KR102451848B1 - Detecting apparatus, detecting system and detecting method for phase of supplied power - Google Patents

Abstract

The present invention relates to an apparatus, system and method for detecting a power phase, wherein the device for detecting a power phase according to the present invention is installed in a part that receives power and consumes power in a certain phase, and detects a specific phase through power line communication. a power line communication unit on the receiving unit side for receiving the phase detection signal transmitted at the time of zero crossing; a timer for measuring a time difference between a time point at which the phase detection signal is received and a time point at which the random phase crosses zero; and a phase detection unit configured to detect which phase the arbitrary phase is by using the measured time difference.
Accordingly, it is possible to accurately detect the power supply phase with a simple configuration.

Description

Power phase detection apparatus, system and method {Detecting apparatus, detecting system and detecting method for phase of supplied power}

The present invention relates to an apparatus, system and method for detecting a power supply phase, and more particularly, to an apparatus, system and method for detecting a power supply phase capable of accurately detecting a power supply phase through power line communication with a simple configuration.

Power generated in the power plant is generally supplied to a transformer in a three-phase four-wire system, and is decompressed in the transformer and supplied to the final receiver. In some cases, the power supplied to the final recipient is a 3-phase 4-wire type, but in general housing, single-phase power is supplied.

On the other hand, for efficient operation of power, power consumption for each phase should be the same, and accordingly, if power consumed for each phase is unbalanced, it is necessary to correct it.

In order to correct the power consumption for each phase, it is necessary to check the phase of the power used by the receiver in advance.

As one of the prior art related to checking what phase the power source on the receiver's side is, there is a 'phase information detection system and detection method' of registration number 10-0730627. In the prior art, a main device that is installed in a power plant, a substation, or any place where phase confirmation is possible and collects information about the phase of a three-phase transmission/distribution line, and a wireless communication between the main device and an operator at any measurement place The phase of the line is detected using a measuring device that checks the phase information of the transmission/distribution line. And more specifically, a) after the communication between the measuring device and the main device is made, synchronizing the time of the measuring device and the main device with the current time possessed by the communication relay station that relays the wireless communication at every predetermined time, b ) subdividing and dividing the synchronized time, creating a waveform identical to the phase of the measurement line at the divided time and substituting the phase for the measured phase to calculate phase angle information, c) the main device in the measuring device By comparing the transmitted phase angle information with the phase angle of the transmission/distribution line in which the main device is installed, the phase angle difference between -60 degrees and less than +60 degrees is determined as the same phase and notified to the measuring device The phase of the line is detected through the steps.

However, in the case of detecting the power phase according to the prior art, a separate wireless communication means is required to transmit information between the main device and the measuring device, and the time synchronization between the main device and the measuring device is properly performed according to the wireless communication state. If not, there may be a problem that the accuracy of phase discrimination is lowered.

US 10-0730627 B1

Accordingly, an object of the present invention is to solve the problems of the related art, and to provide an apparatus, system and method for detecting a power supply phase that can accurately check the phase of the power used by the receiver through a simpler configuration.

The problem to be solved by the present invention is not limited to the above-mentioned problems, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The above object is, according to the present invention, installed in a part that receives power and consumes power in a certain phase, and receives a phase detection signal transmitted at a time of zero crossing of a specific phase through power line communication. Receiving unit side power line communication unit; a timer for measuring a time difference between a time point at which the phase detection signal is received and a time point at which the random phase crosses zero; and a phase detection unit that detects which phase the arbitrary phase is by using the measured time difference.

Preferably, the timer measures a time difference between a time point at which the phase detection signal is received and a time point at which zero crossing of the arbitrary phase occurs immediately after the time point at which the phase detection signal is received.

The phase detection unit determines that the random phase is the same phase as the specific phase when the time difference is 0 ± 1 ms, and determines that the arbitrary phase is the previous phase of the specific phase when the time difference is 2.7 ± 1 ms, and the time difference When is 5.4 ± 1 ms, it may be determined that the arbitrary phase is the next phase of the specific phase.

According to another embodiment of the present invention, the power line communication unit is installed on the power supply, and transmits a phase detection signal at the time of zero crossing of a specific phase through power line communication; a power line communication unit installed in a portion that receives power and consumes power in an arbitrary phase, and receives the phase detection signal; a timer for measuring a time difference between a time point at which the phase detection signal is received and a time point at which the random phase crosses zero; and a phase detection unit configured to detect which phase the arbitrary phase is by using the measured time difference.

Preferably, the supply-side power line communication unit transmits the phase detection signal in response to a request from the accommodation-side power line communication unit.

The accommodating unit-side power line communication unit may further include a central server that transmits information about the arbitrary phase detected by the phase detection unit to the supply-side power line communication unit and receives information about the arbitrary phase from the supply-side power line communication unit. have.

According to another embodiment of the present invention, a power phase detection device installed in a portion receiving power and consuming power in an arbitrary phase is performed at the zero crossing point of a specific phase through power line communication from the power line communication unit on the supply side by the power line communication unit on the receiving unit side. a phase detection signal receiving step of receiving the transmitted phase detection signal; a time difference measuring step of measuring, by the power-supply phase detection device, a time difference between a time point at which the phase detection signal is generated and a time point of the zero crossing of the arbitrary phase by a timer; and a phase detection step in which the power-supply phase detection device detects which phase the arbitrary phase is by using the time difference measured by the phase detection unit.

a phase information sending step in which the receiving unit-side power line communication unit transmits information about the arbitrary phase detected in the phase detection step to the supply unit-side communication unit, which proceeds after the phase detection step; and a phase information aggregation step of transmitting the information about the arbitrary phase received by the supply unit-side power line communication unit to a central server.

According to the power phase detection apparatus, system and method according to the present invention, when checking the power phase consumed by the power receiving unit, it is possible to economically perform work without a separate communication means by utilizing power line communication.

In addition, since the phase detection signal is transmitted through the zero-crossing point in the power phase detection process, noise in the signal or signal attenuation can be prevented, thereby increasing the accuracy of the detection result.

1 is a schematic configuration diagram of a power phase detection system according to the present invention;
2 is an explanatory diagram of a method for determining which phase is an arbitrary phase by the phase derivation unit of the power phase detection device according to the present invention;
3 is an explanatory diagram of a power phase detection method according to the present invention.

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

As shown in FIG. 1 , the power phase detection device 1 according to the present invention includes a power line communication unit 10 , a timer 20 and a phase detection unit 30 .

The receiving unit-side power line communication unit 10 is installed in a facility that ultimately consumes power, such as a house. The receiver-side power line communication unit 10 may transmit/receive data to and from the supply-side power line communication unit 2 to be described below through the power line. The receiver-side power line communication unit 10 may be a power line modem built into a power meter installed for an automatic remote meter reading system for power line communication.

The power receiver side consumes power of a random phase (P2) according to the phase of the watt-hour meter among the three phases supplied from the power supply side, and therefore, to balance the power consumption for each phase, it is used on the power receiver side It is necessary to check which phase the power of the random phase P2 is.

In order to check what phase the power used in the receiving unit of power such as a house is, the power line communication unit 2 on the supply side transmits the phase detection signal S at the zero crossing point of the specific phase P1 through power line communication. and the receiving unit-side power line communication unit 10 receives the abnormality detection signal S through power line communication. Even if the specific phase P1 from which the phase detection signal S is transmitted is not the same as the phase P2 of the receiving unit side power line communication unit 10, the supply unit side power line communication unit 2 and the receiving unit side power line communication unit 10 are N ( Neutral) line can be used in common, so power line communication is possible.

The timer 20 is the time when the phase detection signal S is received from the receiving unit side power line communication unit 10, that is, the zero crossing of the specific phase P1 from which the supply unit side power line communication unit 2 has transmitted the phase detection signal S The time difference Δt between the time point ZC1 and the zero-crossing time point ZC2 of the arbitrary phase P2 used at the receiving unit side of the electric power is measured. The timer 20 may be built in the receiving unit side power line communication unit 10 .

The phase detection unit 30 detects which phase the arbitrary phase P2 is by using the time difference Δt measured by the timer 20 . Since the power used at the power receiving unit is supplied from the power supply side, the power of the power line communication unit 2 and the power line communication unit 10 at the receiving unit have the same waveform, and thus the phase detection signal through the measured time difference Δt It is possible to determine which phase the arbitrary phase P2 is by calculating the angle difference between the specific phase P1 and the arbitrary phase P2 to which (S) is transmitted. The phase detection unit 30 may also be built into the receiving unit-side power line communication unit 10 .

As shown in FIG. 2 , the three-phase currents have an interval of 120°. Since each phase has two zero-crossing points per cycle, the zero-crossing points of each phase have an interval of 60°.

Therefore, for example, assuming that the phase detection signal S is transmitted through the A phase, the angle difference between the time point ZC1 at which the phase detection signal S is generated and the zero crossing time point ZC2 of the arbitrary phase P2 is 0° In the case of , the random phase P2 is the same phase as the A phase, and when the angle difference between the time point ZC1 at which the phase detection signal S is generated and the zero crossing time point ZC2 of the random phase P2 is 60°, the random phase If (P2) is phase C, which is the previous phase of phase A, and the angle difference between the time point (ZC1) at which the phase detection signal (S) is generated and the time point (ZC2) of zero crossing of the arbitrary phase (P2) is 120°, the random phase (P2) It can be confirmed that it is the next merchant of this A phase, B phase.

Taking 60 Hz, which is a general frequency of the power supplied to the power receiving unit, as an example, when the time difference Δt measured by the timer 20 is about 0, the time point ZC1 at which the phase detection signal S is generated and the random phase ( Since the angular difference between the zero crossing time point (ZC2) of P2) is 0°, the specific phase (P1) that transmits the phase detection signal (S) and the arbitrary phase (P2) are the same phase, and the measured time difference (Δt) is about 2.7 ms In this case, since the angle difference between the time point (ZC1) at which the phase detection signal (S) is generated and the time point (ZC2) of the zero crossing of the arbitrary phase (P2) is 60°, the arbitrary phase (P2) is the previous phase of the specific phase (P1), and the measurement If the time difference (Δt) is about 5.4 ms, the angle difference between the time point (ZC1) at which the phase detection signal (S) is generated and the time point (ZC2) of the random phase (P2) is 120°, so the random phase (P2) is specified It is the next phase of phase P1.

In consideration of the error, when the measured time difference (Δt) is 0±1 ms, the random phase P2 is the same as the specific phase P1 that transmits the phase detection signal S, and in the case of 2.7±1 ms, the random phase (P2) is the previous phase of the specific phase (P1) that transmits the phase detection signal (S), and in the case of 5.4±1ms, the arbitrary phase (P2) of the specific phase (P1) that transmits the phase detection signal (S) It is desirable to judge the next merchant.

In this way, if the power line communication is used to check the phase of the power consumed by the power receiver, it is economical because a separate communication means is not required to transmit phase-related information between the remotely located power supply side and the power receiver side. In addition, when the phase detection signal S is transmitted at the time of zero crossing, since noise and signal attenuation can be minimized, the accuracy of the phase detection result can be increased.

The timer 20 includes the zero-crossing time ZC2 of the arbitrary phase P2 that occurs immediately after the time ZC1 at which the phase detection signal S is received among the zero-crossing time ZC2 of the arbitrary phase P2. The time difference Δt between the time points at which the phase detection signal S is received is measured.

As shown in FIG. 2, the specific phase (P1) and the arbitrary phase (P2) are zero-crossed at multiple locations, and the random phase (P2) is derived by the time difference (Δt) measured based on which zero-crossing time point. It is possible, but the time difference between the zero-crossing time ZC2 of the arbitrary phase P2 that occurs immediately after the time point ZC1 at which the phase detection signal S is received and the time point at which the phase detection signal S is received ( By measuring Δt), it is possible to more quickly and easily derive which phase the random phase P2 is.

Hereinafter, a power phase detection system according to the present invention will be described.

While describing the power-supply phase detection system according to the present invention, detailed descriptions of the contents mentioned in the description of the power-supply phase detection apparatus 1 of the present invention will be omitted.

As shown in FIG. 1 , the power supply phase detection system according to the present invention includes a power supply-side power line communication unit 2 and a power supply phase detection device 1 .

The supply-side power line communication unit 2 is installed in a facility that serves to reduce high-voltage power, such as a transformer, and supply it to the receiver. The power line communication unit 2 on the supply side can transmit/receive data to and from the power phase detection device 1 through a power line that supplies power rather than a separate communication line, and a three-phase (A) at the power supply side such as a transformer Power line communication is possible through three phases just as power of phase, B, and C) can be supplied.

The power line communication unit 2 on the supply side may be a power line modem constituting a Data Concentration Unit (DCU) installed in a transformer, and the data concentrator may be used to operate a power line communication automatic remote meter reading system. .

The power line communication unit 2 on the supply side transmits the phase detection signal S at the zero crossing point of the specific phase P1 through power line communication.

The power supply phase detection device 1 includes the accommodating part-side power line communication unit 10, the timer 20 and the phase detection unit 30 as described above, and receives the phase detection signal S from the accommodating unit-side power line communication unit 10. Then, the timer 20 measures the time difference Δt between the time point ZC1 at which the phase detection signal S is received and the zero crossing time point ZC2 of the arbitrary phase P2 consumed by the accommodating unit side, and the phase detection unit (30) detects which phase the random phase P2 is by using the measured time difference Δt.

The supply-side power line communication unit 2 transmits the phase detection signal S according to the request from the receiving-side power line communication unit 10, and only when necessary, the supply-side power line communication unit 2 transmits the phase detection signal S. can make this happen.

The detection operation on the power source may be performed when a new watt-hour meter is registered while the power accommodating unit side is newly installed or the watt-hour meter of the power accommodating unit side is exchanged. That is, the phase detection signal S may be transmitted from the power line communication unit 2 on the supply side according to the registration request signal of the modem built into the watt-hour meter.

It is preferable that the request signal from the receiving unit side power line communication unit 10 is made through power line communication.

The receiver-side power line communication unit 10 transmits information about the arbitrary phase P2 detected by the phase detection unit 30 to the supply-side power line communication unit 2, and at this time, the power phase detection system according to the present invention is a central server 3 ) may be further included. The central server 3 receives information about the arbitrary phase P2 from the power line communication unit 2 on the supply side.

The information about the random phase P2 received by the central server 3 may be used to equalize power consumption for each phase. For example, if it is confirmed that the phase of the current used in the accommodating part is the same as the phase in which the load is concentrated in the corresponding area, it is possible to equalize the power consumption by phase by changing the phase of the current used in the accommodating part to another phase.

The receiver-side power line communication unit 10 transmits information about the arbitrary phase P2 at the time of zero crossing through power line communication so that the information on the arbitrary phase P2 is accurately transmitted. The power line communication unit 2 on the supply side may transmit information about the arbitrary phase P2 to the central server 3 through power line communication or general wired/wireless communication.

The central server 3 may be, for example, a server of Korea Electric Power Corporation.

Hereinafter, a power phase detection method according to the present invention will be described.

The power-on detection method according to the present invention proceeds through a detection signal reception step (S20), a time difference measurement step (S30) and a phase detection step (S40), as shown in FIG. 3 .

In the phase detection signal receiving step S20 , the power line communication unit 10 of the receiving unit side of the power phase detection device 1 receives the phase detection signal S. The phase detection signal (S) is transmitted at the zero crossing point of the specific phase (P1) through the power line communication by the power line communication unit (2) on the supply side installed in a part that supplies power, such as a transformer. Since the reception of the phase detection signal S can be achieved through a power line for supplying power, a separate communication line is not required. In addition, when the phase detection signal S is transmitted at the time of zero crossing, it is possible to minimize the occurrence of noise in the signal or attenuation of the signal.

In the time difference measuring step S30 , the power phase detection device 1 generates the phase detection signal S by the timer 20 , the time difference between the time point ZC1 and the zero crossing time point ZC2 of the arbitrary phase P2 . (Δt) is measured, and in the phase detection step S40, the power phase detection device 1 uses the time difference Δt measured in the time difference measurement step S30 by the phase detection unit 30 to determine the random phase P2. Detect which phase it is. Since the power of the supply-side power line communication unit 2 and the receiving-side power line communication unit 10 has the same waveform, a specific phase P1 and an arbitrary phase P2 that transmit the phase detection signal S through the measured time difference Δt It is possible to determine which phase the random phase P2 is by calculating the angular difference.

For example, in the phase detection step (S40), when the power of the supply-side power line communication unit 2 and the receiving-side power line communication unit 10 has a frequency of 60 Hz, the time difference Δt is 0 ± 1 ms. If it is determined that (P2) is the same phase as the specific phase (P1), and the time difference (Δt) is 2.7 ± 1 ms, it is determined that the random phase (P2) is the previous phase of the specific phase (P1), and the time difference (Δt) is In the case of 5.4 ± 1ms, it can be determined that the random phase (P2) is the next phase of the specific phase (P1).

Before the phase detection signal transmitting step (S20), the phase detection signal request step (S10) may be further performed.

In the phase detection signal request step (S10), the receiving unit-side power line communication unit 10 requests transmission of the phase detection signal S through power line communication. Therefore, it is possible to transmit the phase detection signal S from the power line communication unit 2 on the supply side only when a power phase detection operation is required, such as when a new watt-hour meter is installed on the power receiving unit side.

After the phase detection step (S40), the phase information transmission step (S20) and the phase information aggregation step (S20) may be sequentially performed.

In the phase information transmission step (S20), the receiving unit side power line communication unit 10 transmits information about the arbitrary phase P2 detected in the phase detection step (S40) to the supply unit side communication unit, and in the phase information aggregation step (S20) The information about the arbitrary phase P2 received by the supply-side power line communication unit 2 is transmitted to the central server 3 .

The information about the random phase P2 transmitted to the central server 3 may be used to equalize power consumption for each phase based on the load concentration state for each phase in the region.

The scope of the present invention is not limited to the above-described embodiments, but may be implemented in various forms within the scope of the appended claims. Without departing from the gist of the present invention claimed in the claims, it is considered to be within the scope of the claims of the present invention to the extent that various modifications can be made by anyone skilled in the art to which the invention pertains.

1: Power phase detection device
2: Supply side power line communication unit
3: Central Server
10: receiving unit side power line communication unit
20: timer
30: phase detection unit

Claims (8)

a power line communication unit on the receiving unit side that receives power and is installed in a portion that consumes power in a certain phase and receives a phase detection signal transmitted at a time of zero crossing of a specific phase through power line communication;
a timer for measuring a time difference between a time point at which the phase detection signal is received and a time point at which the random phase crosses zero; and
A phase detection unit for detecting which phase the arbitrary phase is by using the measured time difference;
The timer is
and measuring a time difference between a time point at which the phase detection signal is received and a time point at which zero crossing of the arbitrary phase occurs immediately after the time point at which the phase detection signal is received. delete According to claim 1,
The phase detection unit,
If the time difference is 0 ± 1 ms, it is determined that the arbitrary phase is the same phase as the specific phase,
If the time difference is 2.7 ± 1 ms, it is determined that the arbitrary phase is the previous phase of the specific phase,
When the time difference is 5.4 ± 1 ms, it is determined that the random phase is the next phase of the specific phase. a power line communication unit installed in a portion supplying power and transmitting a phase detection signal at a zero crossing point of a specific phase through power line communication;
a power line communication unit installed in a portion that receives power and consumes power in an arbitrary phase, and receives the phase detection signal;
a timer for measuring a time difference between a time point at which the phase detection signal is received and a time point at which the random phase crosses zero; and
and a phase detection unit that detects which phase the arbitrary phase is by using the measured time difference.
The timer is
and measuring a time difference between a time point at which the phase detection signal is received and a time point at which zero crossing of the arbitrary phase occurs immediately after the time point at which the phase detection signal is received. 5. The method of claim 4,
Power phase detection system, characterized in that the supply-side power line communication unit transmits the phase detection signal in response to a request from the accommodating-side power line communication unit. 5. The method of claim 4,
The accommodating unit-side power line communication unit transmits information about the arbitrary phase detected by the phase detection unit to the supply-side power line communication unit,
Power phase detection system, characterized in that it further comprises a central server for receiving the information about the arbitrary phase from the supply-side power line communication unit. Phase detection in which a power phase detection device installed in a part receiving power and consuming power in a certain phase receives a phase detection signal transmitted at the zero crossing point of a specific phase through power line communication from the supply side power line communication unit by the receiving unit side power line communication unit signal receiving step;
a time difference measuring step of measuring, by the power-supply phase detection device, a time difference between a time point at which the phase detection signal is generated and a time point of the zero crossing of the arbitrary phase by a timer; and
a phase detection step in which the power phase detection device detects which phase the arbitrary phase is by using the time difference measured by the phase detection unit;
In the time difference measurement step,
and measuring a time difference between a time point at which the phase detection signal is received and a time point at which zero crossing of the arbitrary phase occurs immediately after the time point at which the phase detection signal is received. 8. The method of claim 7,
which proceeds after the phase detection step,
a phase information transmitting step in which the receiving unit-side power line communication unit transmits information about the arbitrary phase detected in the phase detection step to the supply unit-side communication unit; and
The power phase detection method further comprising a; phase information aggregation step of transmitting the information about the arbitrary phase received by the supply-side power line communication unit to a central server.

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