KR102609438B1 - Sequential power supply control system for led display boards - Google Patents

Abstract

The sequential power supply control system for the LED signboard according to the present invention transmits the relay control signal and current and voltage measurement signals controlled and output from the central processing unit (CPU) to the relay unit 20, the current measurement sensor unit 30, and the voltage measurement unit. It is supplied to each of the sensor units 40, and the first relay 21 of the relay unit 20 is turned on to supply the active line (V) and neutral line ( The current and voltage of the power input through N) are checked by the first current measurement sensor 31 and the voltage measurement sensor 41 of the current measurement sensor unit 30 and the voltage measurement sensor unit 40, respectively, to determine the inrush current. If there is no problem, check whether surge voltage is introduced by supplying stable power to the first cabinet 61 of the first cabinet 60 through the first output terminal 51 of the output terminal 50, and then connect the second relay to the second relay. (22) to Nth relays 26 are sequentially turned on to measure the current and voltage of the power input in real time to the second current measurement sensor 32 of each of the current measurement sensor unit 30 and the voltage measurement sensor unit 40. To Nth current measurement sensor 36 and second voltage measurement sensor 42 to Nth voltage measurement sensor 46 are sequentially checked to check whether surge voltage is introduced due to inrush current, and if there is no problem, the output terminal unit 50 ) is configured to distribute and supply stable power to the second cabinets (62) to the Nth cabinets (66) of the first cabinet unit (60) sequentially through the second output terminals (52) to the Nth output terminals (56). It is characterized by being

Description

SEQUENTIAL POWER SUPPLY CONTROL SYSTEM FOR LED DISPLAY BOARDS}

The present invention relates to a sequential power supply control system for an LED signboard. More specifically, the present invention relates to a sequential power supply control system for an LED display board with a sequential power control function that electrically stabilizes the power supplied to a plurality of cabinets, including LED modules and SMPS, and then automatically distributes the power supply. will be.

As presented in the prior art of Republic of Korea Patent No. 10-2212686, ‘LED signboard system and operation method with shared SMPS’, the LED signage system consists of a cabinet combined with an LED module, a plurality of control devices, and SMPS in series. As an LED signboard system constructed by connecting, a plurality of capacitors are connected to a plurality of printed circuit boards for applying power and control signals to these control devices and SMPS, etc., and these capacitors are connected for the purpose of stabilizing electricity.

However, when initial power is applied to the printed circuit board, a large amount of inrush current is generated, resulting in surge voltage, which becomes more severe as the number of screen display devices increases. Therefore, in the conventional LED signboard system, there is a problem in that the LED signboard is damaged due to a surge voltage being generated during the initial power supply.

Accordingly, the present inventor would like to propose a sequential power supply control system for a new type of LED display board that solves all the problems of the conventional LED display system.

The present invention is a sequential LED signboard with a sequential power control function that checks whether the power supplied to the first cabinet is stabilized in response to the inrush current and then sequentially distributes the stabilized power to the second cabinet to the Nth cabinet. The purpose is to provide a power supply control system.

The above objectives and other inherent objectives of the present invention can all be easily achieved by the present invention described below.

The sequential power supply control system for the LED signboard according to the present invention transmits the relay control signal and current and voltage measurement signals controlled and output from the central processing unit (CPU) to the relay unit 20, the current measurement sensor unit 30, and the voltage measurement unit. It is supplied to each of the sensor units 40, and the first relay 21 of the relay unit 20 is turned on to supply the active line (V) and neutral line ( The current and voltage of the power input through N) are checked by the first current measurement sensor 31 and the voltage measurement sensor 41 of the current measurement sensor unit 30 and the voltage measurement sensor unit 40, respectively, to determine the inrush current. If there is no problem, check whether surge voltage is introduced by supplying stable power to the first cabinet 61 of the first cabinet 60 through the first output terminal 51 of the output terminal 50, and then connect the second relay to the second relay. (22) to Nth relays 26 are sequentially turned on to measure the current and voltage of the power input in real time to the second current measurement sensor 32 of each of the current measurement sensor unit 30 and the voltage measurement sensor unit 40. To Nth current measurement sensor 36 and second voltage measurement sensor 42 to Nth voltage measurement sensor 46 are sequentially checked to check whether surge voltage is introduced due to inrush current, and if there is no problem, the output terminal unit 50 ) is configured to distribute and supply stable power to the second cabinets (62) to the Nth cabinets (66) of the first cabinet unit (60) sequentially through the second output terminals (52) to the Nth output terminals (56). It is characterized by being

In the present invention, a central control processing unit (CPU) that outputs a relay control signal, a current measurement control signal, and a voltage measurement control signal; A relay unit (20) that operates by a relay control signal output from the central processing unit (CPU) to supply power through an active line (V) connected to the three-phase, four-wire power input terminal unit (10); The current measurement control signal output from the fuse unit (F) and the central control processing unit (CPU) connected to the normal contact point (NO) of the relay unit 20 is input, and the current measurement sensor unit 30 measures the input current. )and; A voltage measurement sensor unit that is connected to the current measurement sensor unit 30 and measures the voltage input through the active line (V) and neutral line (N) by receiving a voltage measurement control signal output from the central control processing unit (CPU). (40) and; An output terminal unit 50 that outputs power through the active line (V), neutral line (N), and ground line (G) output from the voltage measurement sensor unit 40; a power supply system (100) for the LED display board, including ) is a good idea.

In the present invention, the active line (V) applies power to the common contact point (COM) of each of the first relay 21 to the Nth relay 26 constituting the relay unit 20, and the central control processing unit (CPU) ) When the first relays 21 to N-th relays 26 are operated by a relay control signal output from ), power is supplied to the normal contact point (NO), and the first fuses (F1) to the first fuses (F1) constituting the fuse unit (F) Current measurement is supplied to the first to N-th current measurement sensors 36 constituting the current measurement sensor unit 30 through the N fuse (F6) and output from the central processing unit (CPU). It is better to measure in real time sequentially whether inrush current flows by signal.

In the present invention, each of the first voltage measurement sensor 41 to the Nth voltage measurement sensor 46 constituting the voltage measurement sensor unit 40 is the first current measurement sensor 31 to the Nth current measurement sensor 36. It is recommended that the inrush voltage be sequentially measured in real time using the voltage measurement signal output from the central control processing unit (CPU) installed between the output terminal and the neutral line (N).

In the present invention, the power supply system 100 of the LED signboard and the power supply system 110 of the second LED signage to the power supply system 120 of the Nth LED signage each have a communication input port (P1) and a communication output port ( P2) is connected to each central control processing unit (CPU), and the communication output port (P2) of the power supply system 100 of the LED display board and the communication input port (P1) of the power supply system 110 of the second LED display board are connected. ), and connect the communication output port (P2) of the power supply system 110 of the second LED display board with the communication input port (P1) of the power supply system 120 of the N LED display board to supply power to the LED display board. It is better to operate the system 100 as a main controller, and allow the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board to operate as a sub-controller.

The present invention measures the supply inrush current and voltage, and after electrical stabilization is achieved, the power supply is distributed to each cabinet constituting the LED display board, and the process of distributing and supplying power sequentially is automatically performed, thereby forming an LED display board. This has the effect of providing a highly reliable sequential power supply control system for LED signboards by eliminating damage and blocking of each cabinet and providing a stable power supply.

In addition, the present invention allows the power supply system of the LED display board to be used independently or by connecting multiple power supply systems in parallel, thereby ensuring a stable supply of power to all N LED display boards, thereby creating a large LED display board. It has an effect that can be applied to .

1 is an electrical circuit diagram of a sequential power supply control system for an LED signboard according to the present invention.
Figure 2 is a configuration diagram according to an example of the use state of the sequential power supply control system of the LED signboard of the present invention.
Figure 3 is a configuration diagram of another example of the sequential power supply control system of the LED display board of the present invention in use.
Figure 4 is a configuration diagram of another example of the sequential power supply control system of the LED signboard of the present invention in use.
Figure 5 is a diagram of an embodiment for remotely controlling the sequential power supply control system of LED signs according to the present invention located in different places.
Figure 6 is a diagram showing the use state of the sequential power supply control system of the LED signboard according to the present invention for operating with a contact signal.
Hereinafter, the present invention will be described in detail with reference to the attached drawings.

1 is an electrical circuit diagram of a sequential power supply control system for an LED signboard according to the present invention.

The sequential power supply control system for the LED signboard according to the present invention includes a central control processing unit (CPU) that outputs a relay control signal, a current measurement control signal, and a voltage measurement control signal, and a relay output from the central control processing unit (CPU). A relay unit 20 that operates by a control signal to supply power through an active line (V) connected to the three-phase, four-wire power input terminal unit 10, a normal contact point (NO) of the relay unit 20, and A current measurement sensor unit 30 that measures the input current by receiving a current measurement control signal output from the connected fuse unit (F) and the central control processing unit (CPU), and connected to the current measurement sensor unit 30. a voltage measurement sensor unit 40 that receives a voltage measurement control signal output from a central processing unit (CPU) and measures the voltage input through the active line (V) and the neutral line (N); and the voltage measurement sensor unit. It includes an output terminal unit 50 that outputs power through the active line (V), neutral line (N), and ground line (G) output from (40).

The relay control signal, current measurement control signal, and voltage measurement control signal output from the central control processing unit (CPU) are connected to the relay unit 20 and the current measurement sensor unit ( 30) and the voltage measurement sensor unit 40, respectively, and are controlled and processed.

The central control processing unit (CPU) is operated by a control program by supplying a stabilized DC voltage from a battery (not shown), and the relay unit 20 is also supplied with a stabilized DC voltage (eg 12V) from the battery, and the power input The terminal unit 10 is a terminal unit connected to an AC 3-phase 4-wire input power line and consists of an active line (V) consisting of V1, V2, and V3, a neutral line (N), and a ground line (G) terminal, and the power input terminal section ( 10) and the output terminal unit 50 may be a terminal block or an outlet.

The AC input power supplied to the power supply system 100 of the LED sign can be supplied and cut off by operating an on/off power switch, and the central control processing unit (CPU) operates by manipulating an external input device (not shown). It can be done as much as possible.

The active line (V) applies power to the common contact point (COM) of each of the first relay (21) to the N-th relay (26) constituting the relay unit (20), and is output from the central control processing unit (CPU). When the first relay 21 to Nth relay 26 is operated by the relay control signal, power is supplied to the normal contact point NO, and the first fuse F1 to Nth fuse constituting the fuse unit F ( It is supplied to the first to Nth current measurement sensors 31 to 36 constituting the current measurement sensor unit 30 through F6) and is output from the central processing unit (CPU) by the current measurement signal. Inrush current is sequentially measured in real time.

The output terminals of each of the first current measurement sensors 31 to Nth current measurement sensors 36 constituting the current measurement sensor unit 30 are connected to the first voltage measurement sensor 41 constituting the voltage measurement sensor unit 40. By connecting the first to Nth output terminals 51 to Nth output terminals 56 that are connected to the Nth voltage measurement sensor 46 and constituting the output terminal portion 50, each of the first output terminals of the current measurement sensor portion 30 Whether or not inrush current is flowing can be sequentially measured in real time by the current measurement signal output from the central processing unit (CPU) through the current measurement sensor 31 to the Nth current measurement sensor 36.

Each of the first voltage measurement sensor 41 to the Nth voltage measurement sensor 46 constituting the voltage measurement sensor unit 40 is connected to the output terminal of the first current measurement sensor 31 to the Nth current measurement sensor 36 and the neutral wire. The first voltage measurement sensor 41 of each of the voltage measurement sensor units 40 is connected to the first output terminal 51 to Nth output terminal 56 that is installed between (N) and constitutes the output terminal unit 50. ) Through the Nth voltage measurement sensor 46, it is possible to sequentially measure in real time whether the inrush voltage is flowing in by the voltage measurement signal output from the central control processing unit (CPU).

The output terminal unit 50 may be composed of a first output terminal 51 to an N-th output terminal 56, and each of these first output terminals 51 to N-th output terminals 56 is connected to an active line (V). , a neutral wire (N) and a ground wire (G) terminals, and stabilized power is supplied to the cabinet unit 60, respectively.

The first cabinet unit 60 may be composed of a first cabinet 61 to an N-th cabinet 66, and each of the first cabinets 61 to N-th cabinets 66 is composed of a plurality of cabinets. , refers to an LED display board equipped with LED modules, control devices, SMPS, and printed circuit boards, respectively.

The first current measurement sensor 31 and the first voltage measurement sensor 41 of the current measurement sensor unit 30 and the voltage measurement sensor unit 40 measure the input current and voltage to determine the surge voltage caused by the inrush current. Check whether there is an inflow, and if there is no problem, stable power through the active line (V) and neutral line (N) is supplied to the output terminal section 50 through the normal contact point (NO) of the first relay 21 constituting the relay section 20. It is output to the first output terminal 51 and supplied to an SMPS connected to a printed circuit board (not shown) constituting the first cabinet 61 of the first cabinet part 60, thereby constituting the first cabinet 61. Multiple LED signs can be displayed.

At this time, when the inrush current flows in through the first relay 21 constituting the relay unit 20, the first fuse F1 constituting the fuse unit F is cut by the surge voltage caused by the inrush current to supply power. is blocked, and when the inrush current is not included, safe power is supplied to the first cabinet 61 of the first cabinet part 60 to display the LED display board, thereby preventing damage to the LED display board due to the inrush current. You can.

This invention measures the current and voltage of the input power of both the three-phase, four-wire active line (V) and the neutral line (N) to determine whether inrush current is flowing, so sequential power supply can be achieved by measuring useful current and voltage. there is.

In the present invention, the power that is checked and made safe by the first current measurement sensor 31 and the first voltage measurement sensor 41 is output to the first output terminal 51 of the output terminal unit 50, and the central control detects this. According to the program of the processing unit (CPU), the stabilized power processed in response to the inrush current is sequentially output to the second output terminal 52 to the Nth output terminal 56 constituting the output terminal unit 50, respectively. By doing so, it is possible to distribute power supply and ensure smooth power supply sequentially.

That is, the central control processing unit (CPU) checks whether the inrush current and voltage values measured by the first current measurement sensor 31 and the first voltage measurement sensor 41 are stabilized to check for surge voltage caused by the inrush current. If there is no effect, the second relays 22 to Nth relays 26 constituting the relay unit 20 are sequentially turned on to generate the second current constituting the current measurement sensor unit 30 and the voltage measurement sensor unit 40. The inrush current and voltage are measured in real time by the measurement sensor 32 to the N-th current measurement sensor 36 and the second voltage measurement sensor 42 to the N-th voltage measurement sensor 46, and the central control processing unit (CPU) By performing control processing in the inrush current, the stabilized power that does not contain the inrush current is output to the second output terminal 52 to the Nth output terminal 56 constituting the output terminal unit 50, which causes the LED by the inrush current. It not only improves the reliability of the LED display board by eliminating damage and blocking of the display board, but also provides convenience in repair work by quickly checking for malfunctions.

In this invention, the size of the inrush current is significantly reduced by supplying power sequentially and distributedly, thereby promoting the safety of power supply. It continuously detects current and voltage, and when abnormal voltage and current are detected, an abnormal signal is detected as an output. By blocking the negative relay unit 20, danger can be prevented and a notification can be sent to the control center (operating system).

For this purpose, the present invention connects the communication unit 70 connected to the central control processing unit (CPU) and a computer (PC) via Ethernet or UART (universal asynchronous transmitter/receiver), etc. to check the control status through the Internet from a remote location and check the ON/OFF OFF can be controlled and the state of inrush current and voltage and current state during operation can be observed.

Figure 2 is a configuration diagram according to an example of the use state of the sequential power supply control system of the LED signboard of the present invention.

The power supply system 100 of the LED display board according to the present invention can be used by connecting a plurality of them in parallel. In this case, the power input terminal unit 10 of the power supply system 100 of the LED display board and the power of the second LED display board are connected. The power input terminal 11 of the supply system 110 is connected in parallel, and the power input terminal 11 of the power supply system 110 of the second LED signboard is input to the power supply system 120 of the Nth LED signboard. It can be applied to a large LED signboard by connecting the terminal part 12 in parallel.

In the above, the power supply system 100 of the LED display board can be set as the master, and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board operate as slaves, and each slave The information can be controlled by the master or a separate master controller can be used.

Figure 3 is a configuration diagram of another example of the sequential power supply control system of the LED display board of the present invention in use.

According to this, the power supply system 100 of the LED display board and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board each have a communication input port (P1) and a communication output port (P2). ) is connected to each central control processing unit (CPU), and the communication output port (P2) of the power supply system 100 of the LED signboard and the communication input port (P1) of the power supply system 110 of the second LED signboard and connect the communication output port (P2) of the power supply system 110 of the second LED display board with the communication input port (P1) of the power supply system 120 of the N LED display board to connect the power supply system of the LED display board. The power supply system 100 of the LED display board is operated by operating (100) as a main controller and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board operating as a sub-controller. After the LED display board is displayed in a stabilized state, the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board can be sequentially controlled to operate.

In addition, the central control processing unit (CPU) of the power supply system 100 of the LED sign collects and controls information from the power supply system 110 of the second LED sign to the power supply system 120 of the Nth LED sign. This allows efficient distribution of power supply.

Figure 4 is a configuration diagram of another example of the power supply system 100 of the LED signboard of the present invention in use.

The communication input port (P1) of the power supply system 100 of the LED sign is connected to a computer (PC) through Ethernet communication, and the communication output port (P2) of the power supply system 100 of the LED sign is connected to the second LED sign. is connected to the communication input port (P1) of the power supply system 110, and communicates with the communication output port (P2) of the power supply system 110 of the second LED signboard and the power supply system 120 of the Nth LED signboard. By connecting the input port (P1) to the power supply system 100 of the LED sign, information (on, off status and current) of the power supply system 110 of the second LED sign to the power supply system 120 of the Nth LED sign is connected to the input port (P1). and voltage value confirmation) can be collected and controlled so that control can be easily performed through a computer (PC) from a remote location.

Figure 5 is a diagram of an embodiment for remotely controlling the sequential power supply control system of LED signs according to the present invention located in different places.

The power supply system 100 of the LED display board and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board are installed at each output terminal of the Internet distributor (D) connected to the computer (PC) through an Ethernet communication network. ) By connecting each communication input port (P1), the power supply system 100 of the LED sign and the power supply system 110 of the second LED sign to the power supply system 120 of the Nth LED sign each operate as masters. It may be suggested to do so.

Figure 6 is a diagram showing the use state of the sequential power supply control system of the LED signboard according to the present invention for operating with a contact signal.

The present invention relates to the power supply system 100 of the LED display board and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board, each of which is connected to a central control processing unit (CPU). Connect using (a) and (b), connecting the contact point (b) of the power supply system 100 of the LED display board with the contact point (a) of the power supply system 110 of the second LED display board, and Control processing can be performed by connecting the contact point (b) of the power supply system 110 of the electric sign board to the contact point (a) of the power supply system 120 of the Nth LED electric sign board.

In this invention, after the operation of the power supply system 100 of the LED display board is completed, the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board operate sequentially to provide stabilized power. Each LED display board constituting the first cabinet unit 60 and the second cabinet units 60A to N-th cabinet units 60N is displayed.

It should be noted that the detailed description of the present invention described above is merely an example for understanding the present invention and is not intended to define the scope of the present invention. The scope of the present invention is defined by the appended claims, and all simple modifications or changes within this scope should be understood as falling within the scope of the present invention.

10, 11, 12: 3-phase 4-wire power input terminal
V: Active wire N: Neutral wire
G: Ground wire 20: Relay unit
NO: Normal contact
21 ~ 26: 1st to Nth relay F: Fuse unit
F1 ~ F6: 1st to Nth fuses PC: Computer
30: current measurement sensor unit 40: voltage measurement sensor unit
31 ~ 36: 1st to Nth current measurement sensors
P1, P2: Communication input and output ports
41 ~ 46: 1st to Nth voltage measurement sensors
50: output terminal part
51 ~ 56: 1st to Nth output terminals
60: first cabinet part
60A ~ 60N: 2nd to Nth cabinet sections
61 ~ 66: 1st to Nth cabinets
70: Department of Communications
100: Power supply system of LED signboard
110 ~ 120: Power supply system for the 2nd to Nth LED signboards

Claims (9)

A central control processing unit (CPU) that outputs a relay control signal, a current measurement control signal, and a voltage measurement control signal; A relay unit (20) that operates by a relay control signal output from the central processing unit (CPU) to supply power through an active line (V) connected to the three-phase, four-wire power input terminal unit (10); The current measurement control signal output from the fuse unit (F) and the central control processing unit (CPU) connected to the normal contact point (NO) of the relay unit 20 is input, and the current measurement sensor unit 30 measures the input current. )and; A voltage measurement sensor unit that is connected to the current measurement sensor unit 30 and measures the voltage input through the active line (V) and neutral line (N) by receiving a voltage measurement control signal output from the central control processing unit (CPU). (40) and; An output terminal unit 50 that outputs power through the active line (V), neutral line (N), and ground line (G) output from the voltage measurement sensor unit 40; a power supply system (100) for the LED display board, including ), and the active line (V) applies power to the common contact point (COM) of each of the first relay (21) to the Nth relay (26) constituting the relay unit (20), and the central control processing device When the first relay 21 to the Nth relay 26 are operated by a relay control signal output from the (CPU), power is supplied to the normal contact point (NO) and the first fuse (F1) constituting the fuse unit (F) It is supplied to the first to Nth current measurement sensors 31 to Nth current measurement sensors 36 constituting the current measurement sensor unit 30 through the to Nth fuses (F6) and output from the central control processing unit (CPU). The presence of inrush current is sequentially measured in real time by the current measurement signal, and each of the first voltage measurement sensors 41 to Nth voltage measurement sensors 46 constituting the voltage measurement sensor unit 40 is a first current measurement sensor. It is installed between the output terminal of the (31) to Nth current measurement sensors (36) and the neutral line (N), and sequentially measures in real time whether the inrush voltage is introduced by the voltage measurement signal output from the central control processing unit (CPU), and central processing The first relay 21 of the relay unit 20 is turned on by a relay control signal controlled and output from the device (CPU) to turn on the active line (V) of the AC power connected to the three-phase, four-wire power input terminal unit (10). And checking the current and voltage of the power input through the neutral line (N) by the first current measurement sensor 31 and voltage measurement sensor 41 of the current measurement sensor unit 30 and the voltage measurement sensor unit 40, respectively. Check whether surge voltage is introduced due to inrush current, and if there is no problem, supply stable power to the first cabinet 61 of the first cabinet 60 through the first output terminal 51 of the output terminal 50. By sequentially turning on the second relay 22 to the N-th relay 26, the current and voltage of the input power are measured in real time by the second current measurement sensor of each of the current measurement sensor unit 30 and the voltage measurement sensor unit 40. (32) to N-th current measurement sensor 36 and second voltage measurement sensor 42 to N-th voltage measurement sensor 46 are sequentially checked to check whether surge voltage is introduced due to inrush current and output if there is no problem. Stable power is distributed sequentially to the second cabinets (62) to the Nth cabinets (66) of the first cabinet unit (60) through the second output terminals (52) to N-th output terminals (56) of the terminal unit (50). A sequential power supply control system for an LED signboard, characterized in that the power supply is supplied. delete delete delete The method of claim 1, wherein the power input terminal unit 10 of the power supply system 100 of the LED display board and the power input terminal unit 11 of the power supply system 110 of the second LED display board are connected in parallel, and the second LED display board is connected in parallel. Sequential power supply control of the LED display board, characterized in that the power input terminal portion 11 of the power supply system 110 and the power input terminal portion 12 of the power supply system 120 of the Nth LED display board are connected in parallel. system. The method of claim 1, wherein each of the power supply system 100 of the LED display board and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board has a communication input port (P1) and a communication output. The port (P2) is connected to each central control processing unit (CPU), and the communication output port (P2) of the power supply system 100 of the LED display board and the communication input port of the power supply system 110 of the second LED display board are connected. (P1), and connect the communication output port (P2) of the power supply system 110 of the second LED signboard with the communication input port (P1) of the power supply system 120 of the Nth LED signboard to An LED display board characterized in that the power supply system 100 is operated as a main controller, and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board are operated as sub-controllers. Sequential power supply control system. The method of claim 1, wherein the communication input port (P1) of the power supply system 100 of the LED display board is connected to a computer (PC) through Ethernet communication, and the communication output port (P2) of the power supply system 100 of the LED display board is connected to a computer (PC) through Ethernet communication. ) and the communication input port (P1) of the power supply system 110 of the second LED display board, and supply power to the communication output port (P2) of the power supply system 110 of the second LED display board and the Nth LED display board. By connecting the communication input port (P1) of the system 120 to the power supply system 100 of the LED display board, information ( A sequential power supply control system for an LED signboard, characterized in that it collects and controls on, off status, and current and voltage values. The method of claim 7, wherein the power supply system 100 of the LED display board and the power supply system 110 of the second LED display board to the Nth LED display board are installed at each output terminal of the Internet distributor (D) connected to the computer (PC) through an Ethernet communication network. Each communication input port (P1) of the power supply system 120 is connected to the power supply system 100 of the LED display board and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board. ) A sequential power supply control system for an LED signboard, characterized in that each operates as a master. The method of claim 1, wherein each of the power supply system 100 of the LED display board and the power supply system 110 of the second LED display board to the power supply system 120 of the Nth LED display board are connected to a central control processing unit (CPU). Connected using the contact points (a) and (b), the contact point (b) of the power supply system 100 of the LED signboard is connected to the contact point (a) of the power supply system 110 of the second LED signboard, and the 2 A sequential power supply control system for an LED display board, characterized in that the contact point (b) of the power supply system 110 of the LED display board is controlled by connecting the contact point (a) of the power supply system 120 of the Nth LED display board. .

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