KR20130026841A - Automatic meter reading system and method for detecting phase - Google Patents

Abstract

PURPOSE: An automatic meter reading system for phase detection and a method thereof are provided to simply and inexpensively perform power phase detection and power outage monitoring by an electric power user. CONSTITUTION: An automatic meter reading system(100) for a phase detection includes a watt hour meter(110) and a data concentration unit(120). The watt hour meter synchronizes with a phase detection signal corresponding to the phase of power supplied from a transformer and transmits a phase detection packet. The data concentration unit recognizes a supply power phase signal corresponding to the phase of the supplied power from the transformer by each phase and determines the phase of power supplied to the watt hour meter using the recognized supply power phase signal and the phase detection packet transmitted by the watt hour meter. The watt hour meter includes a phase detection signal generator(111) and a phase detection packet transmitter(112). The phase detection signal generator generates the phase detection signal corresponding to the phase of power supplied from the transformer to the watt hour meter. The phase detection packet transmitter synchronizes with the phase detection signal and transmits the phase detection packet. [Reference numerals] (10) Transformer; (110,110',110'',100''') Watt hour meter; (111) Phase detection signal generator; (112) Phase detection packet transmitter; (113) Power failure detector; (114) Energy storage unit; (120) Data concentration unit; (121) Transformer monitoring unit; (122) Remote meter; (20) Server

Description

Automatic meter reading system and method for detecting phase

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a remote meter reading system and method for phase detection, and in particular, a meter is used to transmit a phase detection packet in synchronization with a phase detection signal corresponding to a phase of power supplied from a transformer, and a data concentrate unit (DCU). The present invention relates to a remote meter reading system and method that can inexpensively and simply perform power phase detection and power failure monitoring of a power customer by determining a phase of power supplied to a power meter using a supply power phase signal and a phase detection packet.

In the current remote meter reading system, it is common to simply acquire information of a electricity meter that records power consumption of a power customer through a communication network. However, according to the demand of smart grid power system intelligence, various new functions are required to be added to the remote meter reading system. In particular, it is difficult to grasp the connected power phase of the power customer in reality, and even by the human resources, it is difficult to adjust the power supply phase of the customer when identifying the power phase of the power customer, thereby minimizing the inequality current between phases due to the load balance between the transformer supply phases. In addition, it is possible to reduce the number of additional facilities and facilities, and thus have a large ripple effect in terms of economy and electrical quality.

On the other hand, in the remote meter reading system, the power outage information collection function of the power customer is required in the smart grid environment as an essential function for minimizing the power supply requirements and the high-down time required in recent years.

An object of the present invention is to transmit a phase detection packet in synchronization with a phase detection signal corresponding to the phase of power supplied from a transformer, and the data intensive device of the power supplied to the power meter using the supply power phase signal and the phase detection packet. It is to provide a remote metering system and method that can be inexpensive and simple to detect the power phase and power outage monitoring of power customers by determining the phase.

A remote meter reading system for phase detection according to an embodiment of the present invention, the power meter for transmitting a phase detection packet in synchronization with the phase detection signal corresponding to the phase of the power supplied from the transformer; And grasping a supply power phase signal corresponding to a phase of power supplied by the transformer for each phase, and using the identified power supply phase signal and the phase detection packet transmitted from the electricity meter to phase of power supplied to the electricity meter. It is configured to include a data concentrator for determining.

The wattmeter may include a phase detection signal generation unit configured to generate a phase detection signal corresponding to a phase of power supplied from the transformer to the wattmeter; And a phase detection packet transmitter configured to transmit a phase detection packet in synchronization with the phase detection signal.

The data concentrator may include a transformer monitoring unit configured to identify a supply power phase signal corresponding to a phase of power supplied by the transformer for each phase; And receiving meter reading information including the phase detection packet, determining a phase of power supplied to the electricity meter using the supply power phase signal and the phase detection packet, and determining the phase of power supplied to the meter reading information and the electricity meter. It may include a remote meter reading unit for transmitting the result of the phase determination to the server.

The phase detection signal may be in the form of a pulse signal that lasts for a predetermined time in synchronization with a specific point of the phase of power supplied to the electricity meter.

The phase detection packet may include a header including one or more of a preamble, start information, a transmission address, a reception address, and an end information of the phase detection packet.

The data intensive device compares a phase detection signal corresponding to a phase detection packet including the preamble or header received at the time when the preamble or header is normally received and the supply power phase signal to minimize phase angle error. May be determined as the phase of the power supplied to the electricity meter which transmitted the phase detection packet including the preamble or the header.

The data concentrator may distinguish a customer corresponding to the electricity meter by using the electricity meter information corresponding to the transmission address of the phase detection packet and the modem address previously identified by the concentrator or the server.

The electricity meter may include a power failure detector that generates and transmits a power failure detection signal when sensing a phase detection signal that lasts for a predetermined time or more.

The electricity meter may further include an energy storage unit configured to supply operating power while generating and transmitting the power failure detection signal.

The data concentrator may transmit a phase detection start packet for instructing the phase meter to start phase detection and a phase detection end packet for instructing the end of phase detection to the electricity meter.

Upon receiving the phase detection start packet, the power meter generates a random number until receiving the phase detection end packet, delays counting the number of phase detection signals by the value of the generated random number, and transmits a phase detection packet. The process can be repeated.

A remote meter reading method for phase detection according to an embodiment of the present invention includes the steps of: transmitting a phase detection packet in synchronization with a phase detection signal corresponding to a phase of power supplied from a transformer; Identifying, by the data intensive device, the power supply phase signal corresponding to the phase of the power supplied by the transformer for each phase; And determining, by the data intensive device, the phase of power supplied to the electricity meter using the supplied power phase signal and the phase detection packet transmitted from the electricity meter.

The phase detection packet may include a header including at least one of a preamble, a start information, a transmission address, a reception address, and an end information of the phase detection packet, and the determining of the phase of power supplied to the electricity meter may include: The phase detection signal corresponding to the phase detection packet including the preamble or header received when the data intensive device normally receives the preamble or the header is compared with the supply power phase signal, and the phase angle error is minimized. The method may include determining the phase of the power supplied to the electricity meter which transmitted the phase detection packet including the preamble or the header.

In the remote meter reading method for phase detection, after determining the phase of the power supplied to the electricity meter, the data intensive device corresponds to a transmission address of the phase detection packet and a modem address previously known from the concentrator or server. The method may further include identifying a customer corresponding to the electricity meter by using the electricity meter information.

The remote meter reading method for phase detection may include generating and transmitting a power failure detection signal when the phase meter detects a phase detection signal that lasts for a predetermined time or more after determining a phase of power supplied to the electricity meter. It may further include.

The determining of the phase of the power supplied to the electricity meter may include: transmitting, by the data intensive device, a phase detection start packet for instructing the electricity meter to start phase detection; The power meter receiving the phase detection start packet; Repeating the step of generating a random number by the electricity meter, counting the number of phase detection signals by the value of the generated random number, and transmitting a phase detection packet; Transmitting, by the data intensive device, a phase detection end packet for instructing the electricity meter to end phase detection; The power meter receiving the phase detection end packet; And generating, by the power meter, delaying counting the number of phase detection signals by the value of the generated random number, and stopping the process of transmitting the phase detection packet.

According to an aspect of the present invention, the electricity meter transmits a phase detection packet in synchronization with a phase detection signal corresponding to the phase of power supplied from a transformer, and the data intensive device supplies the power meter using the supply power phase signal and the phase detection packet. By determining the phase of the power to be provided, it is possible to provide a remote meter reading system and method that can be inexpensive and simple to monitor the power phase and power outage monitoring of the power customer.

1 is a view schematically showing a remote meter reading system for phase detection according to an embodiment of the present invention.
2 is a diagram illustrating a phase detection signal and a phase detection packet of a remote meter reading system for phase detection according to an embodiment of the present invention.
3 is a view for explaining a phase detection process of the remote meter reading system for phase detection according to an embodiment of the present invention.
4 is a diagram for describing a method of transmitting a phase detection packet of a remote meter reading system for phase detection according to an embodiment of the present invention.
5 is a flowchart illustrating a remote meter reading method for phase detection according to an embodiment of the present invention.

The present invention will now be described in detail with reference to the accompanying drawings. Hereinafter, a repeated description, a known function that may obscure the gist of the present invention, and a detailed description of the configuration will be omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shape and size of elements in the drawings may be exaggerated for clarity.

1 is a view schematically showing a remote meter reading system for phase detection according to an embodiment of the present invention.

Referring to FIG. 1, the remote meter reading system 100 for phase detection according to an embodiment of the present invention may include a power meter 110 and a data concentrator 120. In this case, the power meter 110 may include a phase detection signal generator 111, a phase detection packet transmitter 112, a power failure detector 113, and an energy storage unit 114. In addition, the data concentrator 120 may include a transformer monitoring unit 121 and a remote meter reading unit 122. The remote meter reading system 100 for phase detection shown in FIG. 1 is in accordance with one embodiment and the blocks shown in FIG. 1 are not all required components, and in other embodiments some blocks may be added, changed or deleted. Can be.

In the remote meter reading system 100 for phase detection according to an embodiment of the present invention, the electricity meter 110 transmits a phase detection packet in synchronization with a phase detection signal corresponding to the phase of power supplied from the transformer 10. In one embodiment, the electricity meter 110 synchronizes with the phase detection signal generator 111 and the phase detection signal to generate a phase detection signal corresponding to the phase of the power supplied from the transformer 10 to the electricity meter 110. It may include a phase detection packet transmitter 112 for transmitting the phase detection packet. In addition, when the electricity meter 110 detects a phase detection signal that lasts for a predetermined time or more, the power meter 110 generates and transmits an outage detection signal, and generates and transmits the outage detection signal. It may include an energy storage unit 114 for supplying power. The process of detecting the power failure by the power failure detection unit 113 will be described in more detail with reference to FIG. 2 below. Since the energy storage unit 114 cannot supply power to the electricity meter 110 during a power failure, the energy storage unit 114 serves to supply emergency power so that the electricity meter 110 generates and transmits a power failure detection signal.

As shown in FIG. 1, the remote meter reading system 100 for phase detection according to an embodiment of the present invention includes a plurality of power meters 110, 110 ′, 110 ″, 110 ′ connected to the same data intensive device 120. ''). At this time, it may be connected to power lines of different phases such as the electricity meter 110, the electricity meter 110 ', and the electricity meter 110'', and the data such as the electricity meter 110''and the electricity meter 110'''. The concentrator 120 may be connected to power lines of the same phase with each other.

2 is a diagram illustrating a phase detection signal and a phase detection packet of a remote meter reading system for phase detection according to an embodiment of the present invention.

First, since the signal pattern varies according to the normal state 201 in which power is normally supplied and the power failure state 202 in which power is not normally supplied, the description will be made separately.

Referring to FIG. 2, the normal state 201 will be described. In the normal state 201, the phase 210 of the power supplied from the transformer is sinusoidal and corresponds to the phase 210 of the power supplied from the transformer. The phase detection signal 220 is a pulse signal form that lasts for a predetermined time in synchronization with a specific point, for example, the highest point 211, the lowest point 212, or the zero point 213 of the phase 210 of the power supplied from the transformer. Can be. 2 shows a phase detection signal 220 synchronized to the highest point 211 of the phase 210 of power supplied from a transformer. The predetermined time may be set by a user, so long as the pulse signal can only display the specific point.

The phase detection packet 230 is transmitted in synchronization with the phase detection signal 220. The phase detection packet 230 may be immediately transmitted in synchronization with the phase detection signal 220 occurring for a short time. The phase detection packet 230 may include a header 236 including one or more of a preamble 231, a start information 232, a transmission address 233, a reception address 234, and an end information 235. . That is, the phase detection packet 230 may be made up of only minimal packet configuration information without payload. Accordingly, the phase detection packet 230 may be configured as a packet of a small size, thereby minimizing delay time and processing time. That is, since the phase detection packet 230 is immediately transmitted and minimized in synchronization with the phase detection signal 220, it is easy to send a packet within a generation time interval of the series of phase detection signals 220.

In the case of the blackout state 202, since there is no power supplied from the transformer, the phase detection signal 220 is continued until power is supplied again. As such, when the phase detection signal 220 continues for a predetermined time or more, the electricity meter generates and transmits an outage detection signal. The preset time may be preset by the user to determine whether there is a power failure, and may be set to at least one period of the normal phase detection signal or at least a predetermined period of the normal phase detection signal. The generation and transmission of the power failure detection signal may be performed by the power failure detection unit 113 shown in FIG. 1.

Returning to FIG. 1 again, in the remote meter reading system 100 for phase detection according to an embodiment of the present invention, the data concentrator 120 monitors the state of the transformer 10 and determines the phase of the supply power. In addition, the meter information is acquired by communicating with the electricity meter 110 through short range communication and the acquired information is transmitted to the server 20 through a long distance communication network. In one embodiment, the data concentrator 120 may include a transformer 10. The power supply phase signal corresponding to the phase of the power supplied by each phase is identified for each phase, and the power supply phase signal of the power supplied to the electricity meter 110 using the identified power supply phase signal and the phase detection packet transmitted from the electricity meter 110. Determine the phase. At this time, the data concentrator 120 reads the transformer monitoring unit 121 and meter reading information including the phase detection packet for identifying each phase of the power supply phase signal corresponding to the phase of the power supplied by the transformer 10. Receives, and determines the phase of the power supplied to the electricity meter 110 by using the power supply phase signal and the phase detection packet, and the result of the phase determination of the power supplied to the meter information and the electricity meter 110 to the server ( 20 may include a remote meter reading unit 122 to transmit.

The data concentrator 120 detects a phase corresponding to a phase detection packet including the preamble or header received when the preamble or header of the phase detection packet is normally received in order to minimize the phase read delay caused by packet transmission. A phase having a minimum phase angle error may be determined by comparing a signal with a supply power phase signal as a phase of power supplied to a power meter that has transmitted a phase detection packet including the preamble or header.

In addition, the data concentrator 120 may distinguish the customer corresponding to the electricity meter by using the electricity meter information corresponding to the transmission address of the phase detection packet and the modem address previously identified by the concentrator or the server. In one embodiment, the data concentrator 120 may divide a customer corresponding to the electricity meter into individual customers or power outage customers for each phase.

3 is a view for explaining a phase detection process of the remote meter reading system for phase detection according to an embodiment of the present invention.

1 and 3, the data concentrator 120 may include a phase detection start packet 310 for instructing the power meter 110 to start phase detection and a phase detection end packet 330 for indicating the end of phase detection. By transmitting, the phase detection of the electricity meter 110 can be controlled. That is, when the data intensive device 120 transmits the phase detection start packet 310 to the wattmeter 110, the wattmeter 110 transmits the phase detection packet 320 to start phase detection. 120 obtains a phase determination result 340 of the power supplied to the electricity meter using the phase detection packet 320 and transmits it to the server. When the data intensive device 120 transmits the phase detection end packet 330 to the electricity meter 110, the electricity meter 110 ends the phase detection.

4 is a diagram for describing a method of transmitting a phase detection packet of a remote meter reading system for phase detection according to an embodiment of the present invention.

In the remote meter reading system for phase detection according to an embodiment of the present invention, instead of a delay scheme for avoiding a collision in wireless, power line communication (PLC) or other communication networks, the synchronization is performed by synchronizing with the phase detection signal. A phase detection packet transmission method may be used to immediately transmit a phase detection packet and to prevent a phase detection packet transmitted from a plurality of power meters connected to the same phase from colliding on a shared medium.

3 and 4, when the data concentrator 120 receives the phase detection start packet 320 in FIG. 4 (S401), a random number for transmission delay is generated (S402). 4 illustrates the case where the value of the random number is five. Then, the number of phase detection signals is delayed by counting the number of the phase detection signals by the value of the random number (S403), and the phase detection packet is transmitted in synchronization with the phase detection signal (S404). The random number generation, delay, and phase detection packet transmission described above are repeated before the phase detection end packet reception (S406) (S405). As described above, the phase detection packet transmission method using random number and delay can prevent a plurality of power meters connected to the same phase from colliding by transmitting the phase detection packet at the same time.

5 is a flowchart illustrating a remote meter reading method for phase detection according to an embodiment of the present invention.

Referring to FIG. 5, when the remote meter reading method for phase detection according to an embodiment of the present invention is started, a power meter first transmits a phase detection packet in synchronization with a phase detection signal corresponding to a phase of power supplied from a transformer. (S501).

When the electricity meter transmits the phase detection packet (S501), the data concentrator grasps the supply power phase signal corresponding to the phase of the power supplied by the transformer for each phase (S502). Then, the data concentrator determines the phase of the power supplied to the electricity meter using the supplied power phase signal and the phase detection packet transmitted from the electricity meter (S503). The phase detection packet may include a header including one or more of preamble, start information, transmission address, reception address, and end information of the phase detection packet.

In this case, in step S503, the phase detection signal corresponding to the phase detection packet including the preamble or header received at the time when the data intensive device normally receives the preamble or the header is compared with the supply power phase signal. The phase having the smallest phase angle error may be determined as the phase of power supplied to the wattmeter in which the phase detection packet including the preamble or header is transmitted.

In addition, although not shown in FIG. In the remote meter reading method for phase detection according to an embodiment of the present invention, after step S503, the data intensive device corresponds to a transmission address of the phase detection packet and a modem address previously determined by the concentrator or server. The method may further include identifying a customer corresponding to the electricity meter by using the electricity meter information, or generating and transmitting a power failure detection signal when the electricity meter detects a phase detection signal lasting for a predetermined time or more.

In addition, step S503 may include a process according to the phase detection packet transmission method illustrated in FIG. 4.

The above-described remote metering method for phase detection has been described with reference to the flowchart shown in the drawings. While the above method has been shown and described as a series of blocks for purposes of simplicity, it is to be understood that the invention is not limited to the order of the blocks, and that some blocks may be present in different orders and in different orders from that shown and described herein And various other branches, flow paths, and sequences of blocks that achieve the same or similar results may be implemented. In addition, not all illustrated blocks may be required for implementation of the methods described herein.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken as limitations. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (16)

A power meter for transmitting a phase detection packet in synchronization with a phase detection signal corresponding to a phase of power supplied from a transformer; And
The power supply phase signal corresponding to the phase of the power supplied by the transformer is identified for each phase, and the phase of the power supplied to the electricity meter is determined using the identified supply power phase signal and the phase detection packet transmitted from the electricity meter. A remote meter reading system for phase detection comprising a data concentrator for discriminating. The method according to claim 1,
The electricity meter,
A phase detection signal generator configured to generate a phase detection signal corresponding to a phase of power supplied from the transformer to the electricity meter; And
And a phase detection packet transmission unit configured to transmit a phase detection packet in synchronization with the phase detection signal. The method according to claim 1,
The data intensive device,
A transformer monitoring unit configured to identify a supply power phase signal corresponding to a phase of power supplied by the transformer for each phase; And
Receives meter reading information including the phase detection packet, determines the phase of the power supplied to the electricity meter using the supply power phase signal and the phase detection packet, and the phase of the power supplied to the meter information and the electricity meter. And a remote reading unit for transmitting the result of the determination to the server. The method according to claim 1,
The phase detection signal,
And a pulse signal form lasting for a predetermined time in synchronization with a specific point of the phase of power supplied to the electricity meter. The method according to claim 1,
The phase detection packet,
And a header including at least one of a preamble, a start information, a transmission address, a reception address, and an end information of the phase detection packet. The method according to claim 5,
The data intensive device,
A phase detection signal corresponding to a phase detection packet including the preamble or header received at the time when the preamble or the header is normally received and the supply power phase signal are compared to determine a phase having a minimum phase angle error. The remote meter reading system for phase detection, characterized in that the phase detection packet comprising a phase of the power supplied to the power meter to be transmitted. The method according to claim 5,
The data intensive device,
And a customer corresponding to the electricity meter using the electricity meter information corresponding to the transmission address of the phase detection packet and the modem address previously identified by the concentrator or the server. The method according to claim 1,
The electricity meter,
And a power failure detection unit configured to generate and transmit a power failure detection signal upon detecting a phase detection signal that lasts for a predetermined time or more. The method according to claim 8,
The electricity meter,
And an energy storage unit for supplying operating power while the power failure detection signal is generated and transmitted, the remote meter reading system for phase detection. The method according to claim 1,
The data intensive device,
And transmit a phase detection start packet for instructing phase detection to start and a phase detection end packet for indicating phase detection to the wattmeter. The method of claim 10,
The electricity meter,
When the phase detection start packet is received, a random number is generated until the phase detection end packet is received, delayed while counting the number of phase detection signals by the value of the generated random number, and the process of transmitting the phase detection packet is repeated. Remote meter reading system for phase detection, characterized in that. Transmitting, by the meter, a phase detection packet in synchronization with a phase detection signal corresponding to the phase of power supplied from the transformer;
Identifying, by the data intensive device, the power supply phase signal corresponding to the phase of the power supplied by the transformer for each phase; And
And determining the phase of the power supplied to the electricity meter by using the supplied power phase signal and the phase detection packet transmitted from the electricity meter. . The method of claim 12,
The phase detection packet,
A header including one or more of a preamble, start information, a transmission address, a reception address, and an end information of the phase detection packet;
The step of determining the phase of the power supplied to the electricity meter,
A phase detection signal corresponding to a phase detection packet including the preamble or header received when the data intensive device normally receives the preamble or header is compared with the supply power phase signal to obtain an image having a minimum phase angle error. And determining the phase of the phase detection packet including the preamble or the header as the phase of the power supplied to the electricity meter. The method of claim 12,
After the step of determining the phase of the power supplied to the electricity meter,
The data concentrator further comprises distinguishing a customer corresponding to the electricity meter by using the electricity meter information corresponding to the transmission address of the phase detection packet and the modem address previously determined by the concentrator or the server. Remote metering method for phase detection. The method of claim 12,
After the step of determining the phase of the power supplied to the electricity meter,
And generating and transmitting a power failure detection signal when the electricity meter detects a phase detection signal that lasts for a predetermined time or more. The method of claim 12,
The step of determining the phase of the power supplied to the electricity meter,
Transmitting, by the data intensive device, a phase detection start packet for instructing the electricity meter to start phase detection;
The power meter receiving the phase detection start packet;
Repeating the step of generating a random number by the electricity meter, counting the number of phase detection signals by the value of the generated random number, and transmitting a phase detection packet;
Transmitting, by the data intensive device, a phase detection end packet for instructing the electricity meter to end phase detection;
The power meter receiving the phase detection end packet; And
And generating a random number by the power meter, delaying counting the number of phase detection signals by the value of the generated random number, and stopping the process of transmitting a phase detection packet.

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