KR101182410B1 - Time division communication device - Google Patents

Abstract

In the present invention, when power is normally supplied using two lines, when communicating, the same line is disconnected from the power circuit and connected to the communication circuit to enable communication, but the installation of the line is possible regardless of polarity. The present invention relates to a time division communication device that is easy to work and has a very simple structure, which reduces costs and increases communication reliability due to no communication error. The main control unit 100 is connected through two lines (L1) and L2. In the communication device including at least one slave device 200 for power supply and data communication, the main controller 100, the main controller 110, the communication module 120, the power supply unit 130 and a communication switching switch unit 140 in which the first and second switches S1 and S2 are switched, and the slave device 200 includes a power detecting unit 210 and a power supply switch. With 220 The response signal AS is set through the power supply 230 and the key signal input through the key input unit 280, and the request signal RS of the main controller 100 is input through the slave communication module 250. Responsive to the slave control unit 240, the communication module 250, the communication connection switch unit 260 and transmits the response signal (AS) to the main controller 100 through the slave communication module 250 in response to The power supply detecting unit 270 and the key input unit 280 are configured to be included.

Description

Time division communication device

The present invention relates to a communication device that can communicate using a power line, and more particularly, to supply power by using two lines in normal, when communicating the same line from the power circuit and to the communication circuit The present invention relates to a time division communication device that connects to enable communication.

In general, in order to supply power and communicate at the same time using two wires, a data communication part composed of complicated modulation and demodulation circuits is required. Such power line communication is expensive and the circuit configuration is complicated.

As an example in which such communication is applied, a lighting control system using a program switch will be described.

First, the program switch is a switch that does not directly control the power of the lamp, and transmits the operation state of each switch having a unique number (ID) to the main controller to control the lamp according to the program of the main controller. Switch.

However, such a program switch lighting system requires four lines (two power supplies and two data communications) for power supply and data communication between the main controller and the program switch. This occurred.

Therefore, the product has been released to enable communication and power supply in two lines, but this also has a problem in that the circuit configuration is complicated, expensive, and communication speed does not increase due to communication with power supply.

The present invention has been made to solve the above problems, the object of the present invention is to supply power by using two lines in normal communication when the same line is separated from the power circuit and connected to the communication circuit to communicate The present invention relates to a time-division communication device that greatly reduces product cost and reduces communication error, thereby greatly increasing product reliability.

In addition, the object of the present invention is to realize a control unit that performs control by sensing the operation state of the switch, such as a program switch to enable power supply and communication through two lines, the cost is reduced by a very simple structure, the existing RS The present invention provides a time division communication device that can use a communication interface such as -485 as it is.

In order to achieve the above object, the present invention provides a communication device including at least one slave device connected to a main control device through two lines to perform power supply and data communication, wherein the main control device is configured to perform the slave control. A main control unit for supplying power to the device or connecting the communication module and the slave device to communicate with each other, a communication module for communicating with the slave device, a power supply unit for supplying power to the slave device 200; When the power is supplied by the control of the main control unit, the output of the power supply unit is connected to two lines leading to the slave device, and when the communication module and the slave devices perform communication, the first and A communication switching switch unit to which second switches are switched; The slave device provides a driving power to each circuit unit when power is supplied from two lines of the main controller, and when the power supply is cut off, a power supply unit for supplying pre-charged temporary power to each circuit unit, and detecting whether there is a power supply. When the power is cut off, the power detection unit for driving the communication connection switch unit to perform the communication, the response signal is set and the response signal in response to the request signal of the main controller input through the slave communication module the slave communication It characterized in that it comprises a slave control unit for transmitting to the main control unit through the module, a slave communication module for performing data communication with the communication module of the main control unit, and a communication connection switch unit connected when communicating with the communication module of the main control unit. .

As described above, the present invention implements the main controller and the slave device to enable power supply and communication through two lines, thereby reducing the cost with a very simple structure and using the conventional RS-485 communication method as it is. Therefore, it provides an advantage of increased product reliability.

1 is a block diagram of a time division communication apparatus according to the present invention;
2 is a detailed block diagram of a main control device according to the present invention;
3 is a detailed circuit diagram of a slave device according to a first embodiment of the present invention;
4 is a detailed circuit diagram of a slave device according to a second embodiment of the present invention;
5 is a detailed circuit diagram of a slave device according to a third embodiment of the present invention;
6 is a power supply and communication timing diagram between a main controller and a slave device according to the present invention.

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

1 is a block diagram of a time division communication apparatus according to the present invention.

As shown, the time division communication apparatus of the present invention includes a main controller 100 and a plurality of slave devices 200 connected to the main controller 100 by two lines L1 and L2.

The main controller 100 supplies power to the plurality of slave devices 200 through two lines L1 and L2 and performs data communication at the same time, and receives commands received from the slave devices 200. The signal is analyzed to generate a signal for controlling the controlled object.

The information of the data communication may be a request signal RS provided from the main controller 100 and a response signal AS of the slave device 200 provided in response thereto.

The request signal RS is a signal for asking the corresponding slave device 200 whether there is content to communicate, and requesting a response signal AS if there is content to communicate.

The present invention is a communication system that enables power supply and communication between two devices at the same time, and can be usefully applied to a lighting control system including, for example, a program switch. Various applications are possible through the technical idea of the present invention.

2 is a circuit block diagram of the main control device 100 of the light control device to which the present invention is applied.

As shown, the main control device 100 of the present invention,

The main control unit 110, the communication module 120, the power supply unit 130 and communication switching switch unit 140 is included.

The main controller 110 supplies power to the slave device 200 or controls the communication switching switch unit 140 so that the communication module 120 and the slave device 200 communicate with each other.

The communication module 120 outputs a request signal RS to the slave device 200 and receives a response signal AS of the slave device 200 provided in response thereto.

The power supply unit 130 supplies power to the slave device 200.

The communication switching switch unit 140 is switched by the control of the main control unit 110, when supplying power to the line (L1) (L2) of the output terminal of the power supply unit 130 to the slave device 200 The first and second switches S1 and S2 are switched to be connected, and the first and second switches are connected to the output terminal of the communication module 120 when the communication module 120 and the slave device 200 communicate. (S1) (S2) are switched.

According to the present invention, the main control unit 110 is supplied to the slave device 200, the power output from the power supply unit 130 through the switching operation of the communication switching switch unit 140 as shown in FIG. (ON) and OFF (OFF), and immediately after the DC power is cut off (OFF) outputs a request signal (RS), such as (B) from the communication module 120 to the slave device 200 And, in response to this to receive a response signal (AS) of the slave device 200, such as provided (C).

3 is a detailed circuit diagram of the slave device according to the first embodiment of the present invention.

As shown, the present invention slave device 200,

The power supply unit 210 supplies driving power to each circuit unit when power is supplied from two lines L1 and L2 of the main controller 100, and supplies temporary power pre-charged to each circuit unit when the power supply is cut off. And, through the power signal detection unit 220 and the key signal input through the key input unit 260 to sense the power supply, and to drive the communication connection switch unit 250 to perform communication when the power is cut off. The response signal AS is set and the response signal AS is controlled by the slave communication module 240 in response to the request signal RS of the main controller 100 input through the slave communication module 240. Slave control unit 230 for transmitting to the device 100, the slave communication module 240 for performing data communication with the communication module 120 of the main control device 100, and the communication module of the main control device 100 ( 120 and a communication connection switch unit 250 is connected when communicating with, And a key input unit 260 which provides a key button and sets a signal for data communication by performing key input accordingly.

In addition, according to the present invention may further include a display unit 270 for displaying the input state when the key is input through the key input unit 260.

Let's look at this more specifically.

The power supply unit 210 is composed of a diode (D1), a capacitor (C1), a regulator (REG) and a high capacity capacitor (C2), the high capacity capacitor (C2) is charged while the power is supplied when the power is cut off. When it is discharged the charged power temporarily provides power.

The diode D1 is a reverse current blocking device for preventing the power supply detecting unit 250 from misjudged whether or not the power supply detection unit 250 detects the power supply due to the voltage charged in the power supply unit 210 when the power is cut off.

The power detector 220 divides the supplied power into a resistor R1 and a resistor R2, and is connected to apply the divided voltage to the base of the transistor Q1, and outputs the power supply 210. The voltage is connected to the collector terminal of the transistor Q1 through the resistor R3 and the collector output of the transistor Q1 is applied to the communication connection switch unit 250.

The communication connection switch unit 250 is configured such that the third and fourth switches S3 and S4 are interlocked and operated by the collector output of the transistor Q1 of the power sensing unit 220. It is switched ON only when the collector output of Q1) is high level.

The operation of the time division communication apparatus according to the embodiment of the present invention configured as described above will be described. In this case, the case is applied to the lighting device using the program switch for convenience of understanding.

First, when power is applied to the apparatus, the main control unit 110 of the main control unit 100 controls the communication switching switch unit 140 on and off as shown in FIG. Through the power supply to the slave device 200 (for example, program switches) intermittently.

At this time, in the power supply section (ON) that is supplied power to the slave device 200,

The applied power is divided by the resistor R1 and the resistor R2 of the power detector 220 to apply a voltage to the resistor R2, and at the same time, two lines L1 and L2 of the main controller 100. The power provided from is applied to the power supply 210.

The voltage applied to the power supply unit 210 applies a driving voltage to each circuit unit of the slave device 200 (not shown), and at the same time, a charge is charged in the high capacitance capacitor C2.

At the same time, the voltage applied to the power sensing unit 220 turns on the transistor Q1 of the power sensing unit 220 so that a low potential is formed at the collector end thereof, so that the communication connection switch unit 250 is turned off. Will be maintained.

In the communication section OFF of FIG. 6A, that is, the communication section OFF in which power supply is cut off from the main controller 100, FIG.

As the voltage charged in the high capacity capacitor C2 of the power supply unit 210 is discharged, the slave control unit 230 and each circuit unit receive constant operating power by supplying reserve power for a predetermined period (communication section (OFF)). do.

At the same time, the transistor Q1 of the power detecting unit 220 is turned off and the high potential is output to the collector output terminal thereof, so that the third and fourth switches S3 and S4 of the communication connection switch unit 250 are switched on.

When the power is supplied to the slave device 200 in this way,

The user sets a signal necessary for the authoring desired by the key input unit 260 of the slave devices 200.

This signal is, for example, a luminaire or dimming signal of a luminaire, and is a key input to the slave controller 230.

In this case, the slave controller 230 detects an input value of the key input unit 260 to generate a data communication response signal AS.

At the same time, the key input signal value corresponding to the key input unit 260 is output to the display unit 270 so that the user can recognize it.

In this state, when the communication section of FIG. 6A is reached, the data communication request signal RA as shown in FIG. 6B output from the communication module 120 of the main control unit 100 is a line L1. (L2) is transmitted to the slave device 200, the request signal (RA) is passed through the communication connection switch 250 and is input to the slave controller 230 through the slave communication module 240.

When the request signal RS is input through the slave communication module 240, the slave controller 230 outputs a response signal AS as shown in FIG. 6C to the slave communication module 240. The response signal AS outputted to the slave communication module 240 is transmitted through the communication connection switch 250 and the communication switching switch 140 of the main controller 100 via the lines L1 and L2. 120).

The main controller 110 of the main controller 100 receiving the response signal AS from the slave device 200 analyzes the response signal AS to control the driving object.

For example, in the case of lighting device control using a program switch, the lighting device is turned on and off so that the lighting device can be controlled by the response signal AS.

4 is a detailed circuit diagram of a slave device according to a second embodiment of the present invention.

As shown, the slave device 200A according to another embodiment of the present invention,

The power supply unit 210 supplies driving power to each circuit unit when power is supplied from two lines L1 and L2 of the main controller 100, and supplies temporary power pre-charged to each circuit unit when the power supply is cut off. And, through the power signal detection unit 220 and the key signal input through the key input unit 260 to sense the power supply, and to drive the communication connection switch unit 250 to perform communication when the power is cut off. The response signal AS is set and the response signal AS is controlled by the slave communication module 240 in response to the request signal RS of the main controller 100 input through the slave communication module 240. Slave control unit 230 for transmitting to the device 100, the slave communication module 240 for performing data communication with the communication module 120 of the main control device 100, and the communication module of the main control device 100 ( 120 and a communication connection switch unit 250 is connected when communicating with, A key input unit 260 having a key button and performing a key input according thereto to set a signal for data communication, and two lines L1 and L2 connected to the power supply and provided from the main controller 100; Bridge diode (BD) for outputting a constant DC power output irrespective of the polarity of the power supplied through the polarity, and the polarity detection unit for detecting the power polarity of the two lines (L1) (L2) provided from the main controller 100 280, and interposed between the slave communication module 240 and the communication connection switch unit 250, and connected from the communication module 120 of the main controller 100 under the control of the slave controller 230. And a polarity switching switch unit 290 which is switched so that the polarity of the two lines L1 and L2 and the polarity (+) (−) of the communication line of the slave communication module 240 coincide with each other.

In addition, according to the present invention may further include a display unit 270 for displaying the input state when the key is input through the key input unit 260.

According to the embodiment according to the present invention, the polarity of the communication module 120 of the main control device 100 and the polarity of the slave communication module 240 is two between the main control device 100 and the slave device 200. When the lines L1 and L2 are connected, even when their polarities (+) and (-) are changed, they are sensed and the lines L1 and L2 are changed to have the same polarity so that communication is possible.

In the case of the present invention, it is possible to install without considering the polarity of the line (L1) (L2) during installation and construction of the main control device 100 and a plurality of slave devices 200 to provide a convenient construction.

An embodiment according to the present invention will be described in more detail.

The bridge diode BD is interposed between two lines L1 and L2 provided from the main controller 100 and the power supply unit 210, and two lines L1 and L2 from the main controller 100. Even if the polarity (+) (-) of the power supplied through the () is changed to each other, the output of the bridge diode (BD) will always output a constant DC voltage.

The polarity detector 280 is turned on or turned on by the light emitting device D2 which is turned on or off according to the polarity of the DC power supplied from the two lines L1 and L2, and the light emitting device D2 is turned on. Element Q2 and a resistor R5 connected to the photocoupler output terminal including the light emitting element D2 and the light receiving element Q2.

Here, the resistor R4 is a resistor for limiting the current flowing through the photocoupler.

Therefore, the operation thereof, for example, when the anode (L) line (L1) is input to the anode end of the light emitting device (D2), the voltage applied through the resistor (R4) to turn on the light emitting device (D2) The light receiving element Q2 is turned on.

When the light receiving element Q2 is turned on, a low potential is output to the collector end thereof, and this signal is input to the slave controller 230. At this time, the slave controller 230 outputs a low potential signal to the polarity switching switch unit 290 so that the polarity switching switch unit 290 maintains its initial state.

On the other hand, when the cathode (-) line L2 is input to the anode end of the light emitting device D2, the voltage applied through the resistor R4 turns off the light emitting device D2, and the light receiving device Q2 Is off.

The high end is applied to the collector end of the light receiving element Q2, and this signal is input to the slave controller 230. At this time, the slave controller 230 outputs a high potential signal to the polarity switching switch unit 290 so that the polarity switching switch unit 290 is switched.

The polarity switching switch unit 290 is interposed between the communication connection switch unit 250 and the slave communication module 240, the switch switching operation by the control of the slave controller 230, the main control unit 100 The fifth and sixth switches S5 and S6 are switched so that the polarity of the communication module 120 and the polarity (+) (−) of the communication line of the slave communication module 240 coincide with each other.

The operation of the time division communication apparatus according to another embodiment of the present invention configured as described above will be described. In this case, the case is applied to the lighting device using the program switch for convenience of understanding.

When power is applied to the apparatus, the main control unit 110 of the main control unit 100 controls the communication switching switch unit 140 on and off as shown in FIG. 6 (A) through lines L1 and L2. Power is supplied intermittently to the slave devices 200 (eg, program switches).

At this time, in the power supply section (ON) that is supplied power to the slave device 200,

The applied power is applied to the power supply unit 210 by outputting a constant DC voltage through the bridge diode BD regardless of the polarity of the lines L1 and L2.

The voltage applied to the power supply unit 210 applies a driving voltage to each circuit unit of the slave device 200 (not shown), and at the same time, a charge is charged in the high capacitance capacitor C2.

At the same time, the voltage applied to the power detecting unit 220 turns on the transistor Q1 through the resistor R1 and the resistor R2 so that a low potential is formed at the collector end thereof so that the communication connection switch unit 250 is turned off ( OFF) state.

On the other hand, the power supplied from the main controller 100 is also applied to the polarity detector 280.

For example, when the line L1 is the positive electrode (+) and the line L2 is the negative electrode (-), the line L1 is connected to the anode end of the photocoupler light emitting device D2 of the polarity detector 280. In this case, the photocoupler is turned on to output the low potential of the collector terminal of the transistor Q2. On the contrary, when the line L2 is connected to the anode end of the light emitting device D2 of the photocoupler, the photocoupler PC ) Is turned off, and the collector terminal of the transistor Q2 is output with a high potential and is input to the slave controller 230. The slave controller 230 memorizes the polarity detected at the time of power supply and switches the polarity switching switch 290 when the power is cut off and the communication standby state, thereby detecting the polarity detected by the polarity detector 280. The polarity of the line (L1) (L2) and the input and output polarity (+) (-) of the slave communication module 240 to match each other.

That is, when the positive (+) line (L1) is connected to the fifth switch (S5) of the polarity switching switch unit 290, the negative (-) line (L2) is connected to the sixth switch (S6), the polarity switching The movable pieces c of the fifth switch S5 and the sixth switch S6 of the switch unit 290 are connected to the contacts b, respectively, to give the input / output polarity (+) (−) of the slave communication module 240. ), The negative line (L2) is connected to the fifth switch (S5) of the polarity switching switch unit 280, and the positive line (L1) is connected to the sixth switch (S6), the polarity The movable pieces c of the fifth switch S5 and the sixth switch S6 of the switching switch unit 290 are connected to the contacts a, respectively, so that the input / output polarity (+) ( Set the correct communication environment by making-) match each other.

In the communication section OFF of FIG. 6A, that is, the communication section OFF in which power supply is cut off from the main controller 100, FIG.

As the voltage charged in the high capacity capacitor C2 of the power supply unit 210 is discharged, the slave control unit 230 and each circuit unit receive constant operating power by supplying reserve power for a predetermined period (communication section (OFF)). do.

At the same time, the transistor Q1 of the power detecting unit 220 is turned off and the high potential is output to the collector output terminal thereof, so that the third and fourth switches S3 and S4 of the communication connection switch unit 250 are switched on.

When the power is supplied to the slave device 200 in this way,

The user sets a signal necessary for the authoring desired by the key input unit 260 of the slave devices 200.

This signal is, for example, a luminaire or dimming signal of a luminaire, and is a key input to the slave controller 230.

In this case, the slave controller 230 detects an input value of the key input unit 260 to generate a data communication response signal AS.

At the same time, the key input signal value corresponding to the key input unit 260 is output to the display unit 270 so that the user can recognize it.

In this state, when the communication section of FIG. 6A is reached, the data communication request signal RA as shown in FIG. 6B output from the communication module 120 of the main controller 100 is positive (+). ) And the cathode (-) line (L1) (L2) is transmitted to the slave device 200, the request signal (RA) is passed through the communication connection switch 250 and the polarity switching switch unit 290 and slave communication The module 240 is input to the slave controller 230.

When the request signal RS is input through the slave communication module 240, the slave controller 230 outputs a response signal AS as shown in FIG. 6C to the slave communication module 240. The response signal AS output to the slave communication module 240 is a communication switching switch of the main controller 100 via the polarity switching switch unit 290, the communication connection switch 250, and the line L1 and L2. It is transmitted to the communication module 120 through 140.

The main control unit 110 of the main controller 100 receiving the response signal AS from the slay unit 200 analyzes the response signal AS to control the driving object.

After all, according to another embodiment of the present invention, even if the polarity of the line (L1) (L2) connected between the main control device 100 and the slave device 200 is changed to automatically detect the switching to match the polarity, then communication It offers one advantage to do.

5 is a detailed circuit diagram of a slave device according to a third embodiment of the present invention.

In a third embodiment according to the present invention, in a form similar to the above-described second embodiment,

The communication connection switch unit 250 and the polarity switching switch unit 290 of the second embodiment are replaced by the first polarity switching switch unit 291 and the second polarity switching switch unit 292, and the polarity detecting unit 281 The other configuration is the same except that the configuration is changed.

First, the polarity detector 281 includes a voltage divider R6 and a resistor R7 connected to both ends of two power lines L1 and L2, and a contact between the resistor R6 and the resistor R7 and ground. It is composed of a voltage divider (R8) and a resistor (R9) connected to.

Here, the output of the polarity detector 281 becomes a voltage applied to the voltage divider R9, and the resistor R6 and the resistor R7 are configured to have different resistance values.

Therefore, the operation of the positive line is applied to the resistor R6 and the positive line is applied to the resistor R7, which is the opposite of the case where the negative line is applied to the resistor R7. When the negative (-) line is applied to the resistor R6, a large difference appears in the voltage across the resistor R9 finally divided. This difference is determined by the slave controller 230 to determine which line is positive (+).

The first polarity switching switch unit 291 includes a seventh switch S7 and an eighth switch S8 that are interlocked, and the second polarity switching switch unit 292 is an ninth switch S9 and an interlocking member. 10 switch S10 is provided.

In addition, the contact a of the seventh switch S7 of the first polarity switching switch unit 291 is connected to one power line L1, and the contact b is the second polarity switching switch unit 292. It is connected to the contact (b) of the tenth switch (S10) of the same time and the negative (-) communication terminal of the slave communication module 240.

In addition, the contact (a) of the eighth switch (S8) of the first polarity switching switch unit 291 is connected to the other power supply line (L2), the contact (b) of the second polarity switching switch unit 292 It is connected to the contact (b) of the ninth switch (S9) and to the positive (+) communication terminal of the slave communication module 240.

In addition, the contact a of the ninth switch S9 of the second polarity switching switch unit 292 is connected to one power line L1, and the contact a of the tenth switch S10 is connected to the other power line ( It is configured to connect to L2).

In addition, the first polarity switching switch unit 291 and the second polarity switching switch unit 292 are connected to be operated by the outputs of the first and gate AND1 and the second and gate AND2, respectively, An output terminal ?? of the power sensing unit 22 and an output terminal ?? of the slave controller 230 are connected to an input terminal of the AND gate AND1, and the power source is connected to an input terminal of the second AND gate AND2. The output terminal ?? of the sensing unit 22 and the output terminal ?? of the slave controller 230 are configured to be connected to each other.

That is, the first polarity switching switch unit 291 and the second polarity switching switch unit 292 are switched on only when the outputs of the first and gate AND1 and the second and gate AND2 are high level. ON), and the first and gate AND1 and the AND2 output the high level signal only when the high level signal is input to all of the input signals.

Therefore, when power is not supplied through the power detecting unit 230, that is, during communication, the power detecting unit 230 outputs a high signal so that the first and second AND gates AND1 and AND2 operate. Outputs a high signal to one input terminal, wherein the slave controller 230 of the first and second AND gates AND1 and AND2 according to the polarity of the power line detected by the polarity detector 281. By selectively outputting a high signal to one input terminal, the corresponding first polarity switching switch unit 291 or the second polarity switching switch unit 292 is turned on (ON).

For example, when the first polarity switching switch unit 291 is turned on, the line L1 is a cathode (-) and the line L2 is a cathode (+), and the line L1 is a seventh switch. (S7) is connected to the negative (-) communication terminal of the slave communication module 240, the line (L2) is connected to the positive (+) communication terminal of the slave communication module 240 through the eighth switch (S8). Connected.

In addition, when the second polarity switching switch unit 292 is turned on, when the line L1 is a positive electrode (+) and the line L2 is a negative electrode (−), the line L1 is a ninth switch S9. ) Is connected to the positive (+) communication terminal of the slave communication module 240, the line (L2) is connected to the negative (-) communication terminal of the slave communication module 240 through the tenth switch (S10). .

The subsequent operation relationship is the same as described above.

100: main controller 110: main control unit
120: communication module 130: power supply
140: communication switching switch unit 200, 200A, 200B: slave device
210: power supply unit 220: power detection unit
230: slave controller 240: slave communication module
250: communication connection switch unit 260: key input unit
270: display unit 280,281: polarity detection unit
290: polarity switching switch unit 291: first polarity switching switch unit
292: second polarity switching switch section BD: bridge diode
AND1: first and gate AND2: second and gate

Claims (7)

A communication device including at least one slave device connected to a main control device through two lines and performing power supply and data communication,
The main controller,
A main control unit for supplying power to the slave device or connecting a communication module and a slave device to communicate with each other, a communication module for communicating with the slave device, and a power supply unit for supplying power to the slave device 200. When the power is supplied by the control of the main control unit, the output of the power supply unit is connected to two lines leading to the slave device, and when the communication module and the slave devices communicate with each other, they are connected to the input terminal of the communication module. A communication switching switch unit to which first and second switches are switched;
The slave device,
When power is supplied from the two lines of the main controller, the driving power is supplied to each circuit part, and when the power supply is cut off, the power supply part which supplies the pre-charged temporary power to each circuit part, and detects the presence or absence of power supply, A power sensing unit for performing communication by driving a communication connection switch unit, and setting a response signal and in response to a request signal of the main control unit input through the slave communication module, sends the response signal to the main control unit through the slave communication module; And a slave control unit for transmitting, a slave communication module for performing data communication with the communication module of the main controller, and a communication connection switch unit connected to communicate with the communication module of the main controller.
The method of claim 1,
The slave device provides a driving power to each circuit unit when power is supplied from two lines of the main controller, and when the power supply is cut off, a power supply unit for supplying pre-charged temporary power to each circuit unit, and detecting whether there is a power supply. When the power is cut off, the power detection unit for driving the communication connection switch unit to perform the communication, the response signal is set and the response signal in response to the request signal of the main controller input through the slave communication module the slave communication Slave control unit for transmitting to the main control unit through the module, a slave communication module for performing data communication with the communication module of the main control unit, a communication connection switch unit for communication with the communication module of the main control unit, connected to the power The power supplied via the two lines from the main controller A bridge diode for outputting a constant DC power supply, a polarity detecting unit for detecting power polarity of two lines provided from the main controller, and polarity of two lines connected from the communication module of the main controller under the control of the slave controller. And a polarity switching switch unit for switching the polarity of the communication lines of the slave communication module to coincide with each other.
The method of claim 1,
The slave device provides a driving power to each circuit unit when power is supplied from two lines of the main controller, and when the power supply is cut off, a power supply unit for supplying pre-charged temporary power to each circuit unit, and detecting whether there is a power supply. When the power is cut off, the power detection unit for driving the communication connection switch unit to perform the communication, the response signal is set and the response signal in response to the request signal of the main controller input through the slave communication module the slave communication The slave controller transmits data to the main controller through the module, the slave communication module performing data communication with the communication module of the main controller, and the power supplied through the two lines provided from the main controller is constant DC regardless of polarity. A bridge diode for outputting power and provided from the main controller Is a polarity detecting unit for detecting power polarity of two lines, a first polarity switching switch unit and a second polarity switching interposed between the two power lines and the communication line of the slave communication module to selectively switch the communication polarity. And a first end gate and a second end gate for selectively switching and driving the first polarity switching switch unit or the second polarity switching switch unit by receiving a switch unit, a control output of the slave control unit, and an output of the polarity detecting unit. Time division communication device characterized in that.
The method of claim 2 and 3,
The polarity detecting unit of the slave device includes a photocoupler comprising a light emitting device that is turned on or off according to the polarity of the DC power supplied from two lines of the main controller, and a light receiving device that is turned on when the light emitting device is turned on. Time division communication device characterized in that.
The method of claim 2 and 3,
And the polarity detecting unit of the slave device includes a plurality of voltage divider resistors for detecting a voltage level according to the polarity of the DC power supplied from two lines of the main controller.
The method according to any one of claims 1 to 3,
Time division communication device characterized in that the power supply unit of the slave device comprises a diode, a capacitor, a regulator and a high capacitance capacitor.
The method according to any one of claims 1 to 3,
The slave device further comprises a key input unit and a display unit for displaying the input state when the key is pressed.

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