KR20120133928A - Apparatus and method for detecting failure of led light - Google Patents

Abstract

PURPOSE: An apparatus and method for detecting the failure of an LED device are provided to reduce power consumption by differently supplying power to a normal LED module and a defective LED module. CONSTITUTION: A current converter(100) converts a current applied to an LED module into a voltage. A failure determining unit(200) generates a fault signal about the LED module. A microcomputer(300) receives the fault signal and generates a control signal to control an amount of currents supplied to the LED module. A current control unit(400) controls the amount of currents applied to the LED module according to the control signal. [Reference numerals] (100) Current converter; (200) Failure determining unit; (300) Microcomputer; (400) Current control unit; (500) LED module; (600) Current stabilizer; (700) Power supply device

Description

LED lighting failure detection device and its method {APPARATUS AND METHOD FOR DETECTING FAILURE OF LED LIGHT}

The present invention relates to a technique for accurately diagnosing a failure of a lighting device in a lighting device including a street lamp using LED as a light source. More specifically, the present invention relates to a technique for accurately diagnosing a failure of each module of a lighting device that illuminates by modularizing a plurality of LEDs and controlling the amount of power supplied to each LED according to the diagnosis result.

In street lamps illuminating roads, various lamps used as light sources in conventional street lamps, that is, high-pressure mercury lamps, fluorescent lamps, sodium lamps, etc., have their brightness and diffusion range determined at the time of initial manufacture, so that users cannot adjust them artificially. There is a disadvantage, and also has a short life and very high power consumption.

In view of this, recently, a lighting device using a light emitting diode (LED) as a light source has been proposed, and with the development of technology, a light emitting diode that emits light with low power consumption and high brightness has been gradually developed, There is a trend.

The light emitting diode consumes less power and emits light with high brightness, but also has a longer lifespan than a conventional light source. In addition, a street lamp using a light emitting diode is usually composed of a plurality of LEDs. Accordingly, by accurately checking the state of each LED, research has been made on a technique for implementing and maintaining desired lighting normally.

LEDs can fail due to overcurrent or overvoltage, external voltage and lifetime. In the LED street light in which a plurality of LEDs are lit at the same time, it is difficult to closely detect the failure of each LED, and in particular, the failure of the lighting facility is difficult to recognize unless the reader goes directly and checks with the eyes.

Conventionally, the failure of the LED street light has been used to visually identify when the light of the entire LED street light is turned off. In order to determine the failure of LED street light remotely, LED is modularized and installed, and in order to detect failure by each LED module, by measuring the amount of induction current of LED, it detects failure of each LED module with unlit rate or resistance. A method of determining a failure of each LED module based on the voltage applied to the LED module has been used.

However, the visual discrimination has been pointed out by the problem of time and space, and in the case of LED street light equipped with a current stabilizer, it is pointed out that the problem of detecting the failure of the LED module with the current amount including the induced current amount is very inaccurate. Has been. It is pointed out that measuring the voltage applied to the LED module using a resistor unnecessarily consumes power for fault detection. In addition, even if the failure detection is remote, it has been pointed out that the power is applied to the failed LED module as it is, the waste of power is inevitable.

Accordingly, an object of the present invention is to provide a technique for accurately predicting a failure of each LED module while reducing power consumption in detecting a failure of an LED street light including a plurality of LEDs. In addition, by effectively controlling the power supply when the failure of each LED module is detected from a remote location and replacing the LED, the technology can reduce unnecessary waste of power by supplying different power to the failed LED module and the normal LED module. Its purpose is to.

In order to achieve the above object, LED lighting failure detection apparatus according to an embodiment of the present invention, the current converter for converting the current applied to the LED module to a voltage (CT); A failure determination unit generating a failure signal for the LED module when the converted voltage is less than a preset reference voltage; A microcomputer that receives a fault signal and generates a control signal for controlling an amount of current supplied to the LED module; And a current controller configured to control the amount of current applied to the LED module according to the control signal.

The current controller is provided between an electric double layer capacitor that fills a part of the amount of current applied to the LED module from the power supply device through a connection device, and is a switch that controls charging and discharging of the electric double layer capacitor. And a discharge control unit. At this time, the charge / discharge control unit controls the amount of current charged and discharged to the electric double layer capacitor according to the control signal.

A plurality of LED modules may be installed in the lighting device, and at this time, the current control unit, the current converter, and the failure determination unit are provided for each LED module. In this case, the failure signal may include an identification value of the LED module in which the failure occurs.

The fault signal may include information on the ratio of the number of LED elements in the fault to the total number of LED elements installed in the LED module, wherein the microcomputer reduces the amount of current supplied according to the ratio of the number of LED elements in the fault. Will generate

On the other hand, LED lighting failure detection method according to an embodiment of the present invention, the current converter (ST) converts the current applied to the LED module into a voltage; Generating a failure signal for the LED module when the converted voltage is less than the predetermined reference voltage; Receiving a fault signal by the microcomputer to generate a control signal for controlling an amount of current supplied to the LED module; And controlling, by the current controller, the amount of current applied to the LED module according to a control signal.

In the controlling step, the charge / discharge control unit installed between the connection device and the electric double layer capacitor controls the charge and discharge from the power supply device to the electric double layer capacitor through the connection device. At this time, the controlling step may be a step in which the charge / discharge control unit controls the amount of current charged and discharged in the electric double layer capacitor according to the control signal.

A plurality of LED modules may be installed in the lighting device, wherein the failure signal may include an identification value of the LED module in which the failure occurs.

The failure signal may include information on the ratio of the number of LED elements having a failure to the total number of LED elements installed in the LED module, wherein the generating of the control signal is supplied according to the ratio of the number of LED elements having a failure. Generating a control signal to reduce the amount of current.

According to the present invention, since a current is converted into a voltage using a current transformer (CT) using an inductive element rather than a resistive element, a failure is detected and thus power consumption can be minimized in voltage detection. It works. In addition, the electric double layer capacitor can control the current stably and accurately, and through the control of the microcomputer, there is an effect that can automatically control the amount of current wasted during failure detection.

1 is a block diagram of an LED lighting failure detection apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating the configuration of the current controller and the current converter of FIG. 1.
Figure 3 schematically shows an example of applying the LED lighting failure detection apparatus according to an embodiment of the present invention.
4 is a flowchart of a method for detecting LED lighting failure according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to LED lighting failure detection apparatus and method according to an embodiment of the present invention.

1 is a block diagram of an LED lighting failure detection apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the LED lighting failure detecting apparatus according to the embodiment of the present invention includes a current converter (CT) 100, a failure determining unit 200, a microcomputer 300, and a current controller 400. It features. The current converter 100, the failure determination unit 200, and the current control unit 400 may be installed together with the LED module in the driving unit of the LED module. For example, it may be installed in the driving circuit of the LED module, but the installation position will not be limited thereto.

In addition, according to the characteristics of the LED lighting device, the entire LED lighting device may include a plurality of LED modules 500. Therefore, the LED module 500, the current converter 100, the failure determination unit 200, and the current control unit 400 may exist as a single lighting unit 1000.

Accordingly, the microcomputer 300 may be connected to the failure determination unit 200 and the current control unit 400 of the plurality of units 1000 and 1100. In another embodiment of the present invention, a plurality of microcomputers 300 may exist independently in each unit 1000.

The current converter 100 converts a current applied to the LED module 500 into a voltage. In the embodiment of the present invention, the current converter 100 converts a current into a voltage through an inductive element rather than a resistive element. Accordingly, power consumption can be minimized as compared with when the resistive element is used. On the other hand, it is possible to prevent the phenomenon that the amount of current supplied to the LED module 500 is reduced by the resistive element, it will be possible to supply a stable current to the LED module 500.

The failure determining unit 200 performs a function of generating a failure signal for the LED module 500 when the voltage converted by the current converter 100 is less than a preset reference voltage. The LED module 500 includes a plurality of LED elements. At this time, if each LED device is unable to perform a light emitting function due to a failure, that is, when the LED is turned off, the LED device will not consume power. Accordingly, since the resistance of the LED module 500 is reduced by the number of LED elements in which the failure occurs while the supply of current is constant, the voltage applied to the LED module 500 will be reduced.

Accordingly, the failure determination unit 200 may provide information on voltages when the entire LED elements included in each LED module 500 normally operate according to the type of LED lighting device and the LED elements, and the power consumption of each LED element. It will store information about the voltage along. The LED module 500 may also store a reference voltage that may determine that a failure has occurred. The reference voltage may be a voltage that enables the LED module 500 to determine that a failure occurs and needs to be replaced according to the number of LED devices in which all of the LED elements in the LED module 500 have failed. . For example, the reference voltage may be 60% of the voltage when the LED module 500 operates normally.

That is, the failure determination unit 200 determines that the number of LED devices that a person has failed visually, instead of the failure of more than 40% of the LED devices of the total LED elements included in the LED module 500 based on the applied voltage. At the time, it is determined that the replacement of the LED module 500 will generate a failure signal. Accordingly, it will be possible for a person to check the failure information of the LED lighting device remotely without visually accessing the LED lighting device directly.

The failure determining unit 200 may further include a function of transmitting a failure signal for the LED module 500 to a remote communication device (not shown) so that a user can check it. The remote communication device may be a communication device of a user's mobile communication means, or a communication device of an LED lighting management server.

In another embodiment of the present disclosure, the failure determination unit 200 does not compare the reference voltage and the converted voltage, and generates a failure signal whenever the converted voltage is less than the voltage when the LED module 500 is normally operated. can do. This controls the amount of current supplied to the LED module 500 automatically regardless of whether the LED module 500 is replaced when there is at least one LED element having a failure among the LED elements included in the LED module 500. This is to reduce waste of unnecessary power.

Even in this case, the reference voltage is stored, and when the reference voltage is higher than the converted voltage, only the converted voltage is transmitted, and when the reference voltage is lower than the converted voltage, the information that the LED module 500 needs to be replaced. May be generated simultaneously with the converted voltage. Through this, as well as precise control of the amount of current by transmitting replacement information for the LED module 500 to a remote user, more efficient management of the LED lighting device will be possible.

As mentioned above, a plurality of LED modules 500 may be installed in the LED lighting device. Therefore, the failure determination unit 200, when generating a failure signal, in order to identify which LED module 500 has a failure in the microcomputer 300, to identify the identification value for the LED module 500 has a failure. It may be included in the fault signal together.

The failure determining unit 200 notifies the information about the ratio of the number of LED elements having a failure to the total number of LED elements installed in the LED module 500 in order to reduce the operational load of the microcomputer 300 as well as the converted voltage. Can be included in creation. When the failure determination unit 200 transmits only the converted voltage to the microcomputer 300, the microcomputer 300 may need to calculate the ratio of the number of LED elements in which the failure occurs in order to control the amount of current. If there are many modules 500, the load may be excessive in computation.

The microcomputer 300 receives a failure signal generated by the failure determination unit 200 and uses the same to generate a control signal for controlling the amount of current supplied to the LED module 500.

As mentioned above, the failure signal that may be generated by the failure determination unit 200 includes simple failure information for the LED module 500 and the number of LED elements in which the failure occurs compared to the total number of LED elements included in the LED module 500. Information on the ratio of, the identification value of the LED module 500, the voltage applied to the LED module 500, information indicating that the replacement of the LED module 500 may be included.

Since the microcomputer 300 generates a control signal for controlling the amount of current applied to each LED module 500 by using the received fault signal, the method of controlling the amount of current may vary according to the nature of the fault signal.

For example, if only a simple fault signal determined that the voltage converted by the current converter 100 is lower than the reference voltage is generated and transmitted, the microcomputer 300 supplies the current amount corresponding to the reference voltage to the LED module 500. You can do that. This is because it cannot be determined that a voltage lower than the reference voltage is being applied.

When information on the ratio of the number of LED elements having a failure to the total number of LED elements included in the LED module 500 or information on the voltage applied to the LED module 500 is transmitted, a voltage or a failure occurs accordingly. It will be possible to generate a control signal that reduces the amount of current supplied depending on the ratio of the number of LED elements.

The microcomputer 300 transmits a control signal to the current controller 400 connected to each LED module 500 by using an identification value to control the amount of current supplied to each LED module 500. The current controller 400 controls the amount of current applied to the corresponding LED module 500 according to the control signal of the microcomputer 300.

The current controller 400 may control the amount of current applied to the LED module 500 in a step mode or a linear mode according to the control signal of the microcomputer 300. That is, the type of control signal that may be generated in the microcomputer 300 may belong to a step mode or a linear mode.

The step mode is a mode which can be used when only a simple failure signal is generated, and the case mode is divided into control when the failure occurs and the power supply is cut off when the normal state is largely normal. For example, in the normal state, the amount of current supplied to the LED module 500 through the power supply 700 and the current stabilizer 600 is not reduced, and when the fault signal is received, the amount of current corresponds to the reference voltage. It is a mode of controlling to reduce the control current, otherwise cut off the supply current.

The linear mode can be used when the failure signal includes information on the ratio of the number of LED elements having a failure to the total number of LED elements included in the LED module 500 or information on the voltage applied to the LED module 500. Mode. In this case, the current controller 400 performs a control to proportionally reduce the amount of current so as to correspond to information about the number of LED elements in which a failure occurs or the voltage applied to the LED module 500 according to the control signal of the microcomputer 300. Done.

FIG. 2 is a diagram illustrating the configuration of the current controller and the current converter of FIG. 1. In the following description, portions that overlap with the description of FIG. 1 will be omitted.

2, it can be seen that the current converter 100 is made of an inductive element. The output of the current converter 100 will be the voltage value.

In an embodiment of the present invention, the current controller 400 may include a connection device 410, a charge / discharge control unit 420, and an electric double layer capacitor 430. The connector 410 is a device connected to the connection line between the current stabilizer 600 and the current converter 100 so that the electric double layer capacitor 430 can share the current flowing from the current stabilizer 600 through the current converter 100. Means.

An electrochemical double-layer capacitor (EDLC) 430 is a capacitive element, also called a gold capacitor or super capacitor. The electric double layer capacitor 430 is suitable as an element for controlling the current in the embodiment of the present invention because it can be rapidly charged and discharged, and precise charge and discharge control when used for the current at a low voltage.

The electric double layer capacitor 430 intercepts and stores some of the current supplied to the LED module 500 in the present invention, thereby controlling the amount of current supplied to the LED module 500. In an embodiment of the present invention, a plurality of electric double layer capacitors 430 may exist. In order to supply different amounts of current according to the control signal to the LED module 500, a plurality of electric double layer capacitors 430 are connected, and a control for adjusting the number of electric double layer capacitors 430 charged or discharged according to the amount of current to be controlled. Will be able to perform

Accordingly, the charge / discharge control unit 420 may refer to a switching network installed between the electric double layer capacitor 430 and the connector 410. The charge / discharge control unit 420 controls the connection between the electric double layer capacitor 430 and the connector 410 according to the control signal of the microcomputer 300.

It is assumed that a failure occurs in the LED module 500 and a control signal is received from the microcomputer 300 to control the amount of current applied to the LED module 500 at a predetermined ratio (for example, 60%). At this time, one or more electric double layer capacitors 430 may be provided. The charge / discharge control unit 420 receiving the control signal, the electric double layer capacitor 430 is a part of the current flowing through the power supply line between the current converter 100 from the current stabilizer 600 connected through the wiring 410. Connect the connector 410 and the electric double layer capacitor 430 to be charged in.

At this time, the capacity of the electric double layer capacitor 430 installed will be set to the capacity to receive 40% of the current flowing between the current converter 100 from the current stabilizer (600). To this end, an electric double layer capacitor 430 having a different capacity may be installed for each LED lighting device, or some number of capacitors and the connector 410 of the plurality of electric double layer capacitors 430 may be connected.

Figure 3 schematically shows an example of applying the LED lighting failure detection apparatus according to an embodiment of the present invention. Descriptions overlapping with the descriptions of FIGS. 1 and 2 will be omitted.

Referring to FIG. 3, first, the LED lighting apparatus includes a plurality of lighting units 1000 including a plurality of LED modules 500 and a current converter 100, a failure determining unit 200, and a current control unit 400. . In the exemplary embodiment of the present invention, a plurality of lighting units 1000 are installed on the inclined inner wall of the housing in which the lower part and the upper part are opened and the diameter increases toward the lower part. The LED device 1001 is installed on the outer surface of each lighting unit 1000, and a group of the LED devices 1001 installed in the lighting unit 1000 is defined as the LED module 500.

Each lighting unit 1000 is connected to the power supply 700 through the current stabilizer 600, the failure determination unit 200 of each lighting unit 1000 is connected to the microcomputer 300. As described with reference to FIG. 1, the failure determination unit 200 may transmit failure information to a remote location. Referring to FIG. 3, when the microcomputer 300 receives a failure signal from the failure determination unit 200, the microcomputer 300 may transmit failure information to a remote place through a communication device installed in the microcomputer 300.

4 is a flowchart of a LED lighting failure detection method according to an embodiment of the present invention. In the description of FIG. 4, portions overlapping with the description of FIGS. 1 to 3 will be omitted.

Referring to FIG. 4, first, a step S1 of converting a current flowing through the LED module into a voltage is performed. As described above with reference to FIG. 1, the step S1 may be performed by the current converter 100, and thus, the current may be converted into a voltage without consuming power.

Thereafter, the failure determination unit 200 determines whether the voltage applied to the LED module 500 which is the voltage converted and output from the current converter 100 is less than the reference voltage (S2). As a result of the determination in step S2, if the converted voltage is less than the predetermined reference voltage generates a failure signal. According to the characteristic of the step (S3) of generating a fault signal, the simple fault information that is a result of simply comparing the reference voltage and the voltage of the LED module 500 is generated, or the actual information about the converted voltage is different from the step S2 It may be delivered. In addition, the identification value for the failure LED module 500 may also be selected and sent in step S3. Finally, information on the ratio of the number of LED elements having a failure to the total number of LED elements installed in the LED module 500 may also be generated.

In step S4, the microcomputer 300 having received the failure signal generates a control signal for the amount of current as described in FIGS. 1 and 2. In operation S5, the current controller 400 controls the amount of current applied to the LED module 500 according to the generated control signal. In FIG. 4, when the current controller 400 is composed of the connector 410, the charge / discharge control unit 420, and the electric double layer capacitor 430 as shown in FIG. 2, the voltage of the LED module 500 is increased. When the voltage is lower than the reference voltage, the control of reducing the amount of current supplied to the LED module 500 by charging the electric double layer capacitor 430 is described. However, separate embodiments of the step S3 may vary as described for the functions of the microcomputer 300 and the current controller 400 in FIGS. 1 and 2.

It is to be understood that the above-described embodiments of the present invention are illustrative purposes and do not limit the claims of the present invention. In addition to the embodiments of the present invention, an equivalent invention that performs the same function as the present invention will also fall within the scope of the present invention.

Claims (16)

A current converter CT for converting a current applied to the LED module into a voltage;
A failure determination unit generating a failure signal for the LED module when the converted voltage is less than a preset reference voltage;
A microcomputer that receives the fault signal and generates a control signal for controlling an amount of current supplied to the LED module; And
LED lighting failure detection device characterized in that it comprises a current control unit for controlling the amount of current applied to the LED module according to the control signal. The method according to claim 1,
The current control unit;
An electric double layer capacitor that fills a part of the amount of current applied to the LED module from a power supply through a connection device;
And a charge / discharge control unit disposed between the connection device and the electric double layer capacitor, the charge / discharge control unit which controls a charge and discharge of the electric double layer capacitor. The method according to claim 2,
The charge and discharge control unit,
LED lighting failure detection device, characterized in that for controlling the amount of current charged and discharged to the electric double layer capacitor in accordance with the control signal. The method according to claim 1,
The LED module is provided with a plurality of lighting devices,
And the current control unit, the current converter, and the failure determination unit are provided for each of the LED modules. The method of claim 4,
The fault signal is,
LED lighting failure detection device, characterized in that it comprises an identification value of the LED module has a failure. The method according to claim 1,
The fault signal is,
LED lighting failure detection device, characterized in that it comprises information on the ratio of the number of LED elements having a failure to the total number of LED elements installed in the LED module. The method of claim 6,
The microcomputer,
And a control signal for reducing the amount of current supplied according to the ratio of the number of LED elements in which the failure occurs. The method according to claim 1,
The failure determination unit,
And a function of transmitting the fault signal to a remote communication device. Converting the current applied to the LED module into a voltage by the current converter ST;
Generating a failure signal for the LED module when the converted voltage is less than a preset reference voltage;
Receiving, by the microcomputer, the fault signal and generating a control signal for controlling an amount of current supplied to the LED module; And
And controlling the amount of current applied to the LED module according to the control signal. The method according to claim 9,
Wherein the controlling comprises:
LED charging failure detection method characterized in that the charge and discharge control unit installed between the connection and the electric double layer capacitor to control the charge and discharge from the power supply to the electric double layer capacitor through the connection. The method of claim 10,
Wherein the controlling comprises:
And the charge / discharge control unit controls the amount of current charged and discharged to the electric double layer capacitor according to a control signal. The method according to claim 9,
LED lighting failure detection method, characterized in that the plurality of LED modules are installed in the lighting device. The method of claim 12,
The fault signal is,
LED lighting failure detection method comprising the identification value of the LED module has a failure. The method according to claim 9,
The fault signal is,
LED lighting failure detection method, characterized in that it comprises information on the ratio of the number of LED elements having a failure to the total number of LED elements installed in the LED module. The method according to claim 14,
Wherein the step of generating the control signal comprises:
And generating a control signal for reducing the amount of current supplied according to the ratio of the number of LED elements in which the failure occurs. The method according to claim 9,
And transmitting the failure signal generated by the failure determination unit to a remote communication device.

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