-type electronic watt hour meter 42, And a plurality of slave modems 33 connected to the plurality of G-Type electronic watt-hour meters 43. [

The AMI server 10 manages various devices constituting the AMI system such as the data concentrator 20, the slave modem 31-33 and the electronic watt-hour meter 41-43, and stores, analyzes and processes the meter reading data, And provides the meter reading data to the energy information display device (IHD: In Home Display).

The data concentrator 20 is an apparatus for collecting meter reading data of the customer-side electronic watt hour meter 41-43 in the AMI system.

The slave modem 31 is connected to the standard electronic watt-hour meter 41 in a one-to-one manner, and the plurality of slave modems 31 are connected to the data concentrator 20. The slave modem 31 performs PLC communication with the data concentrator 20 and performs RS 485 or IR communication with the electronic watt hour meter 41. Here, the slave modem 31 is a built-in power line modem as a power line communication (PLC) modem.

The slave modem 32 is connected to a maximum of 30 E-type electronic watt-hour meters 42, and the plurality of slave modems 32 are connected to the data concentrator 20. The slave modem 32 performs PLC communication with the data concentrator 20 and RS485 communication with the E-type electronic watt-hour meter 42. [ Here, the slave modem 32 is an external power line modem as a power line communication (PLC) modem.

The slave modem 33 is connected to up to 30 G-type electronic watt-hour meters 43, and the plurality of slave modems 33 are connected to the data concentrator 20. The slave modem 33 performs PLC communication with the data concentrator 20 and performs RS485 communication with the G-Type electronic watt-hour meter 43. Here, the slave modem 33 is a built-in or external power line modem as a power line communication (PLC) modem.

The electronic watt-hour meter 41-43 is an electric meter which measures the various electric usage amounts of a customer, generates and stores meter reading data, and provides the meter reading data to the slave modems 31-33 through communication.

FIG. 2 is a control flowchart of a power line communication method according to an embodiment of the present invention, and a power line communication method according to an embodiment of the present invention will be described as follows.

The data concentrator 20 sequentially transmits the meter reading command data to the slave modems 31 to 33 via the master modem 21 (S11).

On the other hand, the slave modems 31 to 33 transmit the response data to the data concentrator 20 through the master modem 21.

In this state, the data concentrator 20 checks whether the N-th response data has been received from the slave modems 31-33. If it is determined that all the N response data have been received, N slave modems are selected as slave modems to be inspected (S12, S13).

Thereafter, the data concentrator 20 simultaneously starts the power meter reading operation for the N slave modems selected as objects to be inspected (S14).

Whenever it is determined that the power meter reading operation through any one of the slave modems has been completed, the data concentrator 20 transmits one slave modem to the slave modem as a reference for the new registration (S15, S16).

Thereafter, the data concentrator 20 terminates the power meter reading operation when it is determined that the power meter reading operation for the corresponding electronic watt-hour meter is completed through the last slave modem through the above process (S17).

For example, when there are 120 slave modems connected to the data concentrator and 200 electronic wattmeters connected to the slave modems, N (for example, 20 Slave modems are selected as slave modems to be inspected, and at the same time, the electric power meter reading operation for the electronic watt-hour meters is started.

Thereafter, every time the power meter reading operation through one slave modem is determined to be completed, the slave modem of the next step is additionally registered as a slave modem to be searched, and the power meter reading operation is performed as described above.

Therefore, the data concentrator can perform the power meter reading operation simultaneously within the range of the maximum number of the slave modems targeted in advance.

The number (N) of the slave modems selected as the objects to be inspected can be appropriately changed according to the communication environment. Since the communication environment varies from time to time depending on the amount of power used, it is necessary to grasp the communication environment according to the power consumption of the slave modems in advance.

For example, if communication is performed between the data concentrator and the slave modems in order to detect the amount of power in the afternoon time with a large amount of power consumption, the probability that the power meter read information is damaged due to a high communication load is increased so that the incidence of communication errors increases, The communication speed also slows down. However, if the above-mentioned communication is performed at the early morning hours when there is little power consumption, the rate of occurrence of the communication error is lowered and the communication speed is also increased.

For this reason, when the communication environment is bad, the data convergence device has to communicate with a large number of slave modems because of its slow response speed. When the communication environment is good, the response speed is high, so that a smaller number of slave modems Communication can be performed.

As a result, when the data concentrator communicates with a certain number of slave modems without considering the communication environment between the data concentrator and the slave modems, when the communication environment is poor, the response time becomes slow and the waiting time becomes long. On the other hand, when the communication environment is good, the response speed is high and it is necessary to respond immediately. However, if the number of the slave modems is large, it can not respond immediately. Nevertheless, in the immediate case, the data may be corrupted due to data overload.

Meanwhile, FIG. 3 is a control flowchart of a power line communication method according to another embodiment of the present invention, and a power line communication method according to another embodiment of the present invention will be described as follows.

The data concentrator 20 checks the number of watt-hour meters 41-43 connected to the N slave modems 31-33 (S21).

Thereafter, the data concentrator 20 aligns the N slave modems 31-33 in the order in which many watt-hour meters are connected (S22).

Thereafter, the data concentrator 20 performs meter reading on the electronic watt-hour meter through the slave modem according to the sorted order (S23).

One of the methods for reducing the meter reading time when the data concentrator 20 performs a meter reading operation on the watt-hour meters 41-43 connected to the N slave modems 31-33 is to connect the external slave modems 32 and 33 The order of the meter reading is decided.

For example, when a maximum of 30 E-type electronic watt-hour meters are connected to the external slave modem 32, when the meter-checking operation for the slave modem 32 is lastly performed, 630 = You can not complete the meter reading within 180 seconds of the target time (for example, 5 minutes).

However, if the meter reading operation of the slave modem 32 is performed from the beginning, the meter reading operation can be performed at the same time as other built-in slave modem 31 or 33, thereby reducing the meter reading time, Can be completed.

As a result, when sorting the slave modems in the order in which the electronic watt-hour meters are connected in order, the power line communication (PLC) environment can be grasped when the meter reading operation is performed and the number of the slave modem connected to the environment can be appropriately adjusted according to the environment. Can be completed.

Although the preferred embodiments of the present invention have been described in detail above, it should be understood that the scope of the present invention is not limited thereto. These embodiments are also within the scope of the present invention.

10: AMI server 20: data concentrator
21: Master Modem 31-33: Slave Modem
41-43: Electronic watt hour meter

Claims (4)

(a) selecting a plurality of slave modems connected to an electronic watt-hour meter as the objects to be searched according to a power line communication speed, the data converging device selecting N slave modems;
(b) the data concentrator simultaneously initiating a power meter reading operation for the N slave modems;
(c) replacing the slave modem in the next priority order with the slave modem to be searched every time the power meter reading operation through any one slave modem among the N slave modems is completed; And
(d) repeating the power meter reading operation and the replacement registration operation to end the power meter reading operation when the power meter reading operation for the electronic watt-hour meter is completed through the last slave modem,
The step (c)
The data concentrator may replace the slave modem having the highest order among the slave modems that have not yet performed the power meter reading operation, instead of the slave modem having completed the power meter reading operation, with the slave modem of the power meter reading target, And the power meter reading operation is simultaneously performed through the N high-level slave modems.
The method of claim 1, wherein step (a)
Transmitting the meter reading command data to the slave modem through the master modem;
The slave modems transmitting response data to the data concentrator via the master modem; And
And selecting the N slave modems from which the response data is received as the slave modem to be searched when the Nth response data is received from the slave modems by the data concentrator. Power line communication method of meter reading system.
The method as claimed in claim 2, wherein the master modem is a power line communication (PLC) modem and is provided inside the data concentrator.
The method of claim 1, wherein the slave modems
And a power line communication (PLC) modem.

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