KR102370889B1 - Standby power management method for reducing power consumption of LED signage system using supercapacitors - Google Patents

Abstract

The present invention relates to a standby power management method for reducing the power consumption of an LED signage system by using a supercapacitor, which can reduce the total power consumption of the LED signage system by limiting an operation of a DC power supply means maintained with the standby power of the LED signage system by using the supercapacitor. The standby power management method comprises: a power control monitoring step of measuring the terminal voltage of the supercapacitor and whether a controller unit is in a drive standby state through a power control circuit unit; and a standby power supply step of stopping the operation of a DC power supply unit and discharging the supercapacitor to supply electrical energy to the controller unit, if the controller unit is in the drive standby state and the terminal voltage of the supercapacitor exceeds a charging resume voltage in the power control monitoring step. Therefore, the method can turn off the operation of the DC power supply unit when the LED signage system is in the drive standby state, to prevent standby power from being generated, thereby reducing the total power consumption of the LED signage system.

Description

Standby power management method for reducing power consumption of LED signage system using supercapacitors}

The present invention relates to a method for more effectively reducing power consumption of an LED signage system that is installed in a place or space used by multiple people and provides various information such as advertisement information by outputting text, image, video, etc. In particular, a supercapacitor It relates to a standby power management method for reducing the total power consumption of an LED signage system by limiting the driving of a DC power supply means for maintaining the standby power of the LED signboard system by using it.

As shown in the drawing showing an example of the LED signage system in FIG. 1, a device commonly referred to as an 'LED signage system' is installed indoors or on the exterior wall of a building to display various information such as traffic conditions, weather information, and promotional images and images. As a type of display means to provide, as LED devices are used as light emitting devices, display output with high luminance is generally achieved compared to other display means, and displays for indoor or outdoor installation due to their ease of manufacture in various sizes and large sizes and high durability. It is widely used in various fields as a means.

As shown in the diagram conceptually illustrating the basic configuration of the LED signage system in FIG. 2, the LED signage system 1 as shown in FIG. = 8, 16, 32) A plurality of plate-shaped LED pixel panels 20-1 formed in a matrix structure are connected in a plane to form an LED light emitting unit 20, and the plurality of LED pixel panels ( In 20-1), light emission is controlled by a plurality of driving driver modules 30 .

That is, the plurality of LED pixel panels 20-1 forming the LED light emitting unit 20 as shown in FIGS. 1 and 2 are the driving driver module 30 of the LED pixel panel 20-1. Text, image, and video are output by a signal that turns on/off the LED element constituting each pixel.

At this time, the output data for controlling the output of the driving driver module 20 and the control signals for various driving of the LED signage system 1 are made by the controller unit 40 having a data processing function.

That is, the controller unit 40 outputs various contents according to a stored program including a microprocessor, and performs predetermined control according to an external command signal.

And, it comprises a DC power supply unit 50 (SMPS) for receiving an external AC power supply (AC) and supplying DC power to the controller unit 40 and the driving driver module 30 .

As the above-described LED signage system 1 is driven by the DC power supply unit 50 that receives AC power from the outside, converts it into DC power and supplies it, the LED signage system 1 is being driven or in a standby state Also, the DC power supply unit 50 always operates, and in the standby state, supplies current to the controller unit 40 in standby to receive a driving signal.

As such, even in a state in which the LED signage system 1 is not driven, as the controller unit 40 maintains a standby state to receive a driving signal, the DC power supply unit 50 maintains an operating state, and thus the standby consumption Although power is very important in terms of reducing power consumption of the LED signboard 1, there is a problem that is not considered at all.

That is, in the conventional LED signage system 1, the power consumed by the controller unit 40 in the driving standby state is very low, whereas in the DC power supply unit 50 to supply DC power to the controller unit 40, AC A significant conversion loss occurs in converting DC 311V generated by rectifying 220V into a DC voltage of several V required by the controller unit 40 .

Specifically, the standby power of the LED signage system 1 requires that the microprocessor of the controller unit 40 maintain a standby state to receive a driving command, even while the LED signage system 1 is not in operation, so power supply is Although necessary and the power consumed by the microprocessor is extremely weak, the DC power supply 50 generates a significant conversion loss in the process of converting DC 311V generated by rectifying AC 220V to DC 3V actually required.

In order to solve the problem of loss of electrical energy due to standby power of the conventional LED signage system 1, a DC power supply with low conversion loss of standby power has been developed, but there is a physical limit in lowering the change loss of standby power. There is a problem that the effect of saving electric energy is very insufficient.

As a related prior art, Application No. 10-2019-0011076, entitled 'High-efficiency power-saving LED signage that cuts off standby power', has been disclosed.

The prior art extracts the no-load state of the unit lamp corresponding to the unit pixel of the displayed image and cuts the driving power applied to the unit lamp, thereby cutting off standby power that can minimize the power consumption of the LED display. In this regard, a unit lamp that emits light in response to a unit pixel of the displayed image and an LED substrate in which unit lamps are arranged in a matrix form on the front side to form an expression screen on which the displayed image is displayed, and an LED substrate to be connected to a plurality of unit lamps an LED panel including a lamp connector provided on the rear surface of the lamp and a branch connector provided on the rear surface of the LED substrate to be connected to the lamp connector, and detachably coupled to the lamp connector and delivered to the unit lamp in a no-load state among a plurality of unit lamps A control module that individually controls a number of unit lamps so that the power is cut off, a power module that is detachably coupled to the branch connector and supplies power to the LED panel and control module, and a module holder that detachably couples the control module from the lamp connector includes

As another prior art, Application No. 10-2010-0128934, entitled 'Energy-saving LED display using standby power control' has been disclosed.

The prior art relates to a power-saving LED sign using standby power control, and a plurality of LEDs are arranged to form an LED display panel; a panel driver for driving the LED display panel to display an image on the LED display panel; a switching mode power supply unit that receives AC power and generates driving power necessary for driving the LED display panel and the LED module driver and supplies the driving power to the LED display panel and the panel driving unit; Controls the panel driving unit to display an image through the LED display panel, and when an operation in standby mode is detected, driving power output from the switching mode power supply unit to at least a part of the LED display panel and at least a part of the panel driving unit It characterized in that it comprises a main control unit for controlling a switching signal for the operation of the switching mode power supply so that this is cut off. Accordingly, by controlling the switching signal of a switching mode power supply (SMPS) that supplies driving power to the LED display panel and the panel driving unit, the driving power supplied to at least a part of the LED display panel and at least a part of the panel driving unit is controlled. By minimizing the power consumption by blocking, the power can be turned on and off momentarily in a situation where operation in standby mode is required without damage to the circuit.

That is, in the conventional LED signage system 1, in reducing power consumption, the power consumption itself is lowered through the light emitting method or the power consumption from the direct current power supply device (SMPS) itself is reduced due to standby power. There is a problem in that there is a limit to relatively significantly reducing the loss of electrical energy.

The present invention has been devised to solve the problems of the prior art as described above, and the DC power supply unit that converts external power to DC power and supplies it for driving the LED signage system does not work in the standby state of the LED signage system. An object of the present invention is to provide a standby power management method of an LED signboard system that can eliminate the waste of electrical energy due to normal standby power.

That is, the present invention turns off the driving of the DC power supply in the standby state of the LED signage system requiring fine direct current power, and replaces the DC power supply. An object of the present invention is to provide a method for managing standby power of an LED signage system using a supercapacitor serving as a power source.

In addition, an object of the present invention is to provide a standby power management method that can reduce the total power consumption of the LED signage system by managing the standby power of the LED signboard using a supercapacitor.

Other objects of the present invention can be understood through the characteristics of the present invention, can be seen more clearly through the embodiments of the present invention, and can be realized by means and combinations indicated in the claims.

In order to achieve the problems to be solved by the present invention as described above, the present invention has the following technical features.

The standby power management method for reducing power consumption of an LED signboard system using a supercapacitor of the present invention includes: an LED signboard enclosure providing an exterior and an inner space; an LED light emitting unit configured to form a rectangular flat output screen by combining a plurality of LED pixel panels made of LED light emitting devices on the front or both sides of the LED sign board in a plane; a plurality of driving driver modules for outputting a signal for turning on/off the LED light emitting device of each LED pixel panel constituting the LED light emitting unit according to the image signal input from the controller unit; a controller unit for inputting an image signal for outputting content output through an output screen of the LED light emitting unit to the driving driver module; a DC power supply unit for supplying DC power to the controller unit and the driving driver module; and a supercapacitor for supplying electric energy to the controller, a charging circuit for charging the supercapacitor with DC power supplied from the DC power supply, and a power control circuit for controlling the operation of the DC power supply. In the standby power management method of the LED signage system comprising a study, the power control monitoring step of measuring whether the driving standby state of the controller unit and the terminal voltage of the supercapacitor through the power control circuit unit; and when the controller unit is in a standby state for driving in the power control monitoring step and the terminal voltage of the supercapacitor exceeds the charging restart voltage, the DC power supply unit stops the operation and discharges the supercapacitor to supply electrical energy to the controller unit It is characterized in that it includes a; standby power supply step to supply.

The standby power supply step of the standby power management method for reducing power consumption of the LED signage system using the supercapacitor of the present invention measures the terminal voltage of the supercapacitor being discharged through the power control circuit unit in real time so that the terminal voltage of the supercapacitor is When the charging restart voltage is reached, the re-activation of the DC power supply unit through the power control circuit unit to charge the supercapacitor through the charging circuit unit and the recharging step of supplying electric energy to the controller unit; characterized.

In the standby power management method for reducing power consumption of the LED signage system using the supercapacitor of the present invention, stopping the operation of the DC power supply in the standby power supply step is made by blocking the bias current supplied to the DC power supply; technical features.

The supercapacitor of the standby power management method for reducing power consumption of the LED signage system using the supercapacitor of the present invention includes any one of Electric Double Layer Capacitor, Hybrid Capacitor, and Pseudo Capacitor; a technical feature.

The charging circuit unit of the standby power management method for reducing power consumption of the LED signage system using the supercapacitor of the present invention charges the supercapacitor by a constant current charging method when the LED signage system is in a standby state to drive, and the LED signage system In this driving state, charging by a constant voltage charging method is a technical feature.

The supercapacitor of the standby power management method for reducing power consumption of the LED signage system using the supercapacitor of the present invention stops charging the terminal voltage of the supercapacitor in a constant current charging method in a standby state in which the LED signage system is driven by the charging circuit unit It is charged until the voltage is reached, and then fully charged by a constant voltage charging method during the driving state of the LED signage system.

The present invention has the effect of lowering the overall power consumption of the LED signage system by preventing standby power from being generated by turning off the operation of the DC power supply in the standby state of the LED signage system through the means for solving the above problems. there is.

In addition, the present invention prevents the DC power supply from operating in the driving standby state of the LED display system and allows the DC power supply to operate only in the state in which the LED display system is driven. There is an effect that can relatively extend the operating life of the power supply, and through this, there is an effect of relatively increasing the overall driving life of the LED signage system.

In addition, the present invention is easily added to the LED signage system installed and operating in many places, thereby reducing the power consumption of the LED signage system to save electric energy.

Other effects of the present invention can be understood through the characteristics of the present invention, can be seen more clearly through the embodiments of the present invention, and can be exhibited by means and combinations shown in the claims.

1 is a view showing an example of an LED signage system;
2 is a diagram conceptually showing the basic configuration of an LED signage system;
3 is a diagram conceptually illustrating a standby power management method for reducing power consumption of an LED signage system using a supercapacitor of the present invention;
4 is a view conceptually illustrating an LED signage system to which a standby power management method for reducing power consumption of an LED signboard system using a supercapacitor of the present invention is applied;
5 is a view conceptually showing a standby power providing unit of the LED signboard system to which the standby power management method for reducing power consumption of the LED signboard system using the supercapacitor of the present invention is applied;
6 is a diagram conceptually illustrating a standby power management method for reducing power consumption of an LED signboard system using a supercapacitor of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention set forth below refers to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that various embodiments of the present invention are different but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention in relation to one embodiment. In addition, it should be understood that the position or arrangement of individual components in each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the following detailed description is not intended to be taken in a limiting sense, and the scope of the present invention is limited only by the appended claims, along with all scopes equivalent to those claimed. Like reference numerals in the drawings refer to the same or similar functions throughout the various aspects.

3 is a diagram conceptually illustrating a standby power management method for reducing power consumption of the LED signage system using the supercapacitor of the present invention.

As shown in FIG. 3, the technical feature of the standby power management method according to the present invention is that the LED signage system uses the characteristics of a supercapacitor that stores electrical energy and discharges it through the LED light emitting unit 20. In the driving state for outputting contents, the DC power supply unit 50 that supplies DC power required for driving the LED signage system is operated to supply electrical energy to the controller unit 40 and each driving driver module 30, and a predetermined In the driving standby state in which the contents of is not output, only the controller unit 40 requires electric energy, so as shown in FIG. 3 , the operation of the DC power supply unit 50 with a relatively large loss of electric energy is stopped. And, by supplying the electric energy stored in the supercapacitor to the controller unit 40, the controller unit 40 can maintain a driving standby state, which is a state in which a command can be input.

As described above, the standby power management method according to the present invention limits the operation of the DC power supply unit 50 in the driving standby state of the LED signage system, and at the same time replaces the function of the DC power supply unit 50 so that a supercapacitor performs the DC power supply. Energy consumption due to the operation of the supply unit 50 is reduced.

Meanwhile, the supercapacitor is charged while the DC power supply unit 50 is operating.

Therefore, the electric signboard LED system to which the standby power management method according to the present invention can be applied is FIG. 4 conceptually showing the LED signage system to which the standby power management method for reducing power consumption of the LED electric signage system using the supercapacitor of the present invention is applied. As shown in the drawing, in the configuration of a general LED signage system, it further includes a standby power providing unit 60, wherein the standby power providing unit 60 reduces power consumption of the LED signage system using the supercapacitor of the present invention in FIG. 5 As shown in the diagram conceptually showing the standby power providing unit of the LED signage system to which the standby power management method for It is limitedly applied to the LED signage system.

When explaining each configuration of the LED signage system to which the standby power management method according to the present invention is applied as described above, as shown in FIG. 4 , the LED signboard enclosure 10, the LED light emitting unit 20, and the driving driver module 30 , a controller unit 40 , a DC power supply unit 50 , and a standby power supply unit 60 .

As shown in FIG. 4, the LED signboard housing 10 forms an exterior with a box-shaped structure made of a metal material, and front or rear so that the LED light emitting unit 20 can be exposed to the front or front or rear. The front and rear have an open structure.

That is, the LED signboard housing 10 exposes the LED light emitting unit 20 to the outside, and the driving driver module 30 , the controller unit 40 , the DC power supply unit 50 and the standby power supply unit 60 . It has a structure that can be installed inside.

As shown in FIG. 4, the LED light emitting unit 20 is installed on the front or both sides of the electric sign board housing 10, and a plurality of LED pixel panels 20-1 made of LED light emitting devices are combined in a plane. to form a rectangular flat output screen.

Such an LED light emitting unit 20 forms a rectangular flat output screen by combining a plurality of LED pixel panels 20-1 made of LED light emitting devices in a plane as shown in FIG. 4 .

On the other hand, the LED pixel panel 20-1 is a substrate on which LED light emitting devices forming N×N dots are mounted, and depending on the output color of the LED pixel panel 20-1, one The LED light emitting device forms one dot, and in the case of three-color output, two LED light emitting devices having different light emitting colors in red, blue, and green form one dot, and in the case of full color, blue, green, and red Three LED light emitting devices form one dot.

Such an N×N dot LED pixel panel 20-1 may be composed of 8×8 dots to 32×32 dots, preferably 16×16 dots (N=16), or 24×24 dots ( N=24) is preferred.

As shown in FIG. 4, the driving driver module 30 is installed for each LED pixel panel 20-1 or is installed on a plurality of LED pixel panels 20-1 to the LED light emitting unit 20. Outputs a signal for turning on/off the LED light emitting device of each LED pixel panel 20-1 constituting the .

The driving driver module 30 receives an image signal from the controller unit 40, and turns on and off each LED light emitting device constituting the LED pixel panel 20-1 according to the received image signal to emit an image to the LED. output through the unit 20 .

On the other hand, the driving driver module 30 is a driving driver module added to drive each LED pixel panel 20-1 in a typical LED signage system 1, and is not limited to any specific driving driver module.

As shown in FIG. 4 , the controller unit 40 outputs an image signal for outputting a predetermined image content to the driving driver module 30 through an output screen of the LED light emitting unit 20 . As a data storage means and data processing means are included, it is driven according to the program logic, and it processes various data to control the overall driving of the LED signage system 100 .

The DC power supply unit 50 supplies DC power to the driving driver module 30 and the controller unit 40 as a means for receiving external AC power (AC) and converting it into DC power.

Such a DC power supply unit 50 may be a DC power supply device commonly referred to as 'SMPS', which is used to supply DC power in a typical LED signage system 1, and is not limited to any specific DC power supply device. does not

The standby power supply unit 60 stops the operation of the DC power supply unit 50 and replaces the DC power supply unit 50 when the LED signage system 100 is in a driving standby state, and the controller unit 40 By serving to supply electrical energy to the DC power supply unit 50, standby power due to the operation of the DC power supply unit 50 is prevented from being consumed.

As such, the standby power supply unit 60 includes a supercapacitor 110 , a charging circuit unit 120 , and a power control circuit unit 130 , as shown in FIG. 5 .

The supercapacitor 110 is a type of capacitor called a capacitor, which serves as a capacitor for storing electrical energy and is a means for storing electrical energy in a large capacity. ), in particular, it corresponds to an electronic component in which the performance of the electric capacity has been strengthened.

That is, the supercapacitor 110 refers to a large-capacity capacitor with a charge capacity of several hundred to several thousand Farads (F). By using the charging phenomenon by the movement or surface chemical reaction, rapid discharging is possible, and it has high charging/discharging efficiency and semi-permanent cycle life characteristics.

Accordingly, the supercapacitor 110 according to the present invention may include any one of an Electric Double Layer Capacitor, a Hybrid Capacitor, and a Pseudo Capacitor.

The Electric Double Layer Capacitor (EDLC) is also referred to as an 'electric double layer capacitor' and stores energy through reversible adsorption/desorption by electrostatic force of ions in the electrolyte solution in the active electrode.

In other words, the electrons accumulate where the + ions on one side gather and then supply energy in such a way that they fall.

On the other hand, in EDLC, charge transfer does not occur through redox reaction at the electrode, only charging occurs, and it has a storage mechanism through an electrode with a very large surface area, which induces high output through fast energy storage and transport. There are advantages to doing.

The Hybrid Capacitor is a supercapacitor with the advantages of high output, high-speed charging and discharging characteristics and high capacity of a lithium secondary battery, and is called LIC (Lithium Ion Capacitor).

LIC is a structure that connects the positive electrode of EDLC and the negative electrode of a lithium secondary battery. It has high energy density while maintaining the high output characteristics of EDLC. In addition to output and capacity, high operating voltage (3.8~2.2V), small size / It has advantages such as light weight possibility, rapid charge/discharge capability, high durability and reliability, and excellent high temperature stability.

The pseudo-capacitor is also called a 'pseudo capacitor', and the movement of electrons occurs while electrochemical substances are attached to the electrode surface, and stores electric charges through redox reactions. Although the stability of the cycle is inferior, the energy density has a superior advantage compared to EDLC.

The supercapacitor 110 as described above receives the electric energy supplied from the DC power supply unit 40 in the driving state in which the LED signage system 100 is driven and stores the electric energy through the charging circuit unit 120, and the In the driving standby state of the LED signage system 100 , a predetermined current is output at a predetermined voltage capable of driving the controller unit 40 with the stored electrical energy.

For example, the current consumed in the driving (command) standby state of the 3V controller unit 40 is supplied as 1mA.

The charging circuit unit 120 is a means for charging the supercapacitor 110 with the DC power supplied from the DC power supply unit 50. According to the configuration of the supercapacitor 110, a role of charging the supercapacitor 110 do.

Such a charging circuit unit 120 corresponds to a general electric circuit that enables charging and discharging of the supercapacitor 110 to be made, and is not limited to any specific electric circuit.

On the other hand, the charging circuit unit 120 charges the supercapacitor 110 in a constant current charging method while the LED signage system 100 is in a driving standby state in order to prevent excessive charging of the supercapacitor 110, and the LED signage system ( When 100) is in the driving state, the supercapacitor 110 is charged by a constant voltage charging method.

That is, the supercapacitor 110 causes a phenomenon such as short-circuiting the load of the DC power supply unit 50 by sucking an excessive current in a state where there is no charging voltage structurally, and continues even after the charging voltage reaches an appropriate level. Since there is a characteristic that cannot be fully charged unless the constant voltage charging method of supplying current is used, the charging circuit unit 120 is charged in the constant current charging method when the charging voltage is insufficient according to the charging voltage of the supercapacitor 110 to protect the circuit. And when the charging voltage reaches an appropriate level, the supercapacitor 110 is fully charged by switching to the constant voltage charging method.

On the other hand, the constant voltage charging method continuously flows a small current for several hours or more in order to achieve a voltage balance inside the supercapacitor 110, and the supercapacitor 110 as a constant voltage charging method in the driving standby state of the LED signage system 100 When charging is performed, there is a problem in that the efficiency of the total power consumption is deteriorated due to the conversion efficiency in which the electric energy of the DC power supply unit 50 is consumed.

Therefore, the charging circuit unit 120 starts charging in a constant current charging method in the driving standby state of the LED signage system 100, and when the charging voltage of the supercapacitor 110 reaches an appropriate level, the DC power supply unit 50 to maximize the conversion efficiency by stopping the operation of the

That is, when the LED signage system 100 is driven, the supercapacitor 110 is fully charged by performing the constant voltage charging method following the constant current charging method.

The power control circuit unit 130 is configured to be driven by electric energy supplied from the supercapacitor 110 , and when a driving signal is received by receiving a driving signal or a driving standby signal from the controller unit 40 , the A role of supplying a bias current to the DC power supply unit 50 to drive the DC power supply unit 50, and when receiving the driving standby signal, cut off the bias current to stop the driving of the DC power supply unit 50 do

That is, the power control circuit unit 130 corresponds to a means for switching on/off the DC power supply unit 50 .

The on/off switching of the DC power supply unit 50 of the power control circuit unit 130 is performed according to the driving signal and the driving standby signal of the controller unit 40 or according to the terminal voltage of the supercapacitor 110 . .

Meanwhile, the above standby power providing unit 60 may be included in the controller unit 50 .

Hereinafter, a standby power management method according to the present invention that is applied to the LED signage system 100 as described above to reduce standby power will be described.

6, as shown in a diagram conceptually illustrating a standby power management method for reducing power consumption of an LED signage system using a supercapacitor of the present invention, the standby power management method according to the present invention includes a power control monitoring step (S10) and A standby power supply step (S20) performed according to the power control monitoring result is included.

The power control monitoring step (S10) determines the state for replacing the DC power supply unit 50 with the super capacitor 110, and replaces the DC power supply unit 50 with the super capacitor 100 according to the state to function. make a decision to carry out

Specifically, in the power control monitoring step ( S10 ), the charging state is checked through the operating state of the controller unit 40 through the power control circuit unit 130 and the terminal voltage of the supercapacitor 110 .

That is, as shown in FIG. 6 , the power control monitoring step ( S10 ) determines whether the controller unit 40 is in a driving standby state and whether it is charged to supply electric energy through the supercapacitor 110 . In order to confirm whether or not, the power control circuit unit 130 measures the terminal voltage of the supercapacitor 110 to determine whether the charging restart voltage is exceeded, and the terminal voltage does not exceed the charging restart voltage. Even if the controller unit 40 is in a standby state, the operation of the DC power supply unit 50 is not stopped.

Accordingly, in the power control monitoring step (S10), as shown in FIG. 6 , the operating state of the controller unit 40 in the power control circuit unit 130 is determined to be a driving standby state, and at the same time, the terminal of the supercapacitor 110 . The standby power supply step (S20) is performed only when the voltage exceeds the charging restart voltage required for charging.

In the standby power supply step (S20), when the controller unit 40 is in a driving standby state in the power control monitoring step (S10), and the terminal voltage of the supercapacitor 110 exceeds the charging restart voltage, the DC power supply unit ( 50) stops the operation and discharges the supercapacitor 110 to supply electrical energy to the controller unit 40 .

In this case, stopping the operation of the DC power supply unit 50 may be accomplished by blocking the bias current of the DC power supply unit 50 through the power control circuit unit 130 .

That is, in the standby power supply step (S20), when the LED signage system 100 is in a driving standby state, the DC power supply unit 50 stops the operation and the electric energy stored in the supercapacitor 110 is transferred to the controller unit 40 to maintain the driving standby state of the LED signage system 100 even without the operation of the DC power supply unit 50 .

As such, in the standby power management method according to the present invention, as shown in FIGS. 5 and 6, the LED signage system 100 maintains the driving standby state even without the operation of the DC power supply unit 50 using a supercapacitor. By doing so, it serves to lower the total power consumption by lowering the power consumption due to the standby power of the DC power supply unit 50 .

On the other hand, as shown in FIG. 6 , in the standby power supply step ( S20 ), the terminal voltage of the supercapacitor 110 being discharged through the power control circuit unit 130 is measured in real time to the supercapacitor 110 . When the terminal voltage becomes the charging restart voltage, the DC power supply unit 50 is restarted through the power control circuit unit 130 to charge the supercapacitor 110 through the charging circuit unit 120 and the controller unit 40 ) characterized in that it further comprises a recharging step (S30) in which the supply of electrical energy is made.

When the supercapacitor 110 is sufficiently charged through this recharging step (S30), the operation of the DC power supply unit 50 is stopped again, and the recharged supercapacitor 110 is discharged to the controller unit 40. supply electrical energy.

At this time, the supercapacitor 110 is a constant current charging method when the LED signage system 100 is in a driving standby state by the charging circuit unit 120 when the terminal voltage of the supercapacitor 110 reaches the charging stop voltage. It is charged up to, and thereafter, it is characterized in that it is fully charged by a constant voltage charging method during the driving state of the LED signage system 100 .

In addition, when a driving signal is input to the controller unit 40 of the LED signage system 100 in the standby power supply step (S20), the controller unit 40 in the power control circuit unit 130 is driven from the standby state to the driving state. 3, the DC power supply unit 50 is operated again by supplying a bias current to the DC power supply unit 50, and the operated DC power supply unit 50 is again operated as shown in FIG. 3, the LED signage system Electric energy is supplied to each driving driver module 30 and the controller unit 40 of 100 to output various contents through the LED light emitting unit 20 .

On the other hand, if the driving signal is not continuously input to the LED signage system 100 even when the charging of the supercapacitor 110 is made above the set terminal voltage, the power control circuit unit 130 of the standby power supply unit 60 blocks the bias current of the DC power supply unit 50 to stop the operation of the DC power supply unit 50, and as the DC power supply unit 50 is stopped, the controller by electric energy stored in the supercapacitor 110 The part 40 operates.

That is, when the supercapacitor 100 is recharged, the DC power supply unit 50 stops operating, and the electric energy stored in the recharged supercapacitor 110 is supplied to the controller unit 40 so that the LED signage system 100 is When the driving standby state is maintained, and a driving command signal is input to the controller unit 40 in this state, as shown in FIG. 3 , the DC power supply unit 50 is operated while the DC power supply unit 50 is operated by the power control circuit unit 130 as shown in FIG. Electric energy is supplied to the driver module 30 and the controller unit 40 .

In the above, the present invention has been described based on a preferred embodiment, but the technical spirit of the present invention is not limited thereto, and it is possible to make modifications or changes within the scope described in the claims. Those of ordinary skill in the art to which the present invention pertains It is obvious to the user, and such modifications or changes shall fall within the scope of the appended claims.

1: LED signage system
10: electronic sign board
20: LED light emitting part
20-1: LED pixel panel
30: drive driver module
40: controller unit
50: DC power supply (SMPS)
60: standby power supply
100: LED signage system to which the present invention is applied
110: super capacitor
120: charging circuit unit
130: power control circuit unit

Claims (6)

LED signboard housing providing exterior and interior space; an LED light emitting unit for forming a rectangular flat output screen by combining a plurality of LED pixel panels made of LED light emitting devices on the front or both sides of the LED sign board in a plane; a plurality of driving driver modules for outputting signals for turning on/off the LED light emitting devices of each LED pixel panel constituting the LED light emitting unit according to the image signal input from the controller unit; a controller unit for inputting an image signal for outputting content output through an output screen of the LED light emitting unit to the driving driver module; a DC power supply unit for supplying DC power to the controller unit and the driving driver module; A standby power providing unit including a supercapacitor for supplying electric energy to the controller unit, a charging circuit unit for charging the supercapacitor with DC power supplied from the DC power supply unit, and a power control circuit unit for controlling the operation of the DC power supply unit In the standby power management method of the LED signage system comprising a;
a power control monitoring step of measuring whether the controller unit is in a standby state and a terminal voltage of the supercapacitor through the power control circuit unit; and
In the power control monitoring step, when the controller unit is in a driving standby state and the terminal voltage of the supercapacitor exceeds the charging restart voltage, the DC power supply unit stops the operation and discharges the supercapacitor to supply electrical energy to the controller unit Including a standby power supply step;
The charging circuit
When the LED signage system is in a driving standby state, the supercapacitor is charged by a constant current charging method, and when the LED signage system is in a driving state, the supercapacitor is charged by a constant voltage charging method; A standby power management method to reduce system power consumption. According to claim 1, wherein the standby power supply step
When the terminal voltage of the supercapacitor becomes the charging restart voltage by measuring the terminal voltage of the supercapacitor being discharged through the power control circuit unit in real time, the DC power supply unit is restarted through the power control circuit unit to operate the super capacitor through the charging circuit unit A standby power management method for reducing power consumption of an LED signage system using a supercapacitor, characterized in that it further comprises; a recharging step of charging the capacitor and supplying electric energy to the controller unit. According to claim 1,
In the standby power supply step, stopping the operation of the DC power supply unit is made by cutting off the bias current supplied to the DC power supply unit; . The method of claim 1, wherein the supercapacitor is
Electric Double Layer Capacitor, Hybrid Capacitor, including any one of Pseudo Capacitor; standby power management method for reducing power consumption of the LED signage system using a supercapacitor, characterized in that. delete The method of claim 1, wherein the supercapacitor is
By the charging circuit unit, the LED signage system is charged in a constant current charging method in a driving standby state until the terminal voltage of the supercapacitor reaches the charging stop voltage, and then fully charged in a constant voltage charging method during the driving state of the LED signage system A standby power management method for reducing power consumption of an LED signage system using a supercapacitor, characterized in that.

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