KR20130112469A - Synthetic network management system for a pole transformer and operation method of the same - Google Patents

Abstract

PURPOSE: An integrated management network system for pole transformer and an operating method thereof are provided to enable remote administrators to effectively operate monitoring diagnostic data by using a terminal attached to each of a plurality of pole transformers. CONSTITUTION: An integrated management network system for pole transformer transmits a plurality of different measurement data to remote administrators by using a node terminal (120) attached to each of a plurality of pole transformers (110,130,150). The system constructs networks to operate the plurality of pole transformers more systematically and effectively and determines pole transformers to be selected as a replacement target or a maintenance target out of the plurality of pole transformers. The system comprises the node terminal, a slave terminal (140), a master terminal (160), and an integrated management server (300). [Reference numerals] (100,AA,BB) Slave pole transformers; (200) Master pole transformers; (300) Integrated management server for pole transformers; (CC) Wired/wireless communication network

Description

Technical Field [0001] The present invention relates to a pillar transformer integrated management network system and a method of operating the same,

The present invention relates to a control and measurement technology, and more particularly, to a network system for managing and managing a pillar transformer capable of identifying a pillar transformer to be selected as a replacement object or a pillar transformer among a plurality of pillar transformers using a terminal attached to the pillar transformer, And the operating method thereof.

Currently, the transformer management system in operation is as follows. First, a probe capable of measuring current and voltage is attached to the secondary cut-off line of the pillar transformer. Second, the measured current and voltage signals are connected to the terminal by wire. , And obtains the load data such as the current and voltage of the transformer by wirelessly transmitting the measured value to the remote site through the terminal.

In order to install and maintain the terminal, the installer must install directly on the pillar transformer and install a probe corresponding to the current and voltage sensors for each phase on the secondary cut line and connect it to the terminal. However, in the case of the power distribution line, a plurality of wired communication lines other than the power line are very complicated. Therefore, the above-mentioned connection operation is very difficult. In addition, due to strong winds or connection failure, There is a risk of various safety accidents due to terminal breakage, electric shock, short circuit, and the like.

To overcome this problem, a digital type transformer system which can be integrated into a distribution transformer and transmit various operation states to a remote manager has been devised. In the digital type transformer system, the connection line between the probe and the terminal device can be omitted, so that problems such as the difficulty of the installation / maintenance and the risk of the safety accident can be solved. However, each terminal attached to the individual transformer is measured And a communication structure of N: 1 type in which data is transmitted. Thus, there are other problems such as a communication bottleneck and waste of communication resources.

In addition, the digital type transformer system has a problem that the efficiency of operation and the ease of maintenance are significantly reduced when the transformer to be monitored is large, and the communication cost is also increased in proportion to the installed terminals.

A first aspect of the present invention is to provide a pillar transformer integrated management network system and a method of operating the same, which can solve the problems of the prior art, and a first object of the present invention is to provide a pillar transformer integrated management network system To the supervisor at the remote location, thereby constructing a network that more effectively operates the maintenance system for a plurality of pillar transformers.

It is a second object of the present invention to provide a monitoring system for a poultry transformer, which is capable of performing a replacement or repair of at least one pillar transformer deviating from a predetermined error range among a plurality of pillar transformers, It is to be able to decide timely (easily and quickly).

The pillar transformer integrated management network system according to the present invention includes a slave terminal collecting measurement data for each transformer from node terminals attached to each of a plurality of transformers using near field wireless communication and transmitting the measurement data in a first time period; A master terminal for collecting the measurement data transmitted from the slave terminal and transmitting data collected over a second time period through a wired / wireless communication network; And an integrated management server for determining whether at least one of the plurality of transformers is abnormal based on the collected data received from the master terminal.

The slave terminal may be one of node terminals attached to a plurality of transformers of the same side, and the master terminal may be any one of slave terminals attached to a plurality of side plates.

The integrated management server may determine at least one or more transformers deviating from the error range by comparing the collected data with reference data set in advance as an anomaly operation transformer.

The integrated management server may perform a remote check using the installed electric power system diagram of the operation and connection state of at least one transformer deviating from the error range before the determination.

Wherein the slave terminal includes: a slave sensing unit that periodically acquires measurement data generated by a pillar-form transformer in which the slave terminal is installed; A Zigbee communication unit for performing data communication with the node terminal; And an RF communication unit for performing data communication with the master modem unit.

Wherein the node terminal comprises: a node sensing unit for periodically acquiring measurement data generated by a pillar transformer provided with the node terminal; And a Zigbee communication unit for performing data communication with the slave terminal.

When the node terminal fails to communicate with the slave terminal or the master terminal, the node terminal can generate and transmit a self-origination signal.

When the slave terminal or the master terminal recognizes the self-origination signal, the slave terminal or the master terminal can determine that the node terminal that has transmitted the self-origination signal is normally operating.

Wherein the master terminal comprises: a master sensing unit for periodically acquiring measurement data generated by a pillar transformer provided with the master terminal; A Zigbee communication unit for performing data communication with the node terminal; An RF communication unit for performing data communication with the slave modem unit; And a wired / wireless communication unit for performing data communication with the integrated management server.

The wired / wireless communication unit may use a code division multiple access (CDMA) or a mixed-mode HFC communication.

The second time period may be set longer than the first time period.

A method for operating a pillar transformer integrated management network system according to the present invention includes a first step of collecting measurement data for each transformer from a node terminal attached to each of a plurality of transformers of the same substation using short range wireless communication; A second step of the slave terminal transmitting the measurement data in a first time period; A third step of the master terminal collecting the measurement data sent from the slave terminals attached to the plurality of slave terminals; A fourth step in which the master terminal transmits data collected in a second time period through a wire / wireless communication network; And a fifth step of the integrated management server judging whether at least one of the plurality of transformers is abnormal based on the collected data received from the master terminal.

Determining whether the collected data is within an error range by comparing the collected data with preset reference data; And determining at least one or more transformers deviating from the error range to be an anomalous operation transformer.

Further comprising the step of remotely checking the operation and connection state of at least one transformer deviating from the error range by using the installed electric power system diagram before the determining step.

The node terminal further includes a step of generating and transmitting a self-originated signal when communication with the slave terminal or the master terminal fails.

When the master terminal recognizes the self-origination signal, the slave terminal or the master terminal may determine that the node terminal that has transmitted the self-origination signal is normally operating.

The pillar transformer integrated management network system and the method of operating the same may be implemented by transferring measurement data of the pillar transformer to a manager at a remote location by using a terminal attached to a plurality of pillar transformers, And provides a first effect of establishing a network that operates effectively.

Further, according to the present invention, a manager at a remote location can appropriately (quickly and easily) determine replacement time or repair time for at least one pillar transformer deviating from a predetermined error range among a plurality of pillar transformers based on the measurement data Gives the second effect.

FIG. 1 is a configuration diagram of a network system for integrally managing a pillar transformer according to an embodiment of the present invention;
2 is a configuration diagram of a node terminal according to an embodiment of the present invention;
3 is a configuration diagram of a slave terminal according to an embodiment of the present invention;
4 is a configuration diagram of a master terminal according to an embodiment of the present invention.
5 is a flowchart illustrating an operation of a node according to an exemplary embodiment of the present invention.
6 is an operation flow diagram of a slave terminal according to an embodiment of the present invention, and Fig.
7 is a flowchart illustrating an operation of a master terminal according to an exemplary embodiment of the present invention.

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

1 is a diagram showing a network system for integrally managing a pillar transformer according to an embodiment of the present invention.

Referring to FIG. 1, the pillar transformer integrated management network system transmits a plurality of different measurement data to a manager at a remote location using a terminal attached to each of a plurality of pillar transformers 110, 130, and 150, 130, and 150 and a pillar transformer to be selected as a replacement target or a maintenance target among a plurality of pillar transformers 110, 130, and 150. The node terminal 120 A slave terminal 140, a master terminal 160, and an integrated management server 300.

In this case, the measurement data is information in which the unique number and the installed position coordinate value of each pneumatic transformer are stored in advance and the current value, the voltage value, the active power amount, the reactive power amount and the power factor of the secondary side (load side) of the pillar transformer are stored in real time I will mention it in advance.

A selected one of the plurality of node terminals 120 attached to the plurality of the pseudo-pumped transformers 110 is connected to the slave terminal 140, . Three pillar-type transformers are installed on the ordinary stator, and each pillar-type transformer can be divided into A, B and C phases. The slave terminal may be, for example, a terminal attached to one of the p-type transformers A, B and C, and the terminal attached to the other p-type transformer may be set as a node terminal. It will be appreciated that the settings for the node terminal and the slave terminal for each phase may be changed by an external input or a setting of an administrator.

The slave terminal 140 can transmit a plurality of measurement data generated by the plurality of node terminals 120 or measurement data generated by the slave terminal 140 to the connected RF communication network.

3 is a block diagram of a slave terminal according to an embodiment of the present invention.

The slave terminal 140 includes a slave sensing unit 141, a slave database unit (not shown), a zigbee communication unit 142, and an RF communication unit 143.

The slave sensing unit 141 acquires the slave measurement data generated by the pillar transformer 130 to which the slave terminal 140 is attached at a predetermined period (usually every one second).

The slave database part temporarily stores the slave measurement data.

The Zigbee communication unit 142 receives measurement data from a plurality of node terminals installed in the same base station, temporarily stores the measurement data in the slave database, and periodically transmits a plurality of measurement data or slave measurement data to the RF communication network.

The RF communication unit 143 is an example of an RF modem for a long distance communication capable of bidirectional communication with a master terminal 160 connected to an RF communication network.

In summary, the slave terminal 140 transmits a plurality of measurement data acquired from a plurality of node terminals mounted on the same peripheral node and a slave measurement data acquired from the slave sensing section 141 every predetermined period (typically, every 10 seconds) Temporarily stores it in the database unit, and transmits it to the RF communication network every predetermined period (usually every 30 minutes).

Each node terminal 120 forms a 1: 1 matched structure with each pillar transformer 110 and includes a node sensing unit 121, a node database unit (not shown), and a Zigbee communication unit 122 . 2 is a configuration diagram of a node terminal 120 according to an embodiment of the present invention.

The node sensing unit 121 changes and acquires measurement data generated by the pneumatic transformer 110 every predetermined period (usually every one second).

The node database part temporarily stores measurement data.

The Zigbee communication unit 122 transmits measurement data to the Zigbee communication network.

The Zigbee modem unit 122 applies a Zigbee modem for short-range communication, which is capable of bidirectional communication with the slave terminal 140 connected to the Zigbee communication network, as one example.

To summarize, each node terminal 120 periodically (normally, every 10 seconds) transmits the measurement data acquired by the pillar transformer 110 to the zigbee communication network.

If any one of the plurality of node terminals 120 fails to communicate with the slave terminal 140, the corresponding node terminal 120 generates a self-origination signal at a predefined period (typically every 60 seconds) and transmits it to the Zigbee communication network .

As the self-origination signal transmitted through the Zigbee communication network is recognized by the slave terminal 140, the slave terminal 140 confirms that the node terminal that transmitted the self-origination signal is normally operating.

In other words, since any one of the plurality of node terminals 120 performs the time synchronization every predetermined period (typically 60 seconds) in the slave terminal 140, the slave terminal 140 transmits the time synchronization to the plurality of node terminals 120, And the like.

4 is a block diagram of a master terminal 160 according to an embodiment of the present invention.

The master terminal 160 is selected to communicate with the integrated management server 300 among a plurality of slave terminals and is connected to the master terminal 160 by a plurality of measurement data generated by the plurality of node terminals 120, And transmits the generated master measurement data or a plurality of measurement data or slave measurement data received through the RF communication unit to the pre-connected wired / wireless communication network.

In order to improve understanding of the master terminal 160, a more detailed description is given as follows.

Specifically, the master terminal 160 includes a master sensing unit 161, a master database unit (not shown), a Zigbee communication unit 162, an RF communication unit 163, and a wire / wireless communication unit 164.

The master sensing unit 161 acquires the master measurement data generated by the installed pole-shaped transformer 110 every predetermined period (usually every one second).

The master database part temporarily stores the master measurement data.

The Zigbee communication unit 162 receives a plurality of measurement data from a plurality of node terminals installed in the same base station and temporarily stores the measurement data in the master database.

The RF communication unit 163 receives data collected by a slave terminal installed in each of a plurality of side ports.

The wired / wireless communication unit 164 periodically (usually in units of two hours) transmits a plurality of measurement data or master measurement data acquired through Zigbee communication and collected data acquired through RF communication.

The wired / wireless communication unit 164 is connected to the pillar transformer integrated management server 300 through a wireless communication supporting modem such as CDMA, B-CDMA and LTE, a Hybrid Fiber Coaxial (HFC) modem, a PLC (Power Line Communication) A modem, and an optical communication modem.

In summary, the master terminal 240 includes a plurality of measurement data acquired periodically (typically every 10 seconds) from a plurality of node terminals installed on the same peripheral device, master measurement data acquired from the master sensing section 161, 163), periodically (normally every two minutes), and transmits the collected data to the master database unit through the wired / wireless communication unit 164 periodically (usually every two hours) .

The time synchronization between the node terminal 120 and the slave terminal 140 through the self-origination signal is performed in the same manner between the node terminal 120 and the master terminal 160. That is, the node terminal 120 installed in the same port as the master 160 transmits a self-origination signal to the zigbee communication network at a predetermined period (typically every 60 seconds), and the master terminal 160 transmits the self- As the transmitted self-acknowledgment signal is recognized, it is confirmed that the node terminal 120 that has transmitted the self-originated signal is normally driven.

However, when the master terminal 160 can communicate with the integrated management server 300 using the RF communication unit 163, the master terminal 160 can transmit data using the RF communication unit 163 without a separate wired / wireless communication unit.

When a plurality of slave terminals 140 are formed, a plurality of slave terminals and a plurality of slave terminals 160 are grouped into a single master terminal 160. Each master terminal 160 includes a plurality of slave terminals Or slave measurement data is received via the RF communication network. Preferably, the master terminal 160 is installed at the origin of a plurality of slave terminals to facilitate communication between the plurality of slave terminals.

Here, the operator who wishes to change the slave terminal 140 from the master terminal 160 to the slave terminal 140 at any time is required to change the pillar transformer integrated management server 300 ).

The pillar transformer integrated management server 300 receives a plurality of measurement data, slave measurement data, or master measurement data transmitted through a high-speed wired / wireless communication network, and receives a plurality of measurement data, slave measurement data, The pseudo-pumped transformer 130 or the master pseudo-inductive transformer 150 is judged as abnormal operation with respect to at least one of the pseudo-pumped transformer 110, the slave pumped transformer 130 or the master pumice transformer 150, Determine the transformer as the replacement pole transformer or the pillar transformer to be repaired.

The integrated management server 300 performs a remote check using the installed electric power system diagram of the operation state and the connection state of at least one pillar transformer deviating from the error range before the determination.

In addition, the integrated management server 300 generates notification information on at least one pillar transformer that can be regarded as a malfunction or a breakage through a remote check in the form of SMS (Short Message Service) / MMS (Multimedia Message Service) Not only the terminal of the administrator who operates the server 300 for the integrated transformer management but also the terminals that are owned by the various administrators designated by the administrator collectively transmit the text.

5 is an operation flowchart of a node terminal according to an embodiment of the present invention.

The node terminal is respectively installed in the pillar-shaped transformer and senses measurement data of the transformer according to a predetermined period (S501).

The node terminal transmits the measurement data to the slave terminal installed on the same side, and the Zigbee communication network can be used at this time (S502).

When the measurement data transmission fails, the node terminal transmits a self-origination signal to the slave terminal at predetermined time intervals (S503 to S504).

6 is a flowchart illustrating an operation of a slave terminal according to an exemplary embodiment of the present invention.

The slave terminal is set one by one on the side where the plurality of pillar-shaped transformers are installed, and senses measured data of the installed pillar-shaped transformers according to a predetermined period (S601).

The slave terminal collects measurement data of node terminals installed in the same side of the base station according to a predetermined period (S602).

The slave terminal continuously collects the measurement data of the node terminal and transmits measurement data collected so far to the master terminal using the RF communication network when a predetermined first time period elapses (S603 to S604).

7 is a flowchart illustrating an operation of a master terminal according to an exemplary embodiment of the present invention.

The master terminal is installed in an inverter installed with a plurality of pneumatic transformers, and senses the measured data of the installed pneumatic transformers according to a predetermined period (S701).

The master terminal acquires the measurement data of the node terminals installed in the same side station according to a predetermined period (S702).

The master terminal continuously collects the measurement data of the node terminal and collects data transmitted from the slave terminals using the RF communication network when the first time period elapses (S703 to S704). The data transmitted from the plurality of slave terminals means measurement data of all the transformers installed in the slave terminals where the respective slave terminals are installed.

The master terminal collects data from a plurality of slave terminals every first time period, and at the same time, when the second time period has elapsed, data collected from the slave terminal until now, measurement data of the node terminal installed in the same port, (S705 to S706) to the integrated management server. In communication with the integrated management server, the master terminal can communicate with any one of a wireless communication supporting modem such as CDMA, B-CDMA and LTE, an HFC (Hybrid Fiber Coaxial) modem, a PLC (Power Line Communication) Or an RF communication network may be used depending on the distance from the server for integrated management. It is preferable that the second time period is set longer than the first time period so that the communication load can be reduced as much as possible.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention as set forth in the claims below. Will understand.

100: Slave lieutenant
110: Node pole transformer
120: Node terminal
130: Slave pole transformer
140: Slave terminal
200: master lieutenant
150: Master pole transformer
160: Master terminal
300: Pole transformer integrated management server

Claims (16)

A slave terminal collecting measurement data for each transformer from node terminals attached to each of the plurality of transformers using near field wireless communication and transmitting the measurement data in a first time period;
A master terminal for collecting the measurement data transmitted from the slave terminal and transmitting data collected over a second time period through a wired / wireless communication network;
Integrated management server for determining whether at least one or more of the plurality of transformers in operation based on the collected data received from the master terminal
And a pneumatic transformer integrated management network system including the pneumatic transformer.
The method of claim 1,
The slave terminal is any one of the node terminals attached to each of a plurality of transformers of the same peripheral,
The master terminal is any one of the slave terminal attached to each of the plurality of periphery columnar transformer integrated management network system.
The method of claim 1,
Wherein the integrated management server determines at least one or more transformers deviating from an error range as an anomalous operation transformer by comparing the collected data with preset reference data.
The method of claim 3, wherein
Wherein the integrated management server performs a remote check using an installed electric power system diagram of operation and connection status of at least one transformer deviating from the error range before the determination.
The method as claimed in claim 1,
A slave sensing unit periodically acquiring measurement data generated by a pillar-form transformer in which the slave terminal is installed;
A Zigbee communication unit for performing data communication with the node terminal;
An RF communication unit for performing data communication with the master modem unit
And a pneumatic transformer integrated management network system including the pneumatic transformer.
The method of claim 1, wherein the node terminal
A node sensing unit periodically acquiring measurement data generated by a pillar-form transformer provided with the node terminal;
A Zigbee communication unit for performing data communication with the slave terminal
And a pneumatic transformer integrated management network system including the pneumatic transformer.
The method of claim 1, wherein the node terminal
And a self-origination signal is generated and transmitted when communication with the slave terminal or the master terminal fails.
8. The method of claim 7, wherein the slave terminal or the master terminal
And when it recognizes the self-origination signal, determines that the node terminal that has transmitted the self-origination signal is normally driven.
The method of claim 1, wherein the master terminal
A master sensing unit periodically acquiring measurement data generated by a pillar transformer provided with the master terminal;
A Zigbee communication unit for performing data communication with the node terminal;
An RF communication unit for performing data communication with the slave modem unit; And
A wired / wireless communication unit for performing data communication with the integrated management server
And a pneumatic transformer integrated management network system including the pneumatic transformer.
The method of claim 9,
Wherein the wired / wireless communication unit uses a Code Division Multiple Access (CDMA) or a HFC communication system.
The method of claim 1,
And said second time period is set longer than said first time period.
A first step of the slave terminal collecting the measurement data for each transformer from the node terminals attached to each of the plurality of transformers on the same side of the same using the near field wireless communication;
A second step of the slave terminal transmitting the measurement data in a first time period;
A third step of the master terminal collecting the measurement data transmitted from the slave terminals attached to the plurality of slave terminals;
A fourth step of transmitting, by the master terminal, data collected at a second time period through a wired or wireless communication network;
A fifth step of the integrated management server determining whether at least one or more of the plurality of transformers are abnormal based on the collected data received from the master terminal;
Wherein the method comprises the steps of:
13. The method of claim 12, wherein the fifth step
Checking whether the collected data is within an error range through comparison with preset reference data; And
Determining at least one or more transformers deviating from the error range to be an abnormal operation transformer
Wherein the method comprises the steps of:
The method of claim 13,
A step of remotely checking the operation and connection state of at least one transformer deviating from the error range by using the installed electric power system diagram before the determining step
Further comprising the steps of:
13. The method of claim 12,
When the node terminal fails to communicate with the slave terminal or the master terminal, generating a self origination signal and transmitting
Further comprising the steps of:
The method of claim 15,
When the slave terminal or the master terminal recognizes the self-origination signal, determining that the node terminal that has transmitted the self-origination signal is normally driven
Further comprising the steps of:

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