WO2012067336A1 - Led illumination device and auxiliary camera service method for coping with a power outage - Google Patents

Abstract

The present invention relates an LED illumination device and an auxiliary camera service method for coping with power outages. Particularly, a hybrid capacitor or an electric double-layer capacitor (EDLC) is used as a storage battery for the LED illumination device so as to overcome various problems of a secondary battery, so that the LED illumination device can be rapidly charged to provide a clear view in an emergency situation. For this, the LED illumination device comprises a camera module and a memory for easily storing images. A connection request is sent by local area wireless communication for connection with a camera. If the camera is connected through the local area wireless communication, an image is selected and transmitted. If an image signal is transmitted from the camera, the image signal is processed to recognize an identification number of the LED illumination device and set software, updating, turning an illumination device power source on/off, and a sequence for turning the LED illumination device on/off. History information is sent to and received from a central server. The image from the camera is stored as a new image in a local server, and functions such as controlling and crime prevention are performed. The LED illumination device comprises a voltage controller including a low voltage detector of the storage battery. In a situation where power is not supplied, the storage battery, wind, and sunlight are used so that the LED illumination device can be used regardless of the location thereof.

Description

Power failure compensation LED lighting device and auxiliary camera service method

The present invention relates to an electrostatic compensation LED lighting device and an auxiliary camera service method, by using a hybrid capacitor or an electric double layer capacitor (EDLC) in the power storage unit, to overcome various problems caused when using a secondary battery and to emergency The battery is built in the environment where power is not supplied to the blackout compensation LED light, which enables fast charging in a short time so that a lighting device can be easily used in an actual emergency, thereby securing a human vision in an emergency. The process of requesting connection through camera and short-range wireless communication by embedding a device and a camera module that provide an environment that can be used without restriction by using light, and the unique number of each blackout compensation LED lighting device and the unique number Software and updates according to the power, turn on / off the lights, turn on / off The present invention relates to an auxiliary camera service method and apparatus capable of transmitting / receiving order setting and history information from the central server to perform a function such as storing and controlling the latest image from a local server, and controlling security.

In general, the installation of emergency lighting devices to prepare for emergency conditions, such as power outage, in addition to the lighting equipment is basically installed in large buildings or public places, such as the mandatory installation.

The emergency lighting device is designed to be turned on when the external AC power is cut off. In this case, a secondary battery mainly used as a power source of the emergency lighting device is a lithium ion battery or a lithium polymer battery, a lead storage battery, a nickel hydride battery, a nickel cadmium battery, Nickel iron phosphate batteries, lithium iron phosphate batteries and the like.

In addition to the long time it takes to charge the battery, the operating characteristics of the emergency lighting device has a short life.

Recently, a network system capable of performing functions such as remote meter reading, lighting, various digital electronic devices control, and crime prevention is newly developed.

The power control-oriented network control device having an emergency light control function and an infrared (IR) communication function applied to the network system can be said to be an improvement over the prior art.

As described above, the prior arts of camera functions of image storage, control, and crime prevention are called Power Line Communication Transmitter (PLC TX), and Power Line Communication Receiver (PLC RX). .).

It consists of a monitor and connects the camera image to PLC TX. When the PLC TX is transmitted using the camera's own power line, the image is received from the PLC RX mounted on the front end of the monitor and connected to the monitor Video In terminal. Since it is displayed on the monitor, the PLC TX and PLC RX must be separately installed between the camera and the monitor, thereby causing a burden of cost and installation trouble.

On the other hand, in the image storage, control, and security camera functions, the manufacturer or service provider provides the latest software and contents for each product from time to time, so that the user can receive the latest software and contents with the latest information. In addition to the need to directly access the online to perform a predetermined procedure, there is a problem that the user is difficult to check before accessing the online directly, and the utilization of power failure during the power failure.

Therefore, a more practical and advanced use of a battery that overcomes the above-mentioned problems of the secondary battery so that the emergency lighting device can be easily used in an actual emergency and enables fast charging in a short time to ensure human vision in an emergency Development of LED lighting of a power failure compensation function is needed

The present invention has been made in order to overcome the problems of the above-described technology, the storage device used in the lighting device is provided with any one or more of a hybrid capacitor, an electric double layer capacitor and a hybrid battery, lithium iron phosphate battery, lithium polymer in the emergency lighting device The main objective is to ensure more stable operation of the

In addition, an additional object of the present invention includes a light measuring sensor so that the lighting device is not operated when the amount of light supplied from the outside is sufficient even in an emergency, so that the amount of charging power of the battery can be more efficiently used.

Further, an additional object of the present invention is to adjust the illuminance of the LED bulb when light is supplied from the outside in an emergency so as to save more power stored in the battery.

A further object of the present invention is to use a reverse current prevention diode and a protection resistor to prevent damage to the battery and battery errors.

Further, an additional object of the present invention is to determine the time when the power outage is to continue when the power failure in the building so that the illumination is not turned off during the time of the power outage according to the time and the amount of power charged in the battery.

Further, an additional object of the present invention is to convex a specific part of the reflector used in the lighting device so that the emergency evacuation side can be brighter than the other part, so that the person in the building can find the emergency evacuation path more intuitively during an emergency. Do it.

Further, another object of the present invention is to provide a method and apparatus for controlling power failure compensation LED lighting and an auxiliary camera in a smart phone.

Further, an additional object of the present invention is to check the unique number of the power failure compensation LED light in the area where the wireless LAN device is installed so that it can be updated and download the stored image.

Further, an additional object of the present invention is to embed the storage battery in an environment where power cannot be received, and to use the wind power and the solar cell without restriction of a place.

The present invention for achieving this object is connected to the external power source in one portion is formed in the body of the enclosure shape is formed with a socket bolt for receiving AC power, and the assembly is coupled to the opposite side portion of the side the socket bolt is formed in the body An electrostatic compensation function LED lighting device made of a reflector, comprising: a plurality of LED modules formed inside the body such that a plurality of LED bulbs are directed toward the reflector; A converter for converting AC power input from the outside into the DC power through the socket bolt; A storage battery formed in the body; A controller which charges the storage battery using an external power source and controls the operation of the LED module with the power charged in the storage battery in an electrically connected state with the LED module; wherein the control unit charges the storage battery with an external power source. A charging module to be formed, a light measuring sensor formed on one side of the body to sense a current light quantity, a voltage sensing module to sense a voltage of an external power source, a light quantity sensing module to receive a light quantity value from the light measuring sensor, and When the voltage value is received from the voltage sensing module and the voltage value falls below a predetermined level, the light quantity sensing module receives the light quantity value and determines whether to operate the LED module according to the light quantity value to generate an operation signal. Module and an LED that is supplied to the storage battery by receiving an operation signal from the determination module And a control module for controlling the module.

The storage battery is provided with at least one of a hybrid capacitor, an electric double layer capacitor, a hybrid battery, a lithium iron phosphate battery, and a lithium polymer having different configurations of positive and negative electrodes.

The determination module may further include an illuminance determination unit configured to receive the light quantity value from the light quantity detection module and determine an illuminance of the LED light according to the light quantity value to generate an illuminance value. The illuminance control unit further receives an illuminance value and controls an amount of power output from the battery to the LED module.

In addition, the control unit is interlocked with the Korea Electric Power Corporation server through the wireless communication unit via the communication unit for determining the power failure time information of the building and the information receiving module consisting of an input unit for directly receiving the power failure time information from the construction personnel, and charge the battery The apparatus further includes a charge amount detecting module configured to determine the amount of power supplied and to generate charge amount information, wherein the control module receives each information from the information receiving module and the charge amount determining module, during the time information based on the charge amount information. The apparatus further includes an output amount control unit for grasping an output amount per unit of time for maintaining an LED light-on state and controlling a power output amount output from the battery to the LED module.

In addition, the reflector is formed in a fan shape, but a specific portion is formed to be convex inward so that the light emitted from the LED bulb is concentrated and refracted by the specific portion, so that the emergency evacuation point is brighter than other points. .

The reflector is formed of a material having a property of expanding when heat is applied thereto, and a heat storage unit for concentrating and storing heat generated when the LED bulb is turned on the reflector, and a portion provided with the light concentrator. And a partition unit for separating the other parts from thermal exchange, and a heating wire connecting the heat storage unit and the partition unit to transfer heat of the heat storage unit to the partition unit. The module further includes a heat flow control module for receiving the charge information from the module to transfer the heat stored in the heat storage unit to the compartment when the charge amount of the battery is less than a predetermined level. The part is expanded so that the light concentrator is variably flowed according to the amount of charge of the battery. The.

The electrostatic compensation function LED lighting device further includes a flow control unit including a reverse current prevention diode that prevents reverse current from a current input to the storage battery from outside and a protection resistor that prevents rapid flow of current.

Meanwhile, the present invention relates to an image, a software, and a download system in a power failure compensation LED lighting device and an auxiliary camera service method in a wireless LAN area, each of which has a unique number and images, software, contents, and the like according to the unique number. A central server for storing and managing update history information, and transmitting and receiving update history information according to a unique number of a local server and a power failure compensation LED lighting device installed in the wireless LAN area through an Internet network; Installed in the wireless LAN area, the unique number of the blackout compensation LED lighting device, software, video, content and update history information according to the unique number is received and stored from the central server, the blackout compensation LED lighting device Determines whether or not the update target by transmitting and receiving a wireless signal for updating the image, software, and content with the power failure compensation LED lighting device through a wireless LAN device installed in the installed area, and if the update targets the image, A local server transmitting software and contents, and transmitting update history information of the updated power failure compensation LED lighting device to a central server; And after receiving a connection request signal for updating image, software, and content from a local server through the wireless LAN device, and transmitting a connection permission signal or a connection rejection signal according to the request, and the blackout compensation LED lighting device is an update target. A power failure compensation LED lighting device configured to receive an approval request signal from a local server, transmit an approval signal according to the local server, and then receive and store stored images, software, and content from the local server; It includes.

The present invention relates to an auxiliary camera service method of a power failure compensating LED lighting device in a wireless LAN area, the method comprising: receiving a connection request signal for receiving an image, software, and content update from the wireless LAN device. Transmitting the unique number of the power failure compensation LED lighting device to a local server through the wireless LAN device; Determining whether the corresponding power failure compensation LED lighting device is an update target by comparing the unique number of the power failure compensation LED lighting device received by the local server with history information of the previously stored power failure compensation LED lighting device; As a result of the determination of the step, when the update target, transmitting, by the local server, an update approval request signal through the wireless LAN device to the power failure compensation LED lighting device; Transmitting the approval signal to the local server through the wireless LAN device when the power failure compensation LED lighting device intends to approve an update; Transmitting, by the local server, stored images, software, and contents of the power failure compensation LED lighting device through the wireless LAN device; Receiving and storing the latest image, software, and content by the power failure compensation LED lighting device; And after the local server stores the updated update history information, transmitting the updated update history information to the central server through an internet network. It includes.

According to a further object of the present invention, when the connection request is received from the smart phone, a process of connecting through a wireless LAN, and selecting and transmitting an image when connected to the camera through the wireless LAN, A controller for controlling a function of processing and outputting the video signal when a selected video signal is received from the camera; A video signal processing module for processing the received video signal, a display unit for outputting a video signal processed by the video signal processing module, and a wireless LAN transceiver for transmitting and receiving the wireless communication; A control unit for controlling a function of transmitting a photographed video signal to the smart phone by photographing a corresponding area when a selected image is received when the connection request is received from the smart phone; It includes a wireless transceiver for transmitting and receiving the WLAN signal.

According to a further object of the present invention, a method for checking an image by connecting to a camera in a smart phone includes: requesting a connection through a short range wireless communication with the camera when an image receiving application is executed; And selecting and transmitting an image when connected to the camera through the wireless LAN, and processing and outputting the image signal to a display unit when the selected image signal is received from the camera.

And, according to a further object to achieve the above object of the present invention, the electrostatic compensation LED lighting device is a converter for converting AC power into DC power; A controller which charges the storage battery using an external power source and controls the operation of the LED module with the power charged in the storage battery in an electrically connected state with the LED module; The control unit is composed of a voltage sensing module for sensing the voltage of the external power source, and a low voltage control unit to increase the life of the secondary battery, the rotating shaft and the blade formed on one side of the body can be rotated by wind power; Using wind turbines and solar cells that generate electricity generated by wind power, it provides an environment that can be used without restriction of places.

In addition, according to a further object of the present invention, the electrostatic compensation LED lighting device is a constant current and constant voltage element for controlling the current and voltage input to the storage battery from the outside, the hybrid capacitor, the electric double layer capacitor and the hybrid battery Charging unit to prevent the rapid flow of current and voltage to the; Includes additional

According to the electrostatic compensation LED lighting device and the auxiliary camera service method according to the present invention,

1) By using an electric double layer capacitor or a hybrid capacitor as a storage battery, it can maintain a stable storage state, overcome the shortcomings of the secondary battery can be quickly charged and discharged with a large current, in the event of a power failure in the building 1 By configuring the secondary battery and the secondary battery, the effective lighting time can be increased, and the life of the secondary battery can be extended by the low voltage control of the battery.

2) Even if there is a sufficient amount of light supplied from the outside even in an emergency including an optical measuring sensor, the lighting device is not operated so that the amount of charging power of the battery can be used more efficiently.

3) By convexly forming a specific part of the reflector so that the emergency evacuation side is brighter than other parts, it is not only to reduce human accidents by allowing humans to find the emergency evacuation path more intuitively.

4) If there is a power failure in the building, it is effective to grasp the time that the power failure will last so that the lighting does not turn off during the power failure according to the time and the amount of power charged in the battery.

5) Built in the battery in an environment that can not receive power, using the wind and solar power can be used without restrictions of places,

6) By receiving the image of the camera via a wireless LAN output to the smart phone by the installation of the blackout compensation LED lighting auxiliary camera there is an effect that can be serviced using a smart phone.

7) Users do not need to go online to download or perform a separate outage compensation LED lighting device update check by the user, and enter the wireless LAN area to access the images, software and contents of the outage compensation LED lighting device. There is a unique effect that can be automatically provided.

8) In case of power failure in the building, the LED lighting auxiliary camera will be operated according to the amount of power charged in the battery, and the lighting will not be turned off during the time of power failure.

1 is a view showing the configuration of a first embodiment of an electrostatic compensation LED lighting apparatus according to the present invention,

2 is a circuit diagram showing a schematic configuration of a flow control unit 31 of the electrostatic compensation LED lighting device of FIG.

3 is a block diagram showing the configuration of a control unit of the electrostatic compensation LED lighting device of FIG.

4 is a flow chart showing the operation of the control unit of the electrostatic compensation LED lighting device of FIG.

5 is a view showing a process in which the converter power is applied in the electrostatic compensation LED lighting device of FIG.

6 is an enlarged cross-sectional view showing the light reflection angle of the LED lamp using a conventional reflector;

7 is an enlarged cross-sectional view showing an embodiment of a reflector of the electrostatic compensation LED lighting device according to the present invention and the reflection angle of light according thereto;

8 is a view schematically showing a power failure compensation LED lighting auxiliary camera service system according to the present invention;

9 is an overall flowchart of a method of downloading an image, software, and content of an electrostatic compensation LED light auxiliary camera according to the present invention;

10 is a block diagram of a smartphone and a power failure compensation LED lighting auxiliary camera according to an embodiment of the present invention,

11 is a procedure of the smart phone for outputting the image of the LED power assist compensation camera according to an embodiment of the present invention,

12 is a flowchart of a power failure compensation LED lighting auxiliary camera providing an image through short-range wireless communication in a smart phone according to an embodiment of the present invention;

13 is a perspective view of an installed plan view of the electrostatic compensation LED lighting auxiliary camera according to the present invention and an installation example of the secondary power storage unit;

14 is an enlarged cross-sectional view of a built-in perspective view of a power failure compensation LED lighting and a wind generator according to the present invention;

Figure 15 is a block diagram showing the configuration and operation of the control unit built in the electrostatic compensation LED lighting device according to the present invention,

16 is a schematic circuit diagram of an electrostatic compensation LED lighting device according to the present invention.

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

1 is a view showing the configuration of a first embodiment of the electrostatic compensation LED lighting apparatus according to the present invention.

As can be seen from Figure 1, the electrostatic compensation LED lighting device according to the present invention is formed of a housing in which the components such as the storage battery 30 is seated therein, connected to an external power source in one portion to receive AC power The body 10 having the socket bolt 11 formed thereon, and the reflecting plate 40 reflecting the linear light of the LED bulb are assembled to the opposite side portion of the body 10 on the side where the socket bolt 11 is formed, thereby being illuminated. Forming the appearance of the mechanism, the LED module 20 including a first bonding portion which is mounted in a plurality of radially so that the LED bulb toward the reflecting plate 40, and acts as a medium electrically connected to the controller 100 to be described later And, made of any one of an electric double layer capacitor (EDLC) or a hybrid capacitor including a storage battery 30 connected to the control unit 100 to be described later, the second junction connected to the first junction of the LED module 20 The power supplied by the storage battery group 30 composed of a control unit 100 that controls the operation of the LED module 20.

In particular, the body 10 is configured to be made of a polar carbonate (PC) material that transmits light but has a strong resistance to external shocks, thereby protecting internal components more safely from an impact applied to a lighting device during a fire or power failure. Make sure

The socket bolt 11 of the body 10 is adhesively bonded to a portion of the body 10, in which case the adhesive used is epoxy resin and so that the adhesive force is not lowered by heat emitted from the light bulb when the LED bulb is in operation. It is most preferable to use an adhesive based on pigments, additive papers, and polyamide curing agents.

In addition, the first junction portion and the second junction portion connecting the LED module 20 and the control unit 100 may be made of a bolt type or a pin type or the like so that the LED module 20 and the control unit 100 may be electrically connected to each other. When an abnormality occurs in the LED module 20 equipped with an LED bulb, only the LED module 20 can be easily replaced and used.

In addition, the LED bulb of the LED module 20 may be formed in a radial shape so that a plurality of LED bulbs can be mounted in multiple layers rather than in a single layer configuration to further double the illuminance of the lighting device according to the present invention.

To describe the features and differences between the electric double layer capacitor (EDLC) and the hybrid capacitor used as the storage battery 30 in the electrostatic compensation LED lighting device according to the present invention, the electric double layer capacitor (EDLC) is a contact interface between the electrolyte and the electrode in the electrochemical system. An electric double layer in the capacitor, also called a super capacitor, has the intermediate characteristics of the battery and the electrolytic capacitor.

Electric double layer capacitors (EDLC) are regarded as next generation energy storage devices because they have several hundred times more storage energy than conventional capacitors, 10 times more charging and discharging speeds, and longer lifespans than rechargeable batteries.

In other words, the electric double layer capacitor has characteristics that are not present in nickel-hydrogen secondary batteries or lithium-ion secondary batteries.In addition to being capable of rapid charging and discharging with a large current, the performance of the double-layer capacitor can be repeated even after 500,000 charges and discharges are repeated. It has the advantage of not changing. Here, EDLC (Electronic Double Layer Capacitor) is a carbon such as activated carbon

It is composed of positive material mainly composed of positive electrode, polarized electrode of negative electrode and nonaqueous electrolyte, and it is known that the composition of nonaqueous electrolyte has a great influence on voltage resistance and capacitance. It is used for backup, auxiliary power when changing batteries of portable devices, and storage power for clocks and indicator devices using solar cells.

However, the cylindrical EDLC that is commonly used is difficult to lower the electrical resistance of the contacts due to the difficulty in installing the lead wires, and it is pointed out that the filling rate decreases due to the large air gap during assembly, and even in the case of the square shape, the performance of the capacitor is good but difficult to manufacture. Therefore, there is a problem that the price is expensive.

To describe the characteristics of the hybrid capacitor, it is possible to conserve excessive energy for a long time than an electric double layer capacitor (EDLC) by using an ionic liquid of quaternary ammonium salt and quaternary phosphonium salt having at least one alkoxy alkyl group as an electrolyte. In addition, energy and power density may be improved, and electrical stability is known to be more excellent because it has a function similar to that of a secondary battery having high capacity and high rate characteristics of an electrode. In recent years, with the rapid growth of emergency lighting devices, the complexity of the functions of portable devices and equipment is changed from the conventional analog method to the digital method. The portable emergency lighting device according to this trend requires higher power, smaller size, lighter weight, and cheaper price than the existing battery, and especially has a characteristic that a momentary high current pulse flows periodically with a charged power supply, and a high power hybrid battery capable of instantaneous large current pulse discharge. In particular, the present invention relates to a high output hybrid battery having a long current characteristic as well as a large current pulse discharge by parallel hybridizing a high output electric double layer capacitor made of a large area in a lithium primary battery.

The storage battery 30 applied to the present invention includes a hybrid capacitor, an electric double layer capacitor (EDLC) and a high output hybrid battery, a lithium iron phosphate battery, and a lithium polymer, having different configurations of positive and negative electrodes, as described above. It may be provided as any one or more of, and may be provided as an electric double layer capacitor (EDLC) having a circular housing, as shown in Figure 1, the shape and type of the capacitor is not limited to this to store energy Of course, various batteries may be applied.

In addition, when the battery 30 uses a hybrid capacitor or an electric double layer capacitor, a reverse current prevention diode 31a for preventing a current from flowing backward on the battery 30 and a charge current to the battery 30 are rapidly increased. It may be input so as to include a flow control unit 31 made of a protection resistor (31b) so that the storage battery 30 is not damaged due to overvoltage.

As shown in FIG. 2, the flow control unit 31 receives two reverse current prevention diodes 31a and one in the process of charging a battery 30 and outputting the voltage to the voltage output terminal. By using the protection resistor 31b, the current is prevented from being reversed in the battery 30 and the resistance of the current flowing into the battery 30 is prevented so that the battery 30 is not damaged by the inflow of overcurrent. .

The reverse current prevention diode 31a and the protection resistor 31b may be replaced with other elements that perform a similar function within the purpose range of the flow control unit 31.

In order to control the lighting device having the above-described configuration to be turned on in an emergency after being not normally operated, the electrostatic compensation LED lighting device according to the present invention is provided with a controller 100.

3 is a block diagram illustrating a configuration of a control unit of the electrostatic compensation LED lighting device of FIG. 1, and FIG. 4 is a flowchart illustrating the operation of the control unit of the electrostatic compensation LED lighting device of FIG. 1.

3 to 4, the detailed configuration and operation of the controller 100 will be described. The controller 100 includes a charging module 110, an optical measuring sensor 12, a voltage sensing module 120, and an amount of light sensing. Module 130, determination module 160, and control module 170.

The charging module 110 receives the signal from the voltage sensing module 120 and charges the storage battery 30 through a separate power circuit when an external power source is an AC power source.

The light measuring sensor 12 is applied to any one of a sensor such as a photo sensor, a CDS, a solar module, etc., and is installed on one side of the body 10 to sense a current amount of light. This is because the lighting device does not need to be operated when the amount of light from the sun is low enough even during an emergency such as a power failure or a fire, so that the current light value is sensed to control the lighting device more efficiently.

On the other hand, the charging module 110 and the LED module 20 is preferably provided with a separate heat sink to release heat to the fan.

The voltage sensing module 120 detects a voltage of a power supplied from the outside through the socket bolt 11 to detect a power failure or a low voltage state to generate a voltage value.

The light quantity sensing module 130 serves to receive the light quantity value from the light measuring sensor 12, and at this time, the light quantity sensor 12 is connected to the light measuring sensor 12 through a thin cable to receive the value.

The determination module 160 determines whether the LED module 20 operates by receiving each signal from the voltage sensing module 120 and the light quantity sensing module 130, and the voltage value received from the voltage sensing module 120. If it falls below a certain level is to determine the light quantity value in the sequential process to finally determine the on / off of the LED module 20.

In addition, the determination module 160 may include an illuminance determining unit 161. The illuminating determination unit 161 adjusts the illuminance according to the light quantity value transmitted from the light quantity detecting module 130. If there is no light flowing in the current building, the light intensity of the LED bulb is maximized, and if there is a slight amount of incoming light, the LED light bulb adjusts the light intensity of the LED to a certain level to generate a light intensity value. To use the power stored in the more efficient operation.

The control module 170 receives the signal from the determination module 160 and controls the LED module 20. When the on signal is received, the control module 170 outputs power stored in the battery 30 to the LED module 20. Do it. The control module 170 may prevent the damage of the LED module 20 and at the same time ensure a stable driving state by maintaining the voltage output from the battery 30 to the LED module at a predetermined level. do.

In addition, the control module 170 may further include an illuminance control unit 171. The illuminance control unit 171 receives an illuminance value from the illuminance determining unit 161 and according to the corresponding value, the storage battery 30 In the role of controlling the amount of power output to the LED module 20.

That is, the operation of the electrostatic compensation LED lighting device according to the present invention having the above-described configuration will be described with reference to FIGS. 4 to 5, and usually, the voltage sensing module 120 detects whether an AC / DC power supply of an external power source is present. If the corresponding power is DC power, power is supplied directly to the charging module 110, and in the case of AC power, the converter converts the power into DC power to charge the storage battery 30 through the charging module 110. To charge.

However, when an external power supply is cut off due to a power failure or an emergency or the voltage decreases to a predetermined level or less, the determination module 160 determines the light quantity through the light quantity sensing module 130 and the light quantity is also below a predetermined level. By supplying the power stored in the storage battery 30 to the LED module 20 to turn on the LED bulb to be easily lit in an emergency.

On the other hand, the LED module 20 is electrically connected to the boosting unit and also to the power storage unit.

The power storage unit is electrically connected to the pressure reducing unit.

Here, when converter power is applied to the decompression unit, the decompression unit decompresses the converter power, and then transmits the decompressed converter power, that is, the converter power having a low voltage to the power storage unit.

At this time, the power storage unit stores the low voltage, and then transmits the low voltage to the LED module. The LED module transmits the converter power to the booster.

Accordingly, the booster boosts the low voltage transmitted from the LED module to the high voltage.

In addition, as shown in FIG. 7, the reflecting plate 40 is not formed to have a flat thickness like a general reflecting plate 40, but is formed convexly in a predetermined direction so that light incident to the reflecting plate 40 is incident in a specific direction. By refracting and reflecting, the light can be focused on a specific part of the building floor.

It is said that the above-described configuration can achieve a predetermined purpose, but when there is a situation in which power is not supplied to the inside of the building for a predetermined time due to a power outage or electric work of a building that is planned in power construction, In order to allow the LED bulb to be turned on during the corresponding time according to the amount of power charged in the 30, the control unit 100 further includes an information receiving module 140 and the control module 170 includes an output quantity control unit. 172 may be additionally included.

The information receiving module 140 is composed of a communication unit 141 and the input unit 142, the communication unit 141 is to work with the Korea Electric Power Corporation server to determine the power failure time of the building. In other words, the communication unit 141 is connected to the KEPCO server wirelessly through a wireless communication network such as the Internet to grasp the planned outage time provided by the KEPCO.

The input unit 142 allows construction personnel to directly input the corresponding time information when an electric project or the like is planned. The input unit 142 preferably receives information via a known means such as a button or a switch.

At this time, the power required to operate the communication unit 141 to the input unit 142 may be charged with the power charged in the storage battery 30, so that the corresponding time can be grasped and prepared before power failure occurs. It will be possible to do this, in which case additional configuration, that is, a timer and a separate medium to store the information will have to be provided.

The charging amount grasping module 150 generates charging amount information by grasping the charging amount charged in the storage battery 30 and functions in conjunction with the charging module.

The output amount control unit 172 is further included in the control module 170, and receives the time information from the information receiving module 140, receives the charge amount from the charge amount determining module 150 is stored in the storage battery 30 The amount of power allocated for the time corresponding to the time information is divided based on the charge amount, i.e., an appropriate output amount per time unit, that is, per hour or minute, for maintaining the LED light bulb is turned on during the time information. By grasping and controlling the amount of power output from the storage battery 30 to the LED module 20 according to the output information.

In this case, the additional configuration of the battery 30 prevents the case where the battery 30 is not sufficiently charged and the LED bulb is turned on in case of emergency and the bulb is turned off before the external power is restored, causing inconvenience to use. do.

6 is an enlarged cross-sectional view showing the light reflection angle of the LED lamp using a conventional reflector, the reflector 40 is formed in a fan-shaped shape to evenly bend the reflective LED bulb light evenly to illuminate a wide area.

7 is an enlarged cross-sectional view showing an embodiment of the reflector of the electrostatic compensation LED lighting device according to the present invention and the reflection angle of light according to the present invention. As shown in FIG. 7, the reflector 40 used in the present invention has a fan shape. In addition, the reflector plate 40 includes a light concentrator 40a formed to convex a specific portion inwardly, thereby changing the refraction of the light of the LED bulb so that the light is concentrated at a specific point so that the corresponding portion is another portion. Make it look brighter.

This is to intuitively inform the user where the emergency escape route is formed in a dark situation in an emergency. More specifically, the light intensity is concentrated on the side where the emergency escape route is formed (light concentration point on the drawing). The area is shown brighter.

The light concentrator 40a may be designed differently according to the point where the electrostatic compensation LED lighting device is installed according to the present invention so as to more brightly illuminate the emergency escape area closest to the point where the lighting device is installed.

In particular, the amount of light to be concentrated at this time does not exceed a certain amount, that is, by adjusting the illuminance below a certain level, the heat is generated by the concentration of light to prevent the fire or other accidents caused by this, of course.

By applying the reflector plate 40 further provided with the light concentrator 40a, a person in a building during an emergency can find an emergency evacuation path more intuitively at a time of embarrassment, thereby enabling a safer evacuation so that a human accident can occur. It provides a characteristic that can greatly reduce the

Meanwhile, as illustrated in FIGS. 8 to 9, the power failure compensation LED lighting auxiliary camera service system includes a central server 310, a local server 320, and a power failure compensation LED light auxiliary camera 330.

Specifically, the central server 310 stores and manages the MAC address (Media Access Control Address) of each of the blackout compensation LED lighting auxiliary cameras 330, images, software, contents and update history information according to the MAC address, and the Internet. It performs a function of periodically transmitting and receiving update history information according to the MAC address of the local server 320 and the power failure compensation LED lighting auxiliary camera 330 installed in the wireless LAN area through the network.

Here, the MAC address is used as a unique identification number of each of the power failure compensation LED lighting auxiliary camera, and is stored and managed in the central server 310 and the local server 320 together with the update history information according to the MAC address.

Therefore, hereinafter, the MAC address is referred to as a 'unique number'. The update history information includes the number of update services per week / month / year for each image, software, and content.

In addition, the local server 320 is installed in a wireless LAN area, and receives the unique number of the power failure compensation LED lighting auxiliary camera 330, and the image, software, content and update history information according to the unique number from the central server 310. And transmit and receive a wireless signal for updating image, software, and content through the wireless LAN device 200 with the power failure compensation LED light auxiliary camera 330 in the region where the power failure compensation LED light auxiliary camera 330 is installed. Determine whether it is an update target, and if it is an update target, transmit images, software, and content to the power failure compensation LED light auxiliary camera 330, and update update history information of the updated power failure compensation LED light auxiliary camera 330 by a central server ( 310), and

Receives the image, software, content and update history information according to the unique number of the power failure compensation LED light auxiliary camera 330 from the central server 310 through the Internet (Internet) network, updated power failure compensation LED light auxiliary camera 330 Image, software and content and update history information according to the unique number of the blackout compensation LED lighting auxiliary camera 330 received through the first communication unit 210 for transmitting the update history information of) to the central server 310. By managing transmission and reception of the image update information storage unit 220, the power failure compensation LED lighting auxiliary camera 330 and the wireless LAN device 200, the connection request signal and the access permission signal for updating the image, software, power failure compensation Receives a unique number from the LED lighting auxiliary camera 330, and transmits the image, software and content according to the unique number to the blackout compensation LED lighting auxiliary camera 330, The second communication unit 230 for transmitting a communication cutoff signal to the power failure compensation LED light auxiliary camera 330 when it is not an update target or receives an approval rejection signal from the power failure compensation LED light auxiliary camera 330, and the second communication unit. By comparing the unique number received from the blackout compensation LED lighting auxiliary camera 330 with the update history information of the corresponding blackout compensation LED lighting auxiliary camera 330 stored in the image update information storage unit 220, the corresponding power outage The compensation LED lighting auxiliary camera 330 includes an image update target determination unit 240 that determines whether the update target.

That is, by using the unique number received by the local server 320 from the power failure compensation LED lighting auxiliary camera 330, the image update target determination unit 240 of the local server 320 to the image update information storage unit 220. By searching the previously stored history information, it is determined whether the update target.

After receiving the connection request signal for updating image, software, and content from the local server 320 through the wireless LAN device 200, the power failure compensation LED lighting auxiliary camera 330 receives the access permission signal or the access rejection accordingly. When the signal is transmitted, and the power failure compensation LED lighting auxiliary camera 330 is an update target, after receiving the approval request signal from the local server 320 and transmits the approval signal according to the local server 320, the local server ( 320 to receive and store the latest image, software and content from the.

In this case, the electrostatic compensation LED lighting auxiliary camera 330 performs a normal camera function, a description of the configuration of a general camera will be omitted.

For reference, the wireless LAN device 200 is installed in the wireless LAN area as described above, and performs a function of transmitting and receiving wireless signals generated from the local server 320 and the power failure compensation LED lighting auxiliary camera 330.

9 is a view illustrating a method of downloading images, software and contents of a camera in a wireless LAN area using a system consisting of a central server 310, a local server 320, and a power failure compensation LED lighting auxiliary camera 330 according to the present invention. As a whole flow chart, the connection request signal for updating the image, software and content is transmitted through the wireless LAN device 200 in which the power failure compensation LED lighting auxiliary camera 330 is installed in the wireless LAN area as shown in FIG. The power failure compensation LED lighting auxiliary camera 330 receiving the connection request signal from the LAN device 200 is transmitted to the local server 320 through the unique number / ID wireless LAN device 200 of the camera according to the connection request signal. (P2).

Thereafter, the image update target determination unit 240 of the local server 320 receives the unique number and image of the received power failure compensation LED lighting auxiliary camera 330 and the corresponding power failure compensation LED previously stored in the image update information storage unit 220. By comparing the history information of the lighting auxiliary camera 330, it is determined whether the corresponding blackout compensation LED lighting auxiliary camera 330 is an update target (P3).

As a result of the determination of the third step P3, if the update target, the second communication unit 230 of the local server 320 transmits the update approval request signal through the wireless LAN device 200 (P4), the power failure compensation LED lighting auxiliary camera If the 330 wants to approve the update, it transmits the approval signal through the wireless LAN apparatus 200 (P5).

In addition, the second communication unit 230 of the local server 320 is the latest image, software and content of the corresponding power failure compensation LED lighting auxiliary camera 330 stored in the image update information storage unit 220 via the wireless LAN device 200. And transmit (P6), the blackout compensation LED lighting auxiliary camera 330 receives and stores the latest software and content (P7).

Thereafter, the image update information storage unit 220 of the local server 320 stores the updated update history information, and then transmits the updated update history information to the central server 310 through the Internet network (P8). The central server 310 stores the transmitted image, update history information (P9).

In addition, when the determination result of step P3 is not an update target, the second communication unit 230 of the local server 320 transmits a communication cutoff signal to the power failure compensation LED lighting auxiliary camera 330 (P10).

In addition, when the power failure compensation LED lighting auxiliary camera 330 does not want to approve the update in step P5, the device transmits an approval rejection signal through the wireless LAN apparatus 200 (P11), and receives the approval rejection signal from the local server. The second communication unit 230 of 320 transmits a communication cutoff signal to the power failure compensation LED lighting auxiliary camera 330 (P12). In addition, when the communication and power is cut off, the image stored in the built-in memory of the power storage of the power failure compensation LED lighting auxiliary camera 330 is separately stored (P13), and the internal memory video signal is restored during the communication and power recovery. Transmit (P14).

Here, the internal memory may be an SD, MMC, MS, CF card, or the like.

In addition, in the above description, for example, the configuration of the method for servicing a power failure compensation LED light assistance camera in a wireless LAN region has been described, for example, by receiving an image of the power failure compensation LED illumination auxiliary camera 330.

In the smart phone of the present invention to explain the method and apparatus for outputting the image of the power failure compensation LED light auxiliary camera service method through the short-range wireless communication,

Here, the short range wireless communication may be a wireless LAN, Zigbee, Bluetooth, Ultra Wideband, or the like.

10 is a block diagram of a smart phone and a power failure compensation LED lighting auxiliary camera according to an embodiment of the present invention, wherein the smart phone includes a control unit 100, a short range wireless transceiver 406, and an image processor A 403. ), A display unit 407, and an input unit 408.

Referring to FIG. 10, first, the control unit 100 controls the overall operation of the smart phone, and in addition to the normal function, the auxiliary camera application is executed according to the present invention to the camera through the short range wireless transceiver 406. When connected, it controls and processes the function of receiving and outputting the image according to the unique number or ID of the electrostatic compensation LED lighting auxiliary camera 330 input by the user from the electrostatic compensation LED lighting auxiliary camera 330.

The short range wireless transceiver 406 encodes a signal input from the controller 100 and transmits the signal to the power failure compensation LED lighting auxiliary camera 330 through short range wireless communication, and transmits a signal received through the short range wireless communication. Process and transmit to the control unit 100.

The image processor A 403 encodes an image signal input from the electrostatic compensation LED lighting auxiliary camera 330 through short-range wireless communication and outputs the image signal to the display unit 407 or the controller 100.

The display unit 407 displays status information, limited numbers and letters generated during the operation of the smart phone. In addition, the display unit 407 displays the selected image provided from the electrostatic compensation LED lighting auxiliary camera 330 under the control of the control unit 100 according to the present invention.

The input unit 408 includes a key for inputting numeric or text information and function keys for setting a function, and outputs a function corresponding to a key input by the user to the controller 100.

In particular, the input unit 408 outputs an input for executing the auxiliary camera application and an input for selecting a unique number or ID of the electrostatic compensation LED light auxiliary camera 330 to the controller 100 according to the present invention.

10 is a block diagram of the electrostatic compensation LED lighting auxiliary camera 330 according to an embodiment of the present invention, the electrostatic compensation LED lighting auxiliary camera 330 is a control unit 100, a photographing unit 402, an image It includes a processing unit B (404) and a short range wireless transceiver (406).

The controller 100 of FIG. 10 controls the overall operation of the power failure compensation LED lighting auxiliary camera 330 and, in addition to the normal function, when a connection is requested from the smart phone according to the present invention, the wireless communication is performed through the short range wireless communication. Connected to the smart phone and receives the unique number or ID (ID) of the blackout compensation LED lighting auxiliary camera 330 selected from the smart phone and the image of the camera according to the unique number or ID (ID) for the short-range wireless communication Control and process the functions provided by the smartphone through.

The photographing unit 402 includes a camera sensor for converting an image signal into an electrical signal, and a signal processing unit for converting an image signal photographed from the electrostatic compensation LED lighting auxiliary camera 330 into data, and converting the image signal into data. The image signal converted into is outputted to the image processor B (404).

In addition, the electrostatic compensation LED lighting auxiliary camera 330 is to take an image according to the unique number or ID (ID) of the electrostatic compensation LED lighting auxiliary camera 330 selected from the smart phone in accordance with the image processing unit B ( 404).

The image processor B 404 encodes an image signal input from the photographing unit 402 and outputs the image signal to the controller 100.

The short range wireless transceiver 406 processes the signal received through the short range wireless communication, transmits the signal to the control unit 100, encrypts a signal input from the control unit 100, and transmits the signal to the smart phone through the short range wireless communication. It plays a role of transmitting.

Here, the short range wireless communication may be a wireless LAN, Zigbee, Bluetooth, Ultra Wideband, or the like.

11 is a flowchart of a smartphone for outputting an image of an electrostatic compensation LED lighting auxiliary camera according to an exemplary embodiment of the present invention. First, prior to the description, the name of the electrostatic compensation LED lighting auxiliary camera 330 and the name of the auxiliary camera 1112 are regarded as the same.

Referring to FIG. 11, if the auxiliary camera application is executed by the user in step 501, the smartphone proceeds to step 503 to request a connection through the short range wireless communication with the auxiliary camera.

Here, the auxiliary camera application is an application (program) for the user to receive the image of the camera to facilitate the display on the smart phone.

In operation 505, the smart phone checks whether the connection with the auxiliary camera is completed.

If the connection with the auxiliary camera is not completed, the smartphone returns to step 503 and performs the following steps again.

On the other hand, when the connection with the secondary camera is completed, the smartphone proceeds to step 507 and receives a unique ID of the secondary camera by the user.

Here, it is assumed that a unique number (or ID) is assigned to each of the auxiliary cameras.

In operation 509, the smart phone transmits the input information, that is, the user's unique number and ID of the auxiliary camera to the auxiliary camera through the short range wireless communication.

In operation 511, when the image captured by the auxiliary camera is received, the smartphone proceeds to step 513 and outputs the received image to the display unit of the smartphone.

That is, when the secondary camera is selected, the smartphone receives an image from the electrostatic secondary camera through short range wireless communication and outputs the image to the display unit.

In operation 515, the smartphone checks whether the auxiliary camera application is terminated. When the auxiliary camera application is terminated, the smartphone releases short-range wireless communication connection with the auxiliary camera (step 517) and ends the process according to the present invention. .

First, when the secondary camera is requested to connect through the short-range wireless communication from the smartphone in step 601, the auxiliary camera proceeds to step 603 to perform the connection with the smartphone.

In step 605, the auxiliary camera checks whether the connection between the smart phone and the short range wireless communication is completed.

If the connection between the smart phone and the short range wireless communication is not completed, the auxiliary camera returns to step 603 to perform the following steps again.

On the other hand, when the connection via the short-range wireless communication with the smartphone is completed, the secondary camera proceeds to step 607 and receives the selected secondary camera unique number (or ID) from the smart phone in step 609 the selected secondary camera unique number The image according to the ID (or ID) is transmitted to the smart phone through the short range wireless communication.

In step 611, the auxiliary camera checks whether the auxiliary camera application is terminated. When the auxiliary camera terminates, the auxiliary camera proceeds to step 613 to release the connection with the smart phone and terminates the process according to the present invention.

On the other hand, if the auxiliary camera application (program) is not terminated, the auxiliary camera returns to step 609 to perform the following steps again.

The secondary camera then terminates the process according to the invention.

In the following description of the present invention, it is determined that additional description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, and thus the detailed description thereof will be omitted.

Next, as shown in the accompanying Figures 13 to 14 by using the wind and solar energy of the electrostatic compensation LED lighting device of the present invention as a bulb (Bulb) type body 10 without additional power supply natural energy We will explain the cost of power use and the effect that construction and maintenance are convenient.

As can be seen from Figures 13 to 14, the electrostatic compensation LED lighting device is formed of a housing in which the primary power storage unit 1007 components are seated therein, and connected to an external power source on a part thereof to receive AC power. A body 10 having a bulb socket 1001 and a portion of the body 10 in which the bulb socket 1001 is formed are divided up and down in the body 10 and rotated by a solar cell and wind power. By assembling and combining the blade 1004 to generate the appearance of the lighting fixture, the bulb socket 1001 and the opposite side portion of the body 10 side to face the dome-shaped auxiliary camera 1112 downward, Electrostatically compensated LED lighting device that is coupled to the outer surface of the dome-shaped auxiliary camera and acts as an electrical connection is made.

At this time, the body 10 and the bulb socket 1001 of the electrostatic compensation LED lighting device is coupled, the bracket 1116 of the support that is fixed to the bulb socket 1001 is the outer thread and bracket of the bulb socket 1001 The thread of the inner surface of the 1116 is further included, the accessory binding material that is easily rotated to engage.

Thus, the electrostatic compensation LED lighting device is preferably an indoor and outdoor lighting fixture, including outdoor installation.

Next, when the wind turbine 1005 has a plurality of blades 1004 in a horizontal cross section in plan view, the inner side is formed in a recessed shape and the outer side is formed in an opposite shape to face the inner side where lift is easily generated. desirable.

In order to achieve the above object, a description of a component capable of storing power collected from the wind power and the solar cell shown in FIG. 15 attached thereto, or receiving the external power supply and charging and supplying power to the LED module is provided. In other words,

Converter A 1114 and converter B 1115 for converting AC power into DC power; The primary power storage unit 1007 and the secondary power storage unit 1002 in an electrically connected state with the charging unit 1110 charging the primary power storage unit 1007 and the secondary power storage unit 1002 using an external power source. Control unit 100 for controlling the operation of the LED module with the power charged in the; The control unit 100 is composed of a voltage sensing module 1117 for sensing the voltage of the external power source, and a low voltage control unit 1118 that can increase the life of the secondary battery, is installed on one side of the body 10 The wind turbine 1005 includes a blade 1004 that can rotate with wind power on the rotating shaft 1006; A wind power generator 1005 for generating electricity generated through wind power and a solar cell 1003 for generating electricity with external sunlight; By using the USB terminal 1009 for inputting and outputting the internal power to the outer surface of the body 10, it is characterized in that it provides an environment that can be used without restrictions of the place.

Here, the charging unit 1110 charges the converter by depressurizing the power supply and boosts the voltage of the power storage unit during discharge to supply the LED module.

In addition, the low voltage control unit 1118 blocks the charging by the electric switch when the temperature setting value of the charging unit 1110 / first and second power storage unit (1007, 1002) is abnormal.

In addition, the converter A 1114 and the converter B 1115 are preferably connected in parallel, and the converter A 1114 and the converter B 1115 convert AC into DC when external power is supplied to the controller 100. Supplying power to the power supply, it is effective to maintain a long life by connecting in parallel for the purpose of extending the life of the blackout LED lighting device.

Referring to the primary power storage unit 1007, a hybrid capacitor, an electric double layer capacitor (EDLC) and a hybrid battery, a nickel-metal hydride battery, nickel iron phosphate battery, lithium iron phosphate battery, lithium polymer made of any one of the external power supply and wind power And power collected through solar light to the charging unit 1110 connected to the control unit C (100).

The secondary power storage unit 1002 is formed of any one of a hybrid battery, a nickel-metal hydride battery, and a lithium polymer battery, and is connected to the primary power storage unit 1007 in parallel to improve charging efficiency.

Here, lithium iron phosphate batteries are 30% to 40% cheaper than lithium-ion batteries using nickel, cobalt, manganese, etc., because the main raw material is abundant iron. In addition, lithium iron phosphate battery has a chemically extremely stable structure, so there is no fear of explosion even in overheating and overcharging situations.

On the other hand, the characteristic element of the control unit 100 controls the charging unit 1110 for charging the converter power and wind and solar power, and a built-in voltage sensing module 1117 to measure the energy of the solar cell to measure the solar cell When the voltage of 1003 is below the reference value, the LED module is turned on by the power storage unit power, and the internal low voltage controller 1118 is configured to turn off the output switch 1119 when the reference voltage falls below the reference voltage. It is preferable to comprise so that the life of a secondary battery may be extended.

In addition, the secondary power storage unit 1002 is configured to be easily detached from the body 10, and is formed to facilitate the maintenance by configuring the secondary power storage unit cover 1113.

Meanwhile, the charging unit 1110 may include external power input to the primary power storage unit 1007 and the secondary power storage unit 1002 to be charged with a constant voltage and a constant current device, an IC, a reverse current prevention diode, a resistor, and the like. The output voltage of the primary power storage unit 1007 and the secondary power storage unit 1002 is prevented from being output to the LED module through the constant voltage and the constant current device and the IC or the current limiting resistor, and the temperature rise of the power storage unit. It is preferable that the controller is configured to further include a control unit for controlling charging by an electric switch when the temperature is higher than the set value. In addition, when a plurality of batteries 30 are used, the unit price increases. Charge the converter by depressurizing the power and increasing the voltage of the capacitor during discharge.

In addition, an additional use of a fuse (FUSE), a thermal fuse, a temperature sensor, etc. for the purpose of overcurrent and overvoltage protection of the secondary power storage unit 1002 will be omitted in the gist of the present invention.

As a means for effectively controlling heat generation by the amount of power supplied to the LED module, it is preferable to provide heat to the charging module and the LED module separately to radiate heat to a fan (not shown).

Prior to the description of the power storage unit, characteristics of an electric double layer capacitor (EDLC) or a hybrid capacitor, which are generally used in general, will be omitted. In particular, a characteristic element of a hybrid battery is a parallel hybridization of a large output high power double layer capacitor. It is a high output hybrid battery having a long life characteristic as well as a large current pulse discharge, and the shape and type of the capacitor is not limited thereto, and various batteries for storing energy may be applied.

As described so far, the present invention has been expressed in the above description and drawings, but this is merely an example, and the spirit of the present invention is not limited to the above description and drawings, and various modifications may be made without departing from the technical idea of the present invention. Of course, change and change are possible.

Claims (36)

1. An electrostatic compensation function LED lighting device comprising an enclosure-shaped body in which a socket bolt is connected to an external power source to receive AC power at one portion, and a reflector plate assembled to an opposite side portion of the socket bolt-forming side in the body. ,

   A plurality of LED modules formed in the body, the plurality of LED bulbs being mounted toward the reflecting plate;

   A converter for converting AC power input from the outside into the DC power through the socket bolt;

   A storage battery formed in the body;

   The controller is configured to charge the battery using an external power source and control the operation of the LED module with the power charged in the battery while being electrically connected to the LED module.

   The control unit,

   A charging module for charging the storage battery with an external power source,

   An optical measuring sensor formed on one side of the body to sense a current amount of light;

   A voltage sensing module for sensing a voltage of an external power supply and generating a voltage value;

   A light quantity sensing module connected to the light measuring sensor via a cable and receiving a light quantity value from the light measuring sensor;

   Determination module for receiving the voltage value from the voltage detection module when the voltage value falls below a predetermined level receives the light quantity value from the light quantity detection module to determine whether the LED module is in operation according to the light quantity value to generate an operation signal and,

   And a control module for receiving the operation signal from the determination module and controlling the LED module with the power charged in the storage battery.
2. The method of claim 1,

   The storage battery,

   Electrostatic compensation LED lighting device, characterized in that provided with at least one of a hybrid capacitor, an electric double layer capacitor and a hybrid battery, a lithium polymer, a lithium iron phosphate battery produced differently in the configuration of the positive electrode and the negative electrode.
3. The method of claim 1,

   The determination module,

   The light intensity sensing module further comprises a light intensity determination unit for receiving a light quantity value to determine the illuminance of the LED light according to the light quantity value to generate an illuminance value.

   The control module,

   And an illuminance control unit for receiving an illuminance value from the illuminance determining unit and controlling an amount of power output from the storage battery to the LED module.
4. The method of claim 1,

   The control unit,

   An information receiving module comprising an input unit for receiving a power failure time information directly from the communication unit for interlocking with the Korea Electric Power Corporation server through the wireless communication unit to determine the power failure time information of the building,

   In addition, the charge module is interlocked with the charging module to determine the amount of power charged in the battery to generate charge information further includes a charge amount module,

   The control module,

   Receiving each information from the information receiving module and the charge amount determining module to determine the output amount per unit of time to maintain the LED bulb is turned on during the time information based on the charge amount information to determine the LED module in the battery Power failure compensation LED lighting device further comprises an output amount control unit for controlling the output amount of power output.
5. The method of claim 4, wherein

   The reflector is,

   By further including a light concentrating portion that is formed convex inwardly so that the light emitted from the LED bulb is concentrated and refracted to the point where the emergency escape is provided,

   An electrostatic compensation LED lighting device, characterized in that the point provided with the emergency evacuation is brighter than other points.
6. The method of claim 2,

   The blackout LED lighting device,

   Electrostatic compensation LED lighting device further comprises; a reverse current prevention diode for preventing a reverse current of the current input to the battery from the outside, and a flow control unit consisting of a protection resistor to prevent the rapid flow of current.
7. In the service method of the power failure compensation LED lighting auxiliary camera in a wireless LAN area,

   The power failure compensation LED lighting auxiliary camera 330 stores and manages each MAC address (Media Access Control Address, hereinafter, 'unique number') and image, software, content, and update history information according to the unique number, and manages the Internet network. A central server 310 transmitting and receiving update history information according to a unique number of a local server 320 installed in the wireless LAN area and a power failure compensation LED lighting auxiliary camera 330;

   Installed in the wireless LAN area, and receives and stores the unique number of the blackout compensation LED lighting auxiliary camera 330, the image, software, content and update history information according to the unique number from the central server 310 and By transmitting and receiving a wireless signal for updating image, software, and content through the wireless LAN device 200 installed in the wireless LAN region in which the blackout compensation LED lighting auxiliary camera 330 is installed, the blackout compensation LED lighting auxiliary camera 330. Determine whether it is an update target, and if it is an update target, transmit an image, software, and content to the power failure compensation LED light auxiliary camera 330, and update the image and update history information of the updated power failure compensation LED light auxiliary camera 330. Local server 320 for transmitting to the central server 310; And

   After receiving the access request signal for updating the image, software and content from the local server 320 through the wireless LAN device 200, and transmits the access permission signal or the access rejection signal accordingly, the power failure compensation LED lighting assistance When the camera 330 is an update target, the local server 320 receives an approval request signal and transmits the approval signal to the local server 320, and then the latest image, software, and content are received from the local server 320. Outage compensation LED lighting auxiliary camera for receiving and storing 330; Power failure compensation LED lighting auxiliary camera service method in a wireless LAN area comprising a.
8. The method of claim 7, wherein

   The local server 320,

   Receives the image, software, content and update history information according to the unique number of the power failure compensation LED light auxiliary camera 330 from the central server 310 through the Internet (Internet) network, and updated the power failure compensation LED light auxiliary camera ( A first communication unit 210 for transmitting the update history information of 330 to the central server 310;

   An image update information storage unit 220 storing and managing images, software, contents, and update history information according to a unique number of the power failure compensation LED lighting auxiliary camera 330 received through the first communication unit 210;

   By transmitting and receiving the connection request signal and the access permission signal for updating the image, software, and content through the power failure compensation LED light auxiliary camera 330 and the wireless LAN device 200, it is unique from the power failure compensation LED light auxiliary camera 330 A second communication unit 230 which receives a number and transmits the image, software and contents according to the unique number to the power failure compensation LED lighting auxiliary camera 330; And update history information of the unique number received from the power failure compensation LED light auxiliary camera 330 through the second communication unit 230 and the corresponding power failure compensation LED light auxiliary camera 330 stored in the image update information storage unit 220. By comparing, the image update target determination unit 240 for determining whether the corresponding blackout compensation LED lighting auxiliary camera 330 is the update target; Blackout compensation LED lighting auxiliary camera service method comprising a.
9. The method of claim 8,

   When the second communication unit 230 is not an update target or receives an approval rejection signal from the power failure compensation LED light auxiliary camera 330, the second communication unit 230 transmits a communication cutoff signal to the power failure compensation LED light auxiliary camera 330. Blackout compensation LED lighting auxiliary camera service method, characterized in that.
10. The method of claim 7, wherein

    The update history information, the image, software, content, weekly / monthly / year update service comprising a blackout compensation LED lighting auxiliary camera service method.
11. In the image, software and content download method in a wireless LAN area using a system consisting of a central server 310, a local server 320 and a power failure compensation LED lighting auxiliary camera 330, the image from the wireless LAN device 200, The power failure compensation LED light auxiliary camera 330 receiving the connection request signal for software and content update receives the unique number of the power failure compensation LED light auxiliary camera 330 according to the connection request signal from the WLAN device 200. Transmitting to the local server 320 through;

    By comparing the unique number of the electrostatic compensation LED lighting auxiliary camera 330 received by the local server 320 and the history information of the stored electrostatic compensation LED lighting auxiliary camera 330, the corresponding electrostatic compensation LED lighting auxiliary camera 330 Determining whether is an update target;

    The local server 320 transmitting an update approval request signal to the power failure compensation LED lighting auxiliary camera 330 through the wireless LAN device 200 when the unique number and the history information are determined to be updated;

    Transmitting the approval signal to the local server 320 through the wireless LAN device 200 when the blackout compensation LED lighting auxiliary camera 330 intends to approve an update;

    Transmitting, by the local server 320, the latest image, software, and content of the power failure compensation LED lighting auxiliary camera 330 through the wireless LAN device 200;

    Receiving and storing the latest image, software, and content by the power failure compensation LED lighting auxiliary camera 330;

    Storing, by the local server (320), the updated update history information, and transmitting the updated update history information to the central server (310) through an internet network;

    When the communication and power is cut off and restored, the power failure compensation LED light auxiliary camera service method in a wireless LAN area, including separately storing the image taken in the built-in memory of the power storage of the power failure compensation LED lighting auxiliary camera (330).
12. The method of claim 11,

    In the wireless LAN region in which the power failure compensation LED light auxiliary camera 330 is installed, a connection request signal for updating an image, software, and content is transmitted to the power failure compensation LED light auxiliary camera 330 through the wireless LAN device 200. Blackout compensation LED lighting auxiliary camera service method in a wireless LAN region, characterized in that it further comprises.
13. The method of claim 11,

    The central server 310 further comprises the image update history information transmitted from the local server 320, the blackout compensation LED lighting auxiliary camera service method in a wireless LAN area.
14. The method of claim 11,

    If the image is not an update target, the local server 320, the power failure compensation LED lighting auxiliary camera in the wireless LAN region, characterized in that further comprising transmitting a communication cutoff signal to the power failure compensation LED lighting auxiliary camera 330. Service method.
15. The method of claim 11,

    If the power failure compensation LED lighting auxiliary camera 330 does not want to update the image, the wireless LAN device 200 transmits an approval rejection signal to the local server 320 and receives the approval rejection signal from the local. Server 320, the blackout compensation LED lighting auxiliary camera service method in the wireless LAN region, characterized in that further comprising transmitting a communication blocking signal to the blackout compensation LED lighting auxiliary camera (330).
16. The method of claim 11,

    Power failure compensation LED lighting auxiliary camera service method in a wireless LAN area, characterized in that for transmitting the internal memory image signal to the local server 320 during communication and power recovery.
17. In the method of servicing the image to the smartphone from the blackout compensation LED lighting auxiliary camera 330,

    Connecting when the connection request is made from the smart phone through short-range wireless communication;

    Transmitting an image signal of the electrostatic compensation LED lighting auxiliary camera 330 selected from the smartphone to the smartphone;

    Blackout compensation LED lighting auxiliary camera (330) for each of the unique number or ID (ID) is characterized in that the blackout compensation LED lighting auxiliary camera service method.
18. In the method for servicing the image of the power failure compensation LED lighting auxiliary camera 330 in a smartphone,

    Requesting connection through the short-range wireless communication with the power failure compensation LED lighting auxiliary camera 330 when the image service application (program) is executed; Transmitting a selected image of the power failure compensation LED lighting auxiliary camera 330 through the short range wireless communication; Outputting the selected image to the display unit 407 when the selected image signal is received from the electrostatic compensation LED lighting auxiliary camera 330;

    Blackout compensation LED lighting auxiliary camera (330) for each of the blackout compensation LED lighting auxiliary camera service method, characterized in that assigned to a unique number or ID (ID).
19. The method of claim 17 or 18,

    The short-range wireless communication is a wireless LAN, Zigbee (Zigbee), Bluetooth (Bluetooth), ultra wideband (Ultra Wideband), characterized in that the LED lighting auxiliary camera service method.
20. The method of claim 19,

    Blackout compensation LED lighting auxiliary camera service method characterized in that the wireless LAN, Zigbee, it is possible to turn on / off the camera and the lamp using broadband.
21. A body 10 having a bulb socket 1001 configured to receive external power, and the auxiliary camera 1112 assembled to an opposite side portion of the side on which the bulb socket 1001 is formed;

    An LED module coupled to an outer surface of the auxiliary camera 1112 and electrically connected thereto;

    A wind generator for generating electricity via wind power on one side of the body 10;

    The built-in wind generator 1005 includes two or more blades 1004 coupled to the outer surface of the body 10 so as to rotate on the rotating shaft 1006 with wind power;

    A bracket (1116) supporting the body (10) fixedly coupled to the bulb socket (1001);

    A solar cell 1003 for generating electricity with sunlight on an outer surface of the body 10;

    A USB terminal 1009 for inputting and outputting internal power to an outer surface of the body 10;

    Converter A 1114 and converter B 1115 for converting external power into DC power through the bulb socket 1001;

    A primary power storage unit 1007 and a secondary power storage unit 1002 embedded in the body 10;

    The primary power storage unit 1007 and the secondary power storage unit 1002 in an electrically connected state with the charging unit 1110 charging the primary power storage unit 1007 and the secondary power storage unit 1002 using an external power source. Control unit 100 for controlling the operation of the LED module with the power charged in the;

    The control unit 100 includes a voltage sensing module 1117 for sensing external power and a low voltage control unit 1118 for controlling voltage and current of a secondary battery; Blackout compensation LED lighting device, characterized in that consisting of.
22. The method of claim 21,

    The charging unit of the electrostatic compensation LED lighting device,

    An electrostatic compensation LED lighting device, characterized in that it comprises a charge to a constant voltage and a constant current device or IC for controlling the external power input to the primary power storage unit (1007), the secondary power storage unit (1002).
23. The method of claim 21,

    The primary power storage unit 1007,

    Electrostatic compensation LED, characterized in that the positive electrode and the negative electrode is made of a hybrid capacitor, an electric double layer capacitor and a hybrid battery, a nickel hydride battery, a nickel iron phosphate battery, a lithium iron phosphate battery, and a lithium polymer prepared differently Lighting device.
24. The method of claim 21,

    The secondary power storage unit 1002,

    It is configured to be detachably attached to the body (10) and configured to the secondary power storage portion cover (1113);

    Electrostatic compensation LED lighting device characterized in that it is provided with any one or more of a nickel hydrogen battery, a lithium polymer battery, a hybrid battery, a lithium iron phosphate battery, a lithium polymer easy to charge and discharge.
25. The method of claim 21,

    Electrostatic compensation LED lighting device, characterized in that configured to be easily coupled to the outer thread of the bulb socket (1001) and the thread of the inner surface of the bracket (1116) as a support fixed to the bulb socket (1001).
26. The method of claim 21,

    The secondary power storage unit 1002 is a power failure compensation LED lighting device, characterized in that to cut the output voltage and current by turning off the output switch (1119) when it falls below the reference voltage.
27. The method of claim 21,

    The blade 1004 has a horizontal cross-sectional view in plan view, the inner side is formed in a recessed shape and the outer side is an electrostatic compensation LED lighting device provided in the opposite shape facing the inner side is easy to generate lift.
28. The method of claim 21,

    The controller 100 measures the output voltage of the solar cell 1003 and outputs the voltages of the primary power storage unit 1007 and the secondary power storage unit 1002 when the voltage of the solar cell is lower than the reference to the LED module. Outage compensation LED lighting device characterized in that it further comprises an output unit.
29. The method of claim 21,

    Wind generator (1005), solar cell (1003), auxiliary camera (1112) electrostatic compensation LED lighting device, characterized in that configured by selecting one or more of the body (10).
30. The method of claim 21,

    The converter A (1114), converter B (1115) is an electrostatic compensation LED lighting device, characterized in that can be used in parallel connected.
31. The method of claim 21,

    Electrostatic compensation LED lighting device, characterized in that the output voltage of the primary power storage unit (1007) and the secondary power storage unit (1002) is output through the diode (1121).
32. The method of claim 22,

    One or any one or more of the constant voltage and constant current elements and the IC for controlling the external power input from the charging unit 1110 to the secondary power storage unit 1002 or the reverse current prevention diode and the current limiting resistor are selected to be charged. Blackout compensation LED lighting device, characterized in that configured.
33. The method of claim 31, wherein

    Receives the output voltages of the primary power storage unit 1007 and the secondary power storage unit 1002 and is output to the LED module through the constant voltage and constant current device and IC, or a current limiting resistor, the power storage via solar and wind power The electrostatic compensation LED lighting device, characterized in that the power storage.
34. The method of claim 1,

    Electrostatic compensation LED lighting device characterized in that the charge module and LED module provided with a separate heat sink to radiate heat to the fan.
35. The method of claim 21,

    The charging unit charges by reducing the converter power to charge and discharge the voltage of the power storage unit when discharged to the LED module, characterized in that for supplying to the LED module.
36. The method of claim 35, wherein

    When the temperature setting value of the charging unit / power storage unit exceeds the low voltage control unit, the power failure compensation LED lighting device, characterized in that the charge control by the electric switch.

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