KR102349100B1 - Power line communication system using phase control - Google Patents

Abstract

The present invention relates to a power line communication system using phase control to enable a receiving side to accurately recognize a power-off section of a phase control waveform controlled by a transmitting side regardless of charging of a capacitor disposed at a receiving side input end. According to the present invention, the power line communication system comprises: a transmission unit generating a communication signal having information by controlling the phase of a power waveform and transmitting the communication signal to a load unit through a power line; and at least one lighting unit detecting the phase of the power waveform transmitted from the transmitter to extract the communication signal and controlling a light to correspond thereto. The communication signal uses phase control to provide information to keep turning-on or off the vicinity of zero-cross of the power waveform. When the vicinity of zero-cross is turned off, a voltage charged in a load input terminal capacitor of the load unit can be rapidly discharged through a discharge switch within the off-period.

Description

Power line communication system using phase control {POWER LINE COMMUNICATION SYSTEM USING PHASE CONTROL}

The present invention relates to a power line communication system that performs power line communication by controlling the phase of a power waveform, and more particularly, a phase control in which transmitted data can be accurately transmitted to the receiving side by reducing the influence of the load side circuit. It relates to a power line communication system used.

As known, in power line communication using phase control, the phase of the power waveform supplied from the transmitting side to the receiving side (load) is controlled, and the receiving side recognizes the phase-controlled state to determine the presence or absence of phase control and the length of phase control, etc. It is a system that recognizes and communicates information.

The communication signal, which controls the phase of the power waveform, gives the meaning of information (binary data) to the presence or absence of an off section by turning it off on both sides around or near the zero cross of the power waveform, or the length of the off section As such, it has been disclosed in Korean Patent Publication No. 10-0446188, Korean Patent Publication No. 10-1206386, and Korean Patent Publication No. 10-1848314, previously filed by the present inventors.

Such a power line communication system will be described with reference to FIG. 1 .

Hereinafter, the power line communication system will be described as applied to the lighting control field as an example.

The power line communication system generates a communication signal by controlling the phase of the power (AC) waveform and transmits the transmission unit 100 to the lighting unit 200 through the power line, and the phase of the power waveform transmitted from the transmission unit 100 It detects and extracts a communication signal and includes at least one or more lighting unit 200 for controlling the lighting to correspond thereto.

The power line communication system controls the phase of the power waveform in order to send certain information from the transmitter 100 to the lighting unit 200, for example, binary information (communication signal) of “1011” as shown in FIG. In the case of transmission, the transmission control unit 120 controls the phase of the power waveform so that the power waveform including the information 1011 is formed.

That is, the transmission control unit 120 calculates the timing so as to be synchronized with the zero-crossing signal ZC1 input from the zero-crossing detection unit 110 or to enable phase control on both sides around the zero-voltage point, so that the power waveform is near or on both sides of the zero-crossing. The switching signal S2, which is a phase control signal, is output to the first switch 131 so as to have a phase-controlled power waveform that is turned OFF.

The switching signal S2 intercepts the first switch 131 of the switch unit 130, and the power waveform S1 is a phase-controlled power waveform S3 that is turned off or maintained on both sides of the zero crossing vicinity or both sides. ) is supplied to the load side.

Here, if the off state of the power waveform near zero crossing or both sides is set to binary '1' and the state maintaining the on state is set to binary '0', the phase-controlled power waveform S3 is '1011' binary information. becomes a communication signal.

The phase control power waveform S3 having such information is applied to the lighting unit 200 through the power supply (AC) power line.

The phase-controlled power waveform S3 applied to the lighting unit 200 outputs a pulsed output signal S4 through the signal detection unit 211 of the receiving unit 210, and the receiving control unit 212 outputs this signal. After formalizing and extracting the binary information signal S5 as actual information, the protocol is analyzed to control the lighting lamp 222 of the load unit 220 .

The information included in the communication signal may include a variety of information such as address information of the lighting unit 200 or the lighting or off or dimming/toning signals of the corresponding lighting lamp 222 .

However, when there is a capacitor C at the input terminal of the load unit 220, as shown in FIG. 3, an off period according to the phase control at a voltage higher than the threshold voltage of the photocoupler 211a of the signal detection unit 211 When this starts, the lighting unit 200 may not be able to recognize the off-section near the zero-cross of the power waveform transmitted from the transmitter 100 .

The reason is that even when the power is turned off by the phase control, the charge charged in the capacitor C of the input terminal of the off load part 220 is not immediately discharged, but is gradually discharged, and the length of the off section of the power waveform transmitted from the transmitter 100 is not properly identified, and the reception control unit 212 of the reception unit 210 cannot determine that the phase control has started.

As the discharge progresses, the voltage is gradually lowered, and when it is below the threshold voltage of the photocoupler 211a of the signal detection unit 211, it is recognized as OFF, but it is different from the time when the phase control is already started by the transmitter 100, so that the correct information There is a problem that transmission becomes impossible.

That is, the signal to be recognized as shown in (B) of FIG. 3 is recognized as shown in (C), making it difficult to transmit accurate information.

Registered Patent Publication No. 10-0446188, Registered Patent Publication No. 10-1848314, Registered Patent Publication No. 10-1206386

The present invention was devised to solve the above problems, and an object of the present invention is to provide a power line communication system using phase control so that transmitted data can be accurately transmitted to the receiving side by reducing the influence of the load side circuit. it is in

Another object of the present invention is to provide a power line communication system using phase control so that the power-off section of the phase control waveform transmitted from the transmitting side can be recognized very accurately regardless of the charging of the capacitor at the receiving side input terminal at the receiving side. it is in

The present invention for achieving the above object is a transmitter for generating a communication signal having information by controlling the phase of the power waveform and transmitting it to the load unit through a power line; and at least one or more lighting parts for detecting the phase of the power waveform transmitted from the transmitter to extract the communication signal and controlling the lighting to correspond thereto, wherein the communication signal is near or around zero cross of the power waveform. Information is given to the presence or absence of an off section by turning both sides off or the length of an off section, and the transmitter includes a first switch interposed at one end of the power applied to the lighting unit to generate the communication signal, and the power source and a discharge switch connected to the other end of the and one end of the power applied to the lighting unit through the first switch, wherein the discharge switch is turned on immediately after the first switch is turned off and is turned off immediately before being turned on, When it is turned off, it is characterized in that the voltage charged in the load input terminal capacitor of the lighting unit is discharged within this off period.

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In addition, according to the present invention, the transmitter may include: a zero-crossing detector configured to detect a zero-cross of a power waveform; a transmission control unit for outputting predetermined switching signals to the switch unit so that the power waveform has a phase-controlled power source waveform that is turned off near or at both sides of the zero-crossing unit in synchronization with the zero-crossing signal input from the zero-crossing detecting unit; and a switch unit including a first switch interrupted by a switching signal of the transmission control unit, and a discharge switch for discharging the capacitor charging voltage of the load unit, wherein the switching signal of the transmission control unit is in the vicinity of zero cross of the power waveform or its The first switching signal for generating a communication signal by turning off both sides, and the voltage charged in the capacitor of the load that is turned on immediately after outputting the power off signal of the first switching signal and turned off immediately before blocking, is rapidly discharged through the discharge switch It is characterized in that it includes a third switching signal for discharging.

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In addition, according to the present invention, the first switching signal of the transmission control unit is output so that the length of the off section of the power waveform can be varied, and information is given so that the off section of the variable power waveform corresponds to the variable length of the off section. characterized in that

In addition, according to the present invention, the switch unit is further configured with a second switch that is connected in parallel with the first switch and maintains an OFF state when both a communication operation is performed and a lighting unit is in an OFF state, and the second switch is a relay switch. characterized in that

In addition, according to the present invention, the first switch and the discharge switch are configured as semiconductor switches, and have a structure in which a plurality of semiconductor elements are connected in parallel or a structure in which a plurality of semiconductor elements are connected in series. .

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In addition, according to the present invention, a temperature sensor is installed in the first switch of the switch unit, and when the temperature of the first switch becomes an overheating state of a certain temperature or more, the communication operation is stopped and the second switch is turned on to transfer the current to the first switch. It prevents the flow, and when the temperature becomes normal, it is characterized in that it is configured to resume the communication operation.

As described above, the present invention provides an effect that the transmitted data can be accurately transmitted to the receiving side by reducing the influence of the load side circuit.

In addition, the present invention provides the advantage of improving product quality because the power-off section of the phase control waveform transmitted from the transmitting side can be recognized very accurately by the receiving side regardless of the charging of the capacitor at the receiving side input terminal.

1 is a configuration diagram of a power line communication system using a conventional phase control;
Figure 2 is a main part of the output waveform diagram of Figure 1;
3 is a waveform diagram when a capacitor is present at the input terminal of the load unit in FIG. 1;
4 is a configuration diagram of a power line communication system using phase control according to the present invention;
5 (a) (b) is a circuit diagram of the first switch and the discharge switch according to the present invention,
6 is a switching signal timing diagram of the first switch and the discharge switch according to the present invention.

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

First of all, it should be noted that in adding reference numerals to the components of each drawing, the same components are provided with the same reference numerals as much as possible even though they are indicated on different drawings. In the description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

4 is a block diagram of a power line communication system using phase control according to the present invention.

As shown, the power line communication system using the phase control of the present invention,

It includes a transmitter 100 and at least one lighting unit 200 .

The lighting unit 200 may be equally applied to a driving load in other fields other than the lighting field.

The transmitter 100 controls the phase of the power waveform to generate a communication signal and transmits it to the load unit 200 through a power line. The zero crossing detection unit 110, the transmission control unit 120, the switch unit 130A and and an interface unit 140 .

The zero-crossing detection unit 110 detects a zero-cross of the power waveform and inputs it to the transmission control unit 120 .

The zero-crossing detection unit 110 may include a first photocoupler 111 , and is configured to recognize a zero-crossing by an output of the first photocoupler 111 .

The transmission control unit 120 calculates the timing to synchronize with the zero-crossing signal input from the zero-crossing detection unit 110 or to enable phase control on both sides around the zero-voltage point, so that the power waveform is turned off (near or on both sides of the zero-crossing) OFF) and outputting predetermined switching signals to the switch unit 130A so as to have a phase-controlled power waveform.

The switching signal includes a first switching signal that is a phase control signal for generating a communication signal by turning off near the zero-cross of the power waveform, a second switching signal for turning off the second switch 132 only during communication, and , the third switching that turns on immediately after the power off signal of the first switching signal is output and turns off just before shutting off to quickly discharge the voltage charged in the capacitor C of the lighting unit 200 through the discharge switch 133 contains signals.

The power waveform off section by the first switching signal is output to have a variable length, and the variable off section can be configured to match information corresponding to the variable length of the off section.

The switch unit 130A is a means for generating a phase-controlled power waveform having information (communication signal) by turning off near the zero-cross of the power waveform, and is a first switch controlled by the switching signal of the transmission control unit 120 . 131 , a second switch 132 and a discharge switch 133 may be included.

The first switch 131 is connected to be interposed between one end (L) of the power source (AC) and one end (a) of the lighting unit 200 , and the second switch 132 is connected to the first switch 131 . connected in parallel to

The discharge switch 133 is connected to one end (a) of the power applied to the lighting unit 200 through the first switch 131 and the other end (N) of the power, that is, applied to the lighting unit 200. It is interposed at both ends of the power source (AC) and is configured so that the voltage charged in the capacitor of the lighting unit 200 can be discharged.

The first switch 131 is turned off by the first switching signal of the transmission control unit 120 to turn off the zero-cross vicinity of the power waveform.

The second switch 132 is turned off by the second switching signal of the transmission control unit 120, and maintains an off state when the first switch 131 performs a communication operation and cuts off standby power.

The discharge switch 133 is turned on by the third switching signal of the transmission control unit 120, and is turned on immediately after the first switch 131 is turned off by the first switching signal, and the first switch 131 is turned on. It is configured to be turned off just before it is turned on.

The first switch 131 and the discharge switch 133 are composed of a semiconductor switch and may be one of a triac, an FET, an IGBT, and a thyristor.

The second switch 132 is configured as a relay switch, and the relay switch may be one of an electric or mechanical relay and a semiconductor relay (SSR).

The second switch 132 maintains an ON state when the first switch 131 does not perform a communication operation, so that power is supplied through the second switch 132 with much less resistance than the first switch 131 . flow to prevent heat generation of the first switch 131, which is a semiconductor switch.

In addition, the second switch 132 is configured to maintain an off state to cut off standby power when all the loads of the lighting unit 200 are off.

The first switch 131 and the discharge switch 133 have a structure in which two semiconductor devices are connected in parallel as shown in FIG. 5(a), or two semiconductor devices are connected in series as shown in FIG. It can be configured to have a structure connected to

More specifically, in the structure in which the first switch 131 is connected in parallel, the output of the transmission control unit 120 is connected to the gates of the first IGBT (Q1) and the second IGBT (Q2) IGBT drivers ID1, ID2 ), the emitter end of the first IGBT and the collector end of the second IGBT are connected to one end (L) of a power source (AC), and the collector end of the first IGBT and the emitter end of the second IGBT are a lighting unit It is configured to be connected to one end (a) of (200).

In addition, in the serial connection of the first switch 131, the output of the transmission control unit 120 is connected to the IGBT driver ID3 connected to the gates of the third IGBT (Q3) and the fourth IGBT (Q4), and the third The collector terminal of the IGBT (Q3) is connected to one end (L) of the power line, the emitter terminal of the third IGBT (Q3) is connected to the emitter terminal of the fourth IGBT (Q4), and the collector of the fourth IGBT (Q4) The end is configured to be connected to one end (a) of the lighting unit 200 .

The discharging switch 133 can configure switching elements in series or in parallel in the same way as the first switch 131, and one side of the discharging switch 133 is one side (N) of the power source and the other side is a lighting unit ( 200) is configured to be connected to one side (a).

Such a series and parallel structure has a characteristic that the driving circuit is simplified in the case of series, and the amount of heat generated is reduced by 1/4 in the case of parallel.

When the output of the first switching signal and the third switching signal is described with reference to the timing diagram of FIG. 6 , when the first switching signal S2 for turning off the first switch 131 for communication is output, this signal is output Immediately after outputting the third switching signal S6, the discharge switch 133 is turned on, and immediately before the first switching signal S2 is cut off, the third switching signal S6 is cut off to turn on the discharge switch. (133) is configured to off.

That is, the first switch 131 of the switch unit 130A turns on the discharge switch 133 for a period T2 smaller than the period T1 to cut off the power near the zero-cross of the power waveform in order to transmit information. The voltage charged in the capacitor C of the lighting lamp 200 is discharged through the discharge switch 133 during the period T2 without short circuit of the main power source AC.

In addition, a temperature sensor 134 is installed in the first switch 131 of the switch unit 130A, and when the temperature of the first switch 131 becomes an overheating state of a certain temperature or more, the communication operation is stopped and the second switch 132 ) to prevent the current from flowing to the first switch 131, and when the temperature becomes normal, it can be configured to resume the communication operation.

The interface unit 140 receives a wired/wireless signal for controlling lighting lamps from an external input device and transmits it to the transmission control unit 120 .

The input device may be a wall switch, a short-range infrared receiving sensor, a control system through a network or other communication means, or a PC.

On the other hand, the lighting unit 200 detects the phase of the power waveform transmitted from the transmitter 100, extracts a communication signal, and controls the lighting to correspond thereto, and includes a receiver 210 and a load unit 220 .

The receiver 210 includes a signal detector 211 that detects a zero-crossing and phase-controlled signal of the power waveform, and a signal detector 211 that detects an off section of the phase-controlled power waveform, and normalizes the signal output from the signal detector 211 After extracting the communication signal (information), a reception control unit 212 for controlling the lighting lamp 222 with the extracted communication signal is included.

The signal detection unit 211 includes a second photocoupler 211a, and in the case of a power waveform whose phase is controlled with a zero voltage detection signal as an output of the second photocoupler 211a, detects a phase control section and sends it to the reception control unit. print it out

The reception control unit 212 includes a data extraction unit for extracting only data from a signal in which a zero voltage detection signal and a phase control signal input from the signal detection unit 211 are mixed, and a command by analyzing the data input through the data extraction unit. It may include a protocol interpretation unit for recognizing

The load unit 220 includes an illumination lamp 222 and a power supply unit 221 for supplying a driving voltage to the illumination lamp 222. In general, the load unit 220 includes a capacitor C at the input terminal due to the circuit configuration. and the capacitor C is charged with a voltage according to the phase of the power supply voltage.

The operation and operation of the power line communication system of the present invention configured as described above will be described below.

As an example, as shown in FIG. 3 , a process of transmitting a communication signal having binary information of '1011' from the transmitter 100 to the corresponding lighting unit 200 will be described.

For reference, the communication signal '1011' is an exemplary signal, and is actually composed of more information.

When a lighting lamp lighting signal is input to the transmission control unit 120 through the interface unit 140 of the transmission unit 100, the transmission control unit 120 is a switch unit ( 130A) to output a predetermined switching signal.

The transmission control unit 120 first outputs a second switching signal for turning off the second switch 132 of the switch unit 130 .

Accordingly, the second switch 132 is turned off and the power AC flows only through the first switch 131 .

Then, as shown in FIG. 2, the second of the switch unit 130 is controlled so that the phase of the power waveform corresponding to the communication signal '1011' is controlled in synchronization with the zero-cross of the power waveform S1 input from the zero-crossing detection unit 110. A first switching signal S2 for intermitting one switch 131 is output.

Accordingly, the first switch 131 is turned off or maintained in an on state near the zero-cross of the power waveform S1 so that the phase-controlled power waveform S3 is applied to the lighting unit 200 .

When outputting the first switching signal S2 as described above, the transmission control unit 120 transmits the third switching signal ( S6) is output.

That is, when the first switching signal S2 for turning off the first switch 131 is output, the third switching signal S6 is output immediately after the signal is output to turn on the discharge switch 133, and the second switching signal S6 is output. Immediately before the first switching signal S2 is cut off to turn on the first switch, the third switching signal S6 is cut off to turn off the discharge switch to turn the discharge switch 133 off again.

That is, when the first switching signal is output, the first switch is turned off, and when the third switch signal is output, the discharge switch is turned on. The on/off operation may be configured to be reversed depending on the configuration of the logic circuit controlling the switch.

Therefore, at the moment when the first switch 131 of the switch unit 130A cuts off the power near the zero-cross of the power waveform in order to generate transmission information using the phase control, a period T2 shorter than the period T1 of the power cutoff ), the voltage charged in the capacitor (C) of the lighting lamp 200 is rapidly discharged through the discharge switch 133 without short circuit of the power source (AC).

With this discharging operation of the capacitor C, the switch unit 130A transmits the normal phase-controlled power waveform S3 to the load unit 200 as shown in FIG. 2 .

On the other hand, the lighting unit 200 pulses the zero-crossing signal of the power waveform transmitted from the signal detection unit 211 of the receiving unit 210 through the transmitting unit 100 and the off-section near the zero crossing of the phase-controlled power waveform S3. It is output as a form signal S4.

The reception control unit 212 normalizes the output pulse signal S4 of the signal detection unit 211 to extract the communication signal S5 '1011', and then interprets the extracted signal to control the lighting lamp 222 .

As described above, the present invention provides the effect that the power-off section of the phase control waveform transmitted from the transmitting side can be recognized very accurately regardless of the charging of the capacitor at the receiving side input terminal at the receiving side.

Although limited embodiments of the present invention have been described above, those skilled in the art should note that the present invention is not limited thereto and various embodiments are expected.

100: transmitter 110: zero crossing detection unit
120: transmission control unit 130, 130A: switch unit
140: interface unit 200: lighting unit
210: receiving unit 211: signal detecting unit
212: reception control unit 220: load unit
221: power unit 222: lighting

Claims (7)

a transmitter for generating a communication signal having information by controlling the phase of the power waveform and transmitting it to a load unit through a power line; and
At least one lighting lamp unit for detecting the phase of the power waveform transmitted from the transmitter, extracting the communication signal, and controlling the lighting lamp to correspond thereto;
The communication signal provides information on the presence or absence of an off section or the length of an off section by turning it off on both sides around or near the zero cross of the power waveform,
The transmitter is
A first switch interposed at one end of the power applied to the lighting unit to generate the communication signal, and a discharge switch connected to the other end of the power source and one end of the power applied to the lighting unit through the first switch,
The discharge switch is turned on immediately after the first switch is turned off and turned off immediately before being turned on, so that when the power waveform is turned off, the voltage charged in the load input terminal capacitor of the lighting unit is discharged within this off period Powerline communication system using control. The method according to claim 1,
The transmitter is
a zero-crossing detection unit for detecting a zero-crossing of the power supply waveform;
a transmission control unit outputting predetermined switching signals to the switch unit so that the power waveform has a phase-controlled power source waveform that is turned off near or at both sides of the zero-crossing unit in synchronization with the zero-crossing signal input from the zero-crossing detecting unit; and
It is composed of a switch unit including a first switch interrupted by the switching signal of the transmission control unit, and a discharge switch for discharging the capacitor charging voltage of the load unit,
The switching signal of the transmission control unit is turned on immediately after the output of the power-off signal of the first switching signal and is turned off immediately before blocking, and a first switching signal for generating a communication signal by turning off near or both sides of the zero-cross of the power waveform. Power line communication system using phase control, characterized in that it includes a third switching signal for quickly discharging the voltage charged in the capacitor of the load through the discharge switch. delete 3. The method according to claim 2,
The phase, characterized in that the first switching signal of the transmission control unit is output so that the length of the off section of the power waveform can be varied, and information is provided so that the off section of the variable power waveform corresponds to the length of the variable off section Powerline communication system using control. 3. The method according to claim 2,
The switch unit further includes a second switch connected in parallel with the first switch and maintaining an OFF state when both the lighting unit is in an OFF state and when performing a communication operation,
The second switch is a power line communication system using phase control, characterized in that the relay switch. 3. The method according to claim 1 or 2,
The first switch and the discharge switch are composed of a semiconductor switch,
A power line communication system using phase control, characterized in that it has a structure in which a plurality of semiconductor elements are connected in parallel or a structure in which a plurality of semiconductor elements are connected in series. 3. The method according to claim 2,
A temperature sensor is installed in the first switch of the switch unit,
When the temperature of the first switch becomes an overheating state above a certain temperature, the communication operation is stopped and the second switch is turned on to prevent current from flowing to the first switch, and when the temperature becomes normal, the communication operation is resumed. Power line communication system using phase control, characterized in that it is configured to be

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