KR101337384B1 - Communication apparatus and terminal for powerline system, and communication method for the same - Google Patents

Abstract

A method of communicating in a terminal connected to a power line, the method comprising: receiving a request signal by wire or wirelessly; and detecting a phase of a waveform of a power line at a reception point when the request signal is received, wherein the predetermined phase and detection are detected. A communication method is disclosed in which a subsequent process caused by a request signal is performed only when a difference value of a predetermined phase is less than or equal to a predetermined value.

Description

Communication apparatus and terminal for powerline system, and communication method for the same}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to communication devices that can be connected to power lines and communication technology therebetween, and more particularly to techniques that can be used to handle phase information of a plurality of power lines having multiple phases.

Power may be transmitted through a plurality of power lines having different phases. For example, AC power having a frequency of 60 Hz may be transmitted through R, S, and T power lines, that is, three-phase power lines, having a phase difference of 120 ° from each other. In the high voltage transmission path, the R, S, and T phase power lines may extend in parallel. The high voltage power may be converted into medium voltage power or low voltage power by a power converter (transformer or the like). The power consumer may receive one of high voltage power, medium voltage power, and low voltage power, depending on the power level used. All three phase-power lines may be connected to the power consumer, but only one of them, that is, one single-phase power line, may be drawn in. Usually power converters can be installed on power poles or on the ground / underground. In power poles, the power converter converts the high voltage of the three phases of R, S, and T phases into the low voltages of the three phases of R, S, and T phases. There are many cases. At this time, since the R phase, the S phase, and the T phase are names according to the relative phases, when the three-phase low voltage power line is arbitrarily selected, which of the R, S, and T phases the selected low voltage line has? It is not easy to see. The low voltage power line selected for verification should be visually traced back to the power converter. If the number of consumers connected to one of the three phase low voltage power lines is significantly greater than the number of customers connected to the other low voltage power line, the power converter connected to any one of the power lines may fail due to power overload. Therefore, when an arbitrary low voltage power line is selected, it is necessary to easily find out beforehand which phase of the selected low voltage power line corresponds to the R phase, the S phase, and the T phase.

An object of the present invention is to provide a technique for finding out which one of a plurality of phases a power line of any of a plurality of power lines has a plurality of phases. The present invention is not limited to the above-described problems.

In a communication method according to an aspect of the present invention for solving the above problems, the phase of the waveform of the first power line of the plurality of power lines in advance in the terminal connected to any power line of a plurality of power lines having a different phase A communication method for processing a phase-information request signal transmitted at a point in time having a determined value (θ _p ). The method comprises the steps of detecting the phase θ _d of the waveform of any power line above at the point of reception of the phase-information request signal , and the above predetermined value θ _p and the above detection. Determining whether the given phase θ _d satisfies the relationship of equation (1). At this time, the process for generating a response signal to the phase-information request signal is performed only when the above Equation (1) is satisfied.

Equation (1): abs [mod (| θ _p -θ _d |, 360 °)] <α °, wherein α is a predetermined constant.

In this case, the predetermined value θ _p is 0 °, and the detecting may include detecting a zero crossing of a waveform of any power line.

A communication method according to another aspect of the present invention is a method for communicating in a terminal connected to a power line. The method includes receiving the request signal by wire or wirelessly, and detecting the phase θ _d of the waveform of the above power line at the point of reception of the request signal. At this time, the subsequent processing caused by the request signal is performed only when the difference between the predetermined phase θ _p and the detected phase θ _d is less than or equal to the predetermined value.

In this case, the subsequent processing may include transmitting a response signal to the request signal by wireless or wired.

In this case, the response signal may include identification information of the device that transmitted the request signal.

In a communication method according to another aspect of the present invention, in a communication device connected to N power lines having different phases, a phase of a waveform of an arbitrary first power line among the above N power lines is set to a predetermined value θ _p . This is a communication method for processing the phase-information confirmation request signal transmitted at the point of time. This method detects the phase (θ _dk , k is a natural number less than or equal to N) of one or more waveforms of the above N power lines at the time of receiving the phase-information confirmation request signal . Determining a k value that satisfies, and a phase-information confirmation signal including information about the power line corresponding to the determined k value among the N power lines as a response to the phase-information confirmation request signal . Transmitting.

Equation (2): abs [mod (| θ _p -θ _dk |, 360 °)] < α °, wherein α is a predetermined constant.

A communication method according to another aspect of the present invention is a method for communicating in a communication device adapted to be connected to a first power line and a second power line having different phases. The method includes receiving a request signal by wire or wirelessly, receiving a first phase θ _d1 of the waveform of the first power line and receiving the request signal at the time of receiving the request signal. Determining a phase (θ _dk , k = 1 or 2) having a smaller difference value from the predetermined phase θ _p from the second phase θ _d2 of the waveform of the second power line above at the time point, And transmitting information about a power line corresponding to the determined phase θ _dk of the first power line and the second power line, to the apparatus that transmitted the request signal.

In this case, the predetermined phase θ _p is 0 °, and the determining may include detecting a zero crossing of a waveform of one or more power lines of the first power line and the second power line. It may include a step.

According to another aspect of the present invention, there is provided a communication method comprising: a system including a plurality of power lines having different phases, a communication device connected to at least one of the plurality of power lines, and a communication terminal. A communication device communicates with the above communication terminal. The method includes receiving a power line state confirmation request signal from the communication terminal, and applying the power line state confirmation request signal to the plurality of power lines at a time when the phase of the waveform of the first power line has a predetermined value θ _p . phase to one or more terminals connected-information request signal (phase-information request signal) to the above of the steps for transmitting, and one or more terminals of the above-up information relating to sent a response signal to the information request signal to the terminal And transmitting to the communication terminal as status information on the first power line of the apparatus.

In this case, the waveform may be a waveform of a current or a waveform of a voltage.

A terminal according to another aspect of the present invention is a terminal connected to a power line. The terminal includes a communication unit adapted to receive a request signal wirelessly or by wire, a phase detector configured to detect a phase θ _d of the waveform of the power line at the time of reception of the request signal, and a predetermined signal. And a processing unit configured to perform subsequent processing caused by the request signal only when the difference value between the phase θ _p and the detected phase θ _d above is equal to or less than a predetermined value.

In this case, the subsequent processing may include transmitting a response signal to the request signal by wireless or wired.

A communication device according to another aspect of the present invention is a communication device adapted to be connected to a first power line and a second power line having different phases. The communication device includes a communication unit configured to receive a request signal by wire or wirelessly, a phase detection unit configured to detect a phase of the first power line and a phase of the second power line, and a reception that receives the request signal. A predetermined phase among a first phase θ _d1 of the waveform of the first power line at the time point and a second phase θ _d2 of the waveform of the second power line at the time of receiving the request signal received. and a processing section adapted to determine a phase (θ _dk , k = 1 or 2) with a difference value from (θ _p ). In this case, the processing unit is configured to transmit the information about the power line corresponding to the determined phase θ _dk of the first power line and the second power line to the apparatus that has transmitted the request signal.

According to another aspect of the present invention, a communication method includes a plurality of power lines having different phases, a communication device connected to one or more of the plurality of power lines, and one or more terminals connected to the plurality of power lines. In a system comprising a, the communication device is a communication method for communicating with the one or more terminals. In this method, the phase is a predetermined value of a waveform of the first power line of the plurality of power lines of the phase at the time of having a (θ _p) - transmitting the information request signal (phase-information request signal), one of the above or more above one of the terminal-phase signal in response to the information request signal, determining a terminal response signal sent by the information terminal to be connected to a first power line, above.

In this case, one or more of the phase-information request signal or the phase-information response signal may be exchanged through one or more communication channels of a wired communication channel and a wireless communication channel including the plurality of power lines.

At this time, the phase-information response signal is, Of the phase-information includes a response information relating to the instantaneous power of the power suyongga connected to a terminal generates a signal used in the phase-information based on the response signal, used by the power suyongga connected to the first power line above The method may further include calculating a first power line instantaneous power with respect to the total instantaneous power.

According to another aspect of the present invention, a communication method includes a plurality of power lines having different phases, a communication device connected to one or more of the plurality of power lines, and one or more terminals connected to the plurality of power lines. In the system comprising a communication terminal is a method for communicating with the communication device. The method includes transmitting a power line state confirmation request signal to the communication device, and receiving a power line state confirmation signal for a first power line of the plurality of power lines from the communication device. At this time, the power line state confirmation signal for the first power line , the communication device, the phase at the time when the phase of the waveform of the first power line has a predetermined value (θ _p ) to the one or more terminals of the above- after transmitting the information request signal, the above-receiving the response signal to the information request signal, is generated from the information about the response signal is sent to the above device.

According to another aspect of the present invention, a communication method includes N power lines having different phases, a communication device connected to the above N power lines, and one or more terminals connected to the N power lines. In a system, any one of the above one or more terminals is a method of communicating with the communication device. The method includes transmitting a phase-information confirmation request signal to the communication device, and from the communication device, information on which of the N power lines is the power line to which any terminal is connected. Receiving a phase-information confirmation signal . At this time, the phase-information confirmation signal of the phase, the phase of the waveform of one or more of the power line of the above N power lines at the point of reception when the communication device receives the phase-information confirmation request signal (θ _dk , k Is a natural number less than or equal to N), and is determined by determining a k value satisfying the relationship of Equation (2) above.

A terminal according to another aspect of the present invention is a terminal connected to any power line among a plurality of power lines having different phases. The terminal comprises a communication unit configured to receive a phase-information request signal transmitted at a point in time at which a phase of a waveform of the first power line has a predetermined value θ _p , among the plurality of power lines above, the phase-information request signal above. Is a phase detector configured to detect the phase θ _d of the waveform of any of the power lines above, and the predetermined value θ _p above and the detected phase θ _d above And a processing unit for determining not to satisfy the relationship in (1). At this time, the processing unit is to perform the subsequent processing caused by the phase-information request signal only when the above equation (1) is satisfied.

A communication apparatus according to another aspect of the present invention may be connected to N power lines having different phases. The communication apparatus, the phase of the waveform of the first power lines any of the N number of power line above a predetermined value (θ _p) onto the transmission at the time of having the - communication unit adapted to receive information check request signal, and the above The phase (θ _dk , k is a natural number less than or equal to N) of one or more power lines among the N power lines at the time of receiving the phase-information confirmation request signal , is detected. And a processing unit for determining a satisfying k value. In this case, the processing unit is configured to transmit a phase-information confirmation signal including information on the power line corresponding to the determined k value among the N power lines as a response to the phase-information confirmation request signal . .

A communication apparatus according to another aspect of the present invention is a system comprising a plurality of power lines having different phases, and at least one terminal connected to the plurality of power lines, wherein one of the plurality of power lines above A communication device connected to the above and communicating with one or more terminals. The communication device includes a communication unit, and a plurality of power lines of the phases is a predetermined value of a waveform of the first power line above (θ _p) allows the above communication unit at the time of phase with the - information request signal (phase-information request signal) It includes a processing unit configured to transmit the. In this case, the processing unit is configured to determine that the terminal which has transmitted the phase-information response signal , which is a response signal to the phase-information request signal , among the one or more terminals, to be the terminal connected to the first power line.

A communication apparatus according to another aspect of the present invention is a system comprising a plurality of power lines having different phases, and one or more terminals connected to the plurality of power lines, wherein the communication device communicates with the communication terminal and A communication device connected to one or more of a plurality of power lines. The communication apparatus includes a communication unit configured to receive a power line state confirmation request signal from the above communication terminal, and a phase of the waveform of the first power line among the plurality of power lines described above at a time point having a predetermined value θ _p . cause the communication unit a - and a processing unit adapted to transmit the information request signal (phase-information request signal) to one or more terminals of the above. In this case, the processing unit is configured to transmit the information about the terminal that has sent the response signal to the phase-information request signal among the one or more terminals to the communication terminal as the status information on the first power line. have.

According to another aspect of the present invention, a communication terminal includes a plurality of power lines having different phases, a communication device connected to one or more of the plurality of power lines, and one or more terminals connected to the plurality of power lines. In the system comprising a communication terminal for communicating with the above communication device. The communication terminal includes a communication unit and a processing unit for causing the communication unit to transmit a power line state confirmation request signal to the communication apparatus. In this case, the processing of the above, is configured to receive a power-line status checking signal to a first power line of the plurality of power lines above from the communication apparatus of the above, make the power line status signal to a first power line of the above, the communication apparatus of the above A. After the phase -information request signal is transmitted to the one or more terminals at the time when the phase of the waveform of the first power line has a predetermined value θ _p , the response signal to the phase-information request signal receiving the information response signal, the above--in phase is generated from the information on the terminal information sent to the response signal.

A terminal according to another aspect of the present invention, a system comprising N power lines having different phases, a communication device connected to the above N power lines, and one or more terminals connected to the N power lines above. In one or more of the above terminal is a terminal for communicating with the communication device. The terminal includes a communication unit, and a processing unit for causing the communication unit to transmit an image-information confirmation request signal to the communication apparatus. In this case, the processing unit is configured to receive a phase-information confirmation signal including information on which of the N power lines the power line to which any of the above terminals are connected is connected to the above communication device . -The information confirmation signal is a phase (θ _dk , k is a natural number less than or equal to N of the power lines of the above N power lines at the point of time when the communication apparatus receives the phase-information confirmation request signal . ) Is generated by determining a value of k that satisfies the relationship of Equation (2) above.

According to the present invention, it is possible to provide a technique for finding out which of the plurality of phases any of the power lines of any of the plurality of power lines having a plurality of phases has. The present invention is not limited by the above effects.

1 shows an example of a configuration of a power line communication system according to an embodiment of the present invention.
Figure 2 shows the relative phase of the three-phase power line, in order to explain the communication method according to an embodiment of the present invention.
3 and 4 illustrate a method of identifying a phase of a power line according to an embodiment of the present invention.
5 is a zero-crossing detection circuit in accordance with an embodiment of the present invention.
6 is a flowchart illustrating a method of identifying an image of a power line according to an embodiment of the present invention.
7 illustrates a communication method according to an embodiment of the present invention.
8 illustrates a communication method according to another embodiment of the present invention.
9 shows a configuration of a terminal according to an embodiment of the present invention.
10 shows a configuration of a communication terminal according to an embodiment of the present invention.
11 shows a configuration of a communication device according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. Also, the singular forms as used below include plural forms unless the phrases expressly have the opposite meaning.

1 is a block diagram of a power line communication system according to an embodiment of the present invention.

Referring to FIG. 1, the high voltage power transmitted through the high voltage power line 40 may be converted into low voltage power of three phases having different phases through a transformer (power converter) 30 installed in the power pole 20. have. The low voltage power of the three phases may be delivered to the customer through the R phase power line 10R, the S phase power line 10S, and the T phase power line 10T, respectively. The R phase power line 10R is connected to the customers HR1 and HR2, the S phase power line 10S is connected to the customers HS1 and HS2, and the T phase power line 10T is connected to the customers HT1 to H2. HT99).

On the other hand, the communication device 100 through the R-phase terminal (DTR), S-phase terminal (DTS), and T-phase terminal (DTT), respectively R-phase power line (10R), S-phase power line (10S) , And T phase-power lines 10R. The communication device 100 may include a coupling device described in Korean Patent Registration No. 10-1052206 (2011.07.21) and / or an interface device described in Korean Patent Publication No. 10-2011-0038922 (2011.04.15). have. The contents of the above-mentioned Korea Patent Registration 10-1052206 (2011.07.21) and Korea Patent Publication 10-2011-0038922 (2011.04.15) are incorporated herein by reference. The communication device 100 may be configured to communicate through a wired communication channel and / or a wireless communication channel including a power line.

Each customer is provided with a terminal. Among them, the terminals TR1 and TR2 are connected to the consumers HR1 and HR2, the terminals TS1 and TS2 are connected to the consumers HS1 and HS2, and the terminals TT1 to TT99 are connected to the consumers HT1 to HT99. Can be connected. Hereinafter, the terminals TR1, TR2, TS1, TS2, and TT1 to TT99 may be collectively referred to as the terminal 200. The terminal 200 may be configured to communicate via a wired communication channel and / or a wireless communication channel including a power line.

In the configuration example shown in FIG. 1, two customers are connected to each of the R-phase power line 10R and the S-phase power line 10S. However, 99 customers are connected to the T-phase power line 10T. Therefore, a large amount of power may be distributed through the T-phase power line 10T, and thus, a portion of the transformer 30 connected to the T-phase power line 10T may be damaged due to overload. In this situation, if you want to connect the new customer (NH) to the transformer 30, it is preferable to connect to any one of the R-phase power line (10R) and S-phase power line (10S) except for the T-phase power line (10T). something to do. By the way, in the low voltage power line extending from the transformer 30, it may not be noted which phase the power line has this power line. Therefore, there is a problem that it is not possible to know which phase power line is any power line selected to connect the power line to the customer NH. The idea of the present invention for solving this problem will be described below with reference to the drawings.

Figure 2 shows the relative phase of the three-phase power line in order to explain the communication method according to an embodiment of the present invention.

FIG. 2A shows a waveform WR of a current flowing through the R-phase power line 10R connected to the R-terminal DTR of the terminals TR1 and TR2 and the communication device 100. 2B shows a waveform WS of current flowing through the S-phase power line 10S connected to the S-phase terminals DTS of the terminals TS1 and TS2 and the communication device 100. 2C shows a waveform WT of a current flowing through the T-phase power line 10T connected to the T-phase terminal DTT of the terminals TT1 to TT99 and the communication device 100. In this graph, the horizontal axis represents time and the vertical axis represents the magnitude of the waveform. The graph of FIG. 2 may show a waveform of a current as described above, or alternatively, may show a waveform of a voltage. The waveform WR of the R-phase power line 10R and the waveform WS of the S-phase power line 10S have a phase difference of + 120 °. Further, the waveform WR of the R-phase power line 10R and the waveform WT of the T-phase power line 10T have a phase difference of + 240 °.

The point in time t1 and the point in time t4 shown in FIG. 2 (d) are points in time when the phase θ _R of the waveform WR becomes 0 °, and in point in time t2, the phase θ _s of the waveform WS is 0 °. The time point t3 represents a time point at which the phase θ _T of the waveform WT becomes 0 °. In this case, the terminal 200 or the communication device 100 'connected' to the three-phase power line may transmit the communication signal 50 to an arbitrary time point, for example, a time point t1. The communication signal 50 may be transmitted through a wireless or wired channel, and the wired channel may be a power line or a separate wired communication channel such as a BNC cable. Here, 'connected' may mean that at least the phase information of the current or voltage flowing through the power line is known. For example, when the communication channel is wired, the radio wave flowing through the wired line may be detected by the RF method by being directly contacted with the wired line or arranged close to the wired line. In addition, for example, the communication signal 50 may be transmitted wirelessly. For this purpose, the terminal 200 and the communication device 100 may include a wireless communication module. That is, it is only necessary to know the phase information of the current or voltage flowing through the power line using any technical method.

The communication signal 50 reaches the time point t1 + ΔT at the device connected to the three-phase power line. ΔT (not shown) is a propagation delay time of the communication signal 50. In general, AC power has a frequency of 50 Hz or 60 Hz. In the case of a frequency of 60 Hz, one cycle is 1/60 (sec) and has a value of about 16.7 msec. Since one period corresponds to a phase angle of 360 °, the phase difference of 120 ° corresponds to a time difference of about 5.6 msec. Therefore, in the case of having a frequency of 60 Hz, the time point t1 and the time point t2 in FIG. 2D have a difference value of about 5.6 msec. In comparison, when the communication signal 50 is an electromagnetic wave, the ΔT value becomes a negligible value which is much smaller than 5.6 msec. In other words, the communication signal 50 can be immediately received at the time at which it was actually transmitted.

In some embodiments, the communication signal 50 may be transmitted through a power line channel. In this case, when the R-phase power line 10R, the S-phase power line 10S, and the T-phase power line 10T are Y-connected or Δ-connected, the three power lines are connected to each other. The communication signal 50 transmitted from the power line 10R can be transmitted not only to the R-phase power line 10R but also to a device connected to the S-phase power line 10S and the T-phase power line 10T. In another embodiment, the communication signal 50 may be transmitted through a wireless channel.

3 and 4 illustrate a method of identifying a phase of a power line according to an embodiment of the present invention.

1 to 4, in step S301, the communication device 100 includes a power line of any one of an R-phase power line 10R, an S-phase power line 10S, and a T-phase power line 10T. A phase-information request signal 55, which is a kind of communication signal 50, is transmitted to a time point t5 in which the phase of the waveform has a predetermined value θ _p . An example in which the power line 10R is selected and the phase -information request signal 55 is transmitted at a time point t5 in which the phase θ _R of the R-phase power line 10R has a predetermined value θ _p . The ' phase-information request signal ' 55 may be received by the terminals 200 described with reference to FIG. 1.

In a next step S302, the terminal 200 receives a phase-information request signal 55, respectively, at a time t5 + Δt ≒ t5, and the phase θ _d of the waveform of the power line connected thereto. Is detected. At this time, the "phase-information request signal (55) a point in time (t5) is" phase-information request signal, receiving it is possible to know only after receiving (55), each terminal 200 is the time (t5 ) You should continue to detect the phase of the waveform of the power line connected to it beforehand. However, this method can waste the resources of the device. Therefore, according to the exemplary embodiment, it is possible to use the fact that the phase θ _d at the time point t5 and the phase at the time point t6 which is one cycle later are the same. For example, when the power frequency is 60 Hz, each terminal 200 detects the phase of the waveform of the power line connected to itself at a time point t6 after one period (= 1/60 sec) has elapsed from the time point t5. can do. In this way, each terminal 200 may detect a value corresponding to the phase θ _d at the time point t5 of the waveform of the power line connected thereto.

In the next step S303, each terminal 200 determines whether the predetermined value θ _p and the detected phase θ _d above satisfy Equation 1. [Equation 1] is an equation for determining whether the waveform of the power line connected to the ' phase-information request signal ' 55 and the terminal 200 receiving it is synchronized. In this case, each terminal 200 may store a predetermined value θ _p . To this end, the terminal 200 and the communication device 100 may share a predetermined value θ _p . At this time, they may be previously stored together in the memory of each device or shared by transferring or exchanging this value through communication.

[Equation 1]

abs [mod (| θ _p -θ _d |, 360 °)] <α °

Where α is a predetermined constant, abs [x]: absolute value of x, and mod (m, n) is the remaining value when m is divided by n.

In Equation 1, since the α value is an object of optimization, the present invention is not limited by this specific value of α. If Equation 1 is satisfied, the terminal 200 receiving the ' phase-information request signal ' 55 may be regarded as being connected to a power line having the same phase as the communication device 100. In this case, the terminal 200 may perform a subsequent procedure. The subsequent procedure is a predetermined procedure, and may include a procedure of transmitting a ' phase-information response signal ' to the communication device 100 indicating that the ' phase-information request signal ' 55 has been received. In this case, the ' phase-information response signal ' may include identification information of each terminal 200.

Hereinafter, the above-described steps S301 to S303 will be described with specific examples. Referring to FIG 1 to 3, the communication device 100 includes a R-phase - the predetermined value, the phase (θ _R) of the waveform of the power line (10R) (θ _p), the "on time (t5) having a - The information request signal '55 is transmitted. Then, the terminals TR1, TS1, and TT1 each have a phase θ _R1 , θ _S1 , θ _T1 of the waveform of the power line connected thereto at the time t5 when the phase-information request signal 55 is received. ). In this case, θ _p = 45 °, θ _R1 = 45 ° θ _S1 = 285 °, and θ _T1 = 165 °. At this time, if the value of α in [Equation 1] is set to 60, for example, the terminal TR1 satisfies [Equation 1] (see [Equation 2]), but in the terminal TS1, [Equation 1] Does not satisfy (see Equation 3), and the terminal TT1 does not satisfy Equation 1 (see Equation 4). Therefore, only the terminal TR1 transmits the ' phase-information response signal ' to the communication device 100. Since the arrival time of the ' phase-information request signal ' 55 is very short, the present invention can achieve the object even if the value of α is set to a number very smaller than 60.

&Quot; (2) &quot;

abs [mod (| θ _p -θ _d |, 360 °)]

= abs [mod (| θ _p -θ _R1 |, 360 °)]

= abs [mod (| 45˚- 45˚ |, 360˚)] = 0˚ <60˚

&Quot; (3) &quot;

abs [mod (| θ _p -θ _d |, 360 °)]

= abs [mod (| θ _p -θ _S1 |, 360 °)]

= abs [mod (| 45˚-285˚ |, 360˚)] = 240˚> 60˚

&Quot; (4) &quot;

abs [mod (| θ _p -θ _d |, 360 °)]

= abs [mod (| θ _p -θ _T1 |, 360 °)]

= abs [mod (| 45˚- 165˚ |, 360˚)] = 120˚> 60˚

As such, the communication device 100 transmits the ' phase-information request signal ' 55 at the time point t5 in which the phase θ _R of the waveform of the R phase-power line 10R has a predetermined value θ _p . In this case, only the terminals TR1 and TR2 connected to the R-phase power line 10R send a ' phase-information response signal '. That is, when the communication device 100 has a phase θ _X of the waveform of the X- phase power line 10R ( X = R, S, T) having a predetermined value θ _p , the ' phase-information request signal ' When transmitting 55, only terminals connected to the X- phase power line 10 X send a ' phase-information response signal '. As described above, the ' phase-information response signal ' may include identification information of each terminal. Accordingly, the communication device 100 may know which terminal is connected to which phase through steps S301 to S303, and thus, how many terminals are connected to the power line of each phase. have.

In the above embodiment were set to θ _p = 45˚, θ _p can be set to, for example 0˚, 90˚, 180˚, 270˚.

Meanwhile, the communication device 100 and the terminal 200 may detect zero-crossing of the waveform of the power line connected to each other, and measure the phase of the waveform of the power line connected thereto by using the zero-crossing. That is, it is readily understood that the time interval between the zero-crossing point and any point in time can be used to determine the phase of the powerline waveform at any point in the above point.

5 is a zero-crossing detection circuit according to an embodiment of the present invention.

Referring to FIG. 5A, Vin 101 is an input signal from a power line for measuring a phase. Vin 101 has a sinusoidal waveform as shown in FIG. 5 (b). In the light emitting diode 103, only when Vin 101 has a positive value or when the threshold having a positive value is exceeded. Only emits light. The output voltage Vo 106 may be generated by the optical switch 104 operating by light emitted from the light emitting diode 103. The rising-edge or falling-edge of the output voltage 106 may be defined as a zero-crossing point.

The method of determining the phase of the power line waveform by using the zero-crossing described above is an example to assist in understanding the present invention, and the phase of the power line waveform can be determined by various other methods. In addition, the zero-crossing detection circuit described in FIG. 5 is merely an example, and other circuits may be used.

6 is a flowchart illustrating a method of identifying an image of a power line according to an embodiment of the present invention.

This embodiment may be used when the terminal 200 connected to the R-phase power line 10R of the three-phase power line inquires the communication device 100 of the phase of the power line to which it is connected. At this time, the terminal 200 does not know before inquiring that it is connected to the R-phase power line 10R.

Referring to FIGS. 3 and 6, in step S601, the terminal 200 transmits a ' phase-information confirmation request signal ' 55 that inquires about a phase of a power line to which it is connected. The phase of the waveform WR of the power line 10R to which it is connected is transmitted to the communication device 100 at a time point t5 having a predetermined value θ _p . In this case, the ' phase-information confirmation request signal ' 55 may include identification information of the terminal 200.

In a next step S602, the communication device 100 performs the phase of the waveform of the R phase-power line 10R at the reception time t5 + Δt when the ' phase-information confirmation request signal ' 55 is received. One or more of θ _d1 ), the phase θ _d2 of the waveform of the S-phase power line 10S, and the phase θ _d3 of the waveform of the T-phase power line 10T are detected.

In the next step S603, one of the phase θ _d1 , the phase θ _d2 , and the phase θ _d3 is found to satisfy the relation of Equation (5). In other words, the k value satisfying Equation 5 is found.

&Quot; (5) &quot;

abs [mod (| θ _p -θ _dk |, 360 °)] <α °, where α is a predetermined constant.

Where α is a predetermined constant, abs [x]: the absolute value of x, mod (m, n) is the remaining value when m is divided by n, and k is a natural number less than or equal to N.

In this embodiment, for example, α = 60 can be determined. At this time, since the terminal 200 is connected to the R-phase power line 10R, the R-phase power line 10R of the R-phase power line 10R at the reception point t5 + Δt receiving the ' phase-information confirmation request signal ' 55 is received. The phase θ _d1 of the waveform satisfies [Equation 5]. On the other hand, the phase θ _d2 and the phase θ _d3 do not satisfy Equation 5.

Step S603 may be performed after measuring phase θ _d1 , phase θ _d2 , and phase θ _d3 , but phase θ _d1 , phase θ _d2 , and phase θ _d3 ) may be performed separately immediately after each sequential measurement. Therefore, when the phase θ _d1 is measured first among the three phases above, a k value (k = 1) satisfying Equation 5 may be determined without measuring the other two phases. On the other hand, if the phase (θ _d1 ) of the above three phases is measured for the second time, the k value (k = 1) that satisfies [Equation 5] without determining the other remaining phase is determined. Can be.

In a next step S604, the communication device 100 uses the above-described identification information sent from the terminal 200, and the R-phase power line 10R, which is a power line corresponding to the determined k value (k = 1). ), The ' phase-information confirmation signal ' including the information on the information may be sent to the terminal 200 as a response to the ' phase-information confirmation request signal ' 55. In this case, the ' phase-information confirmation signal ' may include, for example, the number and / or identification information of other terminals connected to the R-phase power line 10R. In order to prepare such information, the communication apparatus 100 has previously performed the operation described with reference to FIG. 4 before receiving the ' phase-information confirmation request signal ' 55 or ' phase-information confirmation request signal ' ( It may also be performed after receiving 55).

7 illustrates a communication method according to an embodiment of the present invention.

In operation S701, the communication device 100 detects a time point t5 in which a phase of a waveform of a first power line has a predetermined value θ _p among a plurality of power lines connected to the communication device 100.

In step S702, the communication device 100 transmits the above-mentioned ' image-information request signal ' 55 to the one or more terminals 200 immediately after the detection time t5. At this time, only terminals connected to the first power line among the terminals 200 will return the above-mentioned ' phase-information response signal ' according to the algorithm described in FIG. 4.

In operation S703, the communication apparatus 100 may determine that only terminals returned the ' phase-information response signal ' are terminals connected to the first power line.

When the above steps S701 to S703 are repeated for the R-phase power line 10R, the S-phase power line 10S and the T-phase power line 10T, the communication device 100 performs the R-phase power line 10R. It can be understood that the terminals connected to the S-phase power line 10S and the T-phase power line 10T can all be distinguished.

8 illustrates a communication method according to another embodiment of the present invention.

3 and 8, in step S801, the communication terminal 300 may transmit a power line state confirmation request signal to the communication device 100. In this case, the communication terminal 300 may be one of the terminals 200 connected to or to be connected to the power line, or may be a wired / wireless communication terminal separate from the terminal 200.

In step S802, the communication device 100 transmits the ' phase-information request signal ' 55 to the terminals 200 connected to the R-phase, S-phase, and T-phase waveforms of the R-power line 10R. ) Is transmitted at a time point t10 having a predetermined value θ _p . Then, only the terminal connected to the R-phase power line 10R may return the ' phase-information response signal '. Then, in step S803, the communication device 100 may determine the terminals 200 returning the ' phase-information response signal ' as terminals connected to the R-phase power line 10R. This process can be similarly performed for the S-phase power line 10S and the T-phase power line 10T (steps S804 to S807). When step S807 is finished, the communication device 100 may distinguish all of the terminals 200 connected to the R phase, the S phase, and the T phase.

In step S808, the communication device 100 transmits information about a terminal that has sent a response signal to the ' phase-information request signal ' 55 transmitted in steps S802, S804, and S806. , The R-phase power line 10R, the S-phase power line 10S, and the T-phase power line 10T may be transmitted to the communication terminal 300, respectively. For example, the information about the terminal may be identification information or the number of the terminal.

Unlike the example shown in FIG. 8, the above-described steps S802 to S807 may be performed before the step S801.

9 shows a configuration of a terminal according to an embodiment of the present invention.

Referring to FIG. 9, the terminal 200 may include a communication unit 210, a phase detector 220, and a processor 230. The communication unit 210 may receive, for example, an ' phase-information request signal ' 55 transmitted in step S301 of FIG. 4. The phase detection unit 220 may have a structure shown in FIG. 5A, and may include a waveform of a power line connected to itself at an arbitrary time point including a reception point at which the ' phase-information request signal ' 55 is received. The phase θ _d can be detected. When the predetermined value θ _p stored in the terminal 200 and the detected phase θ _d satisfy the Equation 1, the processor 230 may perform the above phase-information request signal 55. Follow-up processing caused by). This subsequent processing may include, for example, transmitting a ' phase-information response signal ' responsive to the ' phase-information request signal ' 55.

In the modified embodiment of FIG. 9, the processing unit 230 of the terminal 200 may cause the communication unit 210 to transmit the ' phase-information confirmation request signal ' to the communication device 100 as shown in FIG. 6. In addition, the processor 230, from the communication apparatus 100, transmits an ' phase-information confirmation signal ' including information on which power line among the N power lines connected to the communication apparatus 100 is a power line to which the terminal 200 is connected. Can be received.

10 shows a configuration of a communication terminal according to an embodiment of the present invention.

8 and 10, the communication terminal 300 may include a communication unit 310 and a processing unit 330. In this case, the processor 330 may cause the communicator 330 to transmit a power line state confirmation request signal to the communication device 100 (S801). In addition, the communication unit 310 and the processing unit 330 are configured to receive a ' power line state confirmation signal ' for the first power line among the plurality of power lines connected to the communication device 100 from the communication device 100.

11 shows a configuration of a communication device according to an embodiment of the present invention.

6 and 11, the communication device 100 may include a communication unit 110, a phase detector 120, and a processor 130. The communication device 100 may be connected to N power lines having different phases. The communicator 110 may be configured to receive a ' phase-information confirmation request signal ' transmitted at a time when a phase of a waveform of an arbitrary first power line among the N power lines has a predetermined value θ _p . The ' phase-information confirmation request signal ' may be transmitted by the terminal 200. The processor 130 detects the phase (θ _dk , k is a natural number less than or equal to N) of one or more power lines among the N power lines at the time of receiving the ' phase-information confirmation request signal ' [Equation 2] We can determine the k value that satisfies the relationship of. In addition, the processor 130, which includes information about the power line corresponding to the k value determined above, of the N power line transmission in response to a - "Information request signal a 'to' the information confirmation signal" above This can be done (step S604).

In a modified embodiment of the communication apparatus according to FIG. 11, the processor 130 of the communication apparatus 100 may determine a phase θ _p of a waveform of a first power line among a plurality of power lines connected to the communication apparatus 100. The communication unit 110 may transmit the ' phase-information request signal ' at a point in time (see step S702 of FIG. 7). In addition, the processor 130 is a terminal connected to the first power line a terminal that has sent a ' phase-information response signal ' which is a response signal to the ' phase-information request signal ' among one or more terminals connected to the plurality of power lines. It may be determined to be (see step S703 of FIG. 7).

In another modified embodiment of the communication apparatus according to FIG. 11, the communication unit 110 of the communication apparatus 100 is configured to receive a ' power line state confirmation request signal ' from the communication terminal 300 (step of FIG. 8 ( S801). In addition, the processor 130 is configured to transmit the ' phase-information request signal ' to the communication unit 110 when the phase of the waveform of the first power line has a predetermined value θ _p among the plurality of power lines. In addition, the processor 130 may transmit information regarding the terminal that has sent the ' phase-information response signal ', which is a response signal to the ' phase-information request signal ', among the one or more terminals connected to the plurality of power lines, to the first power line. It is to transmit to the communication terminal 300 as the status information for.

A communication method according to another embodiment of the present invention will be described with reference to FIG. This communication method may be a method of communicating in the terminal 200 connected to the power line. The method includes receiving the request signal by wire or wirelessly. In this case, the request signal may be the ' phase-information request signal ' described above. Thereafter, detecting the phase θ _d of the waveform of the power line at the time of receiving the request signal. In this case, the subsequent processing may be performed by the request signal only when the difference between the predetermined phase θ _p and the detected phase θ _d is less than or equal to the predetermined value. Here, the 'predetermined value' may correspond to α in [Equation 1] or [Equation 5].

A communication method according to another embodiment of the present invention will be described with reference to FIG. This method is a communication method in a communication device adapted to be connected to a first power line and a second power line having different phases. The first power line and the second power line may be any one of the three-phase power lines described above. The method may include receiving the request signal by wire or wirelessly. Here, the request signal may be the ' phase-information confirmation request signal ' described above. Next, a first phase θ _d1 of the waveform of the first power line at the reception point of receiving the request signal and a second phase θ of the waveform of the second power line at the reception point of receiving the request signal. _d2 ), determining a phase θ _dk , k = 1 or 2 with a smaller difference value from the predetermined phase θ _p . For this determination, the above-described relationship of Equation 5 may be used, but is not limited to this method. Thereafter, the method may include transmitting information about a power line corresponding to the determined phase θ _dk of the first power line and the second power line to a device that has transmitted the request signal.

The communication terminal 300 mentioned in the present specification may have the same structure as the terminal 200, but it may not be depending on the embodiment.

The amount of power flowing through the power line used in the present invention is not limited.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will readily occur to those skilled in the art without departing from the spirit and scope of the invention. The contents of each claim in the claims may be combined with other claims without departing from the scope of the claims.

Therefore, it should be understood that the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense, and that the true scope of the invention is indicated by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof, .

Claims (16)

In a terminal connected to an arbitrary power line among a plurality of power lines having different phases, another terminal connected to the plurality of power lines when a phase of a waveform of a first power line among the plurality of power lines has a predetermined value θ _p . A communication method for processing a phase-information request signal transmitted through
Detecting a phase θ _d of the waveform of the arbitrary power line at the time of receipt of the phase-information request signal ; And
Determining whether the predetermined value θ _p and the detected phase θ _d satisfy a relationship of equation (1)
Including;
Only when the equation (1) is satisfied, a process for generating a response signal to the phase-information request signal is performed.
Communication method.
Equation (1): abs [mod (| θ _p -θ _d |, 360 °)] <α °, wherein α is a predetermined constant. The method of claim 1, wherein the predetermined value θ _p is 0 ° and the detecting step comprises detecting a zero crossing of a waveform of the power line. A method of communicating in a terminal connected to a power line,
Receiving a request signal transmitted through another terminal connected to the power line by wire or wirelessly; And
Detecting a phase θ _d of the waveform of the power line at the time of receiving the request signal.
Including;
It is arranged to perform subsequent processing caused by the request signal only if a difference value between a predetermined phase θ _p and the detected phase θ _d is less than or equal to a predetermined value.
Communication method. 4. The method of claim 3, wherein the subsequent processing comprises transmitting a response signal to the other terminal, wirelessly or by wire, to the other terminal. The communication method according to claim 4, wherein the response signal includes identification information of a device that has transmitted the request signal. In a communication device connected to N power lines having different phases, another communication device connected to the N power lines when a phase of a waveform of any first power line among the N power lines has a predetermined value θ _p . A communication method for processing a phase-information confirmation request signal transmitted through
Detects the phase (θ _dk , k is a natural number less than or equal to N) of one or more waveforms of the N power lines at the time of receiving the phase-information confirmation request signal, and obtains a k value satisfying the relationship of Equation (2). Determining; And
Transmitting, to the other communication device, a phase-information confirmation signal including information on a powerline corresponding to the determined k value among the N power lines as a response to the phase-information confirmation request signal .
/ RTI &gt;
Communication method.
Equation (2): abs [mod (| θ _p -θ _dk |, 360 °)] &lt; α °, wherein α is a predetermined constant. A method of communicating in a communication device adapted to be connected to a first power line and a second power line having different phases,
Receiving the request signal by wire or wirelessly;
A first phase θ _d1 of the waveform of the first power line at the time of receiving the request signal and a second phase θ _d2 of the waveform of the second power line at the time of receiving the request signal. Determining a phase θ _dk , k = 1 or 2 with a smaller difference value from the predetermined phase θ _p ; And
Transmitting information about a power line corresponding to the determined phase θ _dk of the first power line and the second power line to a device that has transmitted the request signal.
Including, communication method. The method of claim 7, wherein the predetermined phase θ _p is 0 °, and the determining comprises: detecting a zero crossing of a waveform of one or more power lines of the first power line and the second power line. Comprising the steps of: communication method. A system comprising a plurality of power lines having different phases, a communication device connected to at least one of the plurality of power lines, and a communication terminal, wherein the communication device communicates with the communication terminal, comprising:
Receiving a power line state confirmation request signal from the communication terminal;
The point having a predetermined value (θ _p) phase of the waveform of the first power line of the plurality of power lines to one or more terminals connected to the plurality of power-line phase-information for transmitting a request signal (phase-information request signal) step; And
Transmitting, to the communication terminal, information about a terminal from which the response signal to the phase-information request signal of the one or more terminals is sent as status information on the first power line;
Communication method. The method of claim 9, wherein the waveform is a waveform of current or a waveform of voltage. A terminal connected to a power line,
A communication unit configured to receive a request signal wirelessly or by wire;
A phase detector configured to detect a phase θ _d of the waveform of the power line at the time of reception of the request signal; And
A processing unit configured to perform subsequent processing caused by the request signal only when a difference between a predetermined phase θ _p and the detected phase θ _d is less than or equal to a predetermined value
. 12. The terminal of claim 11, wherein the subsequent processing comprises transmitting a response signal to the request signal by wire or wirelessly. A communication device adapted to be connected to a first power line and a second power line having different phases,
A communication unit configured to receive the request signal by wire or wirelessly;
A phase detector configured to detect a phase of the first power line and a phase of the second power line; And
A first phase θ _d1 of the waveform of the first power line at the time of receiving the request signal and a second phase θ _d2 of the waveform of the second power line at the time of receiving the request signal. , A processor configured to determine a phase (θ _dk , k = 1 or 2) having a smaller difference value from the predetermined phase (θ _p )
Including;
The processing unit is configured to transmit information about a power line corresponding to the determined phase θ _dk of the first power line and the second power line to a device that has transmitted the request signal.
Communication device. A system comprising a plurality of power lines having different phases, a communication device connected to one or more of the plurality of power lines, and one or more terminals connected to the plurality of power lines, wherein the communication device is the one or more devices. A communication method for communicating with a terminal,
Transmitting the information request signal (phase-information request signal) - in a point having a predetermined value (θ _p) phase of the waveform of the first power line of the plurality of power lines;
Determining, from among the one or more terminals, a terminal that has sent a phase-information response signal , which is a response signal to the phase-information request signal , to be a terminal connected to the first power line;
/ RTI &gt;
Communication method. The communication method according to claim 14, wherein at least one of the phase-information request signal or the phase-information response signal is exchanged through at least one communication channel of a wired communication channel and a wireless communication channel including the plurality of power lines. . 15. The method of claim 14,
The phase-information response signal is Includes information on the instantaneous power used by the power consumer connected to the terminal generating the phase-information response signal ,
Calculating, based on the phase-information response signal , a first power line instantaneous power relating to total instantaneous power used by power consumers connected to the first power line;
Communication method.

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