KR20100064861A - Led indoor illuminating device using communication line - Google Patents

Abstract

LED indoor lighting device using a communication line according to the present invention, a plurality of indoor lighting devices installed in the room, the illumination sensor is installed in the predetermined position of the room separately from the indoor lighting device, the plurality of indoor lighting devices and the illuminance A control device connected to a sensor to control an indoor lighting device, wherein the indoor lighting device includes a temperature sensor for detecting a light emitting temperature of an LED used in the indoor lighting device and a temperature of a printed circuit board on which the LED is installed; A communication device is provided for communication with the device, and the control device includes a memory unit in which a program for storing an optimum illuminance value based on a value measured by a temperature sensor and an illuminance sensor and calculating a optimum illuminance value is included; Processor to control the indoor lighting device based on the value stored in the memory unit, and input the illumination value desired by the user And an input unit for communicating with the indoor lighting unit for controlling the plurality of indoor lighting units.

Description

LED indoor lighting device using communication line {LED INDOOR ILLUMINATING DEVICE USING COMMUNICATION LINE}

The present invention relates to an LED indoor lighting device using a communication line, and in particular, a plurality of luminaires can control the illumination of the indoor lighting device according to the ambient light through the temperature sensor and the light sensor, and also a plurality of indoor lights using a communication line The present invention relates to an LED indoor lighting device using a communication line that can not only control the device at the same time but also control indoor lighting devices installed in different places.

Currently, lighting devices used as indoor lighting are mostly fluorescent or incandescent. Although incandescent lamps were used as indoor lamps in the early stages, incandescent lamps were not very efficient, so they were difficult to obtain fairly bright light even though they consumed a lot of electricity. In addition, when incandescent lamps are used continuously, a lot of heat is generated. On the other hand, the filament of the incandescent lamp is made of very thin tungsten, and the filament made of tungsten is heated to a temperature of nearly 3000 degrees during incandescent lamp operation to emit light. Therefore, the filament heated at high heat is easily broken by repeated use, so the life of the incandescent lamp is relatively short. Therefore, a fluorescent lamp has been developed to solve such a problem, such a fluorescent lamp has the advantage that the efficiency is superior to the power consumption. However, the fluorescent lamp is a method in which the mercury vapor is excited by electrons generated from the filament to emit light using the phosphor, and the mercury vapor and the phosphor used in the fluorescent lamp are harmful to the environment. In particular, mercury is a substance that can seriously affect the human body.

Therefore, countries around the world, especially developed countries, are going to prohibit the use of lighting lamps, such as fluorescent lights, for environmental reasons within the next few years. Therefore, a new replacement lamp is needed. LEDs using semiconductor materials are attracting attention as such replacement lamps. Initially, LEDs were not valued as lightings because they did not show satisfactory light efficiency, but they are currently being used a lot due to the increase of light efficiency with the development of semiconductor technology and the decrease of unit price due to mass production.

Most of the LEDs currently used are used in the same manner as general conventional lighting lamps without a separate control circuit. That is, only general methods such as a method of illuminating using a light guide plate and an on / off operation using a simple on / off power switch are used.

However, when the light guide plate is used, the illuminance is weakened. Also, the LED uses a semiconductor material. When the temperature increases due to the characteristics of the semiconductor material, electrons and holes move in the semiconductor material, resulting in low light efficiency. Will be. In addition, if a large load is added to the LED, deterioration may occur in the semiconductor material, which is the LED material, and there is a fear that the average life of the LED may not be filled up to 50,000 hours.

In order to solve the above problems, in the same application and the same applicant, the patent application "indoor lighting device using the LED" and "indoor lighting device using the LED which can selectively adjust the illumination" in the same applicant, Adjust the illuminance of the indoor lighting device based on the illuminance value detected by the illuminance sensor detecting the illuminance and the temperature sensor which measures the temperature of the LED mounted on the printed circuit board and the printed circuit board ("LED Indoor lighting device using "" and "indoor lighting device using LED with selective illuminance control"), or by controlling the LEDs by group to adjust the illumination ("indoor lighting device using LED with selective illumination control") By preventing overheating of the LED and the printed circuit board, it is possible to guarantee the maximum useful life of the LED. To achieve the reduction.

However, the present invention relates to a method of controlling one indoor lighting device in one place, and it is difficult to use efficiently when a plurality of indoor lighting devices exist in a large room such as a large office. In particular, when using a plurality of indoor lighting devices in an office with a large number of windows, indoor lighting devices should be controlled according to the location. However, the inventions by the present applicants did not respond appropriately.

Accordingly, an object of the present invention is to provide an LED indoor lighting device using a communication line, and in particular, a plurality of LED indoor lighting device is connected to one control device through a communication line, the illumination sensor in a number of indoor places where the indoor lighting device is installed In addition, by installing a temperature sensor that can measure the light emitting temperature of the LED and the temperature of the printed circuit board in the body of the indoor lighting device, a number of indoor lighting devices are installed on the basis of the values measured by the illuminance sensor and the temperature sensor. It is to provide an LED indoor lighting device using a communication line that can be controlled through one control device.

According to an object of the present invention, the LED indoor lighting device using a communication line, a plurality of indoor lighting devices installed in the room, the illumination sensor is installed in the predetermined position of the room separately from the indoor lighting device, and the plurality of indoor It is composed of a control device that controls the indoor lighting device connected to the lighting device and the illumination sensor, the indoor lighting device is a temperature sensor for detecting the temperature of the light emitting temperature of the LED used in the indoor lighting device and the temperature of the printed circuit board on which the LED is installed And, a communication device for communication with the control device is installed, the control device has a built-in program for storing the optimum illuminance value based on the values measured by the temperature sensor and the illuminance sensor and also calculate the optimal illuminance value A memory unit, a processor for controlling the indoor lighting device based on the value stored in the memory unit, and the illumination intensity desired by the user For the input unit, and a control of the plurality of indoor lighting device for inputting the is characterized in that it comprises a communication unit for communicating with the interior lighting device.

According to another object of the present invention, after the LEDs installed in the individual indoor lighting device of the indoor lighting device is divided into a plurality of groups, it is characterized by controlling the LEDs by groups as a control device.

According to the present invention, by controlling the illuminance of the indoor lighting device based on the temperature sensor and the illuminance sensor, by preventing the overheating of the LED used in the indoor lighting device and the printed circuit board connected thereto, and ultimately extending the available life of the LED This ensures optimum illumination while reducing power consumption.

In addition, according to the present invention, by controlling a plurality of indoor lighting devices using a communication line generally installed in a building or indoors for the control of other devices, it is possible to optimally maintain a plurality of indoor lighting devices in an illumination environment, This will extend the useful life of the LED and reduce the cost.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a view schematically showing a state in which an indoor LED lighting device using a communication line according to the present invention installed indoors, Figure 2 is a block diagram showing the configuration of the LED indoor lighting device using a communication line according to the present invention, 3 is an enlarged view of a portion A of FIG. 2, FIG. 4 is a view showing the configuration of the LED in the LED indoor lighting device using a communication line according to the present invention, Figure 5 is a room lighting according to another embodiment of the present invention A block diagram schematically showing the configuration of the device.

Referring to Figure 1, the LED indoor lighting device 1000 using a communication line according to the present invention is installed a plurality of indoor lighting device 100 on the ceiling of the room (1), such as a large office, these indoor lighting device It is configured to connect to the control device 200 through the communication line (300). In addition, a plurality of illumination sensors 150, such as indoor walls and ceilings, are installed and connected to the control device.

After the installation is completed, when the indoor lighting device 1000 is turned on, the control device individually controls the indoor lighting device 1000 based on the illumination detected by the illumination sensor 150. That is, when a lot of light enters through the indoor window (2), the wall illumination sensor detects the illumination value higher than the target value, but the light sensor installed on the ceiling is lower or higher than the target value, A low illuminance value will be detected. Therefore, the control sensor controls the amount of current supplied to the LED installed in the indoor lighting device located near the window to lower the illuminance of the indoor lighting device near the window so as to approach the target value, and also to adjust the amount of current supplied to the LED installed in the indoor indoor lighting device. By controlling the illuminance close to the target value. This control method will be described in more detail with reference to FIGS. 2 and 3.

Figure 2 is a block diagram showing the configuration of the LED indoor lighting device using a communication line according to the present invention, Figure 3 is an enlarged view of portion A of FIG. As shown in FIG. 2, the LED indoor lighting device 1000 using the communication line according to the present invention includes a plurality of indoor lighting devices 100, a control device 200 for controlling a plurality of indoor lighting devices 100, and Communication line 300 for connecting the indoor lighting device and the control device, and a plurality of illumination sensors 150 are installed separately from the plurality of indoor lighting device, the indoor lighting device is SMPS (Switched mode power supply) ( From 400).

The indoor lighting device 100 is installed a plurality (100'1 ~ 100'16), a plurality of illumination sensors are also installed. The illuminance sensor is preferably installed on the side and four side surfaces of the plurality of indoor lighting.

The control device 200 is based on the optimum illuminance value, the correlation between the luminous temperature and the illuminance value of the LED, the data for the optimal current value to be supplied to the LED based on the value measured by the temperature sensor and the illuminance sensor, and the temperature Based on the values measured by the sensor and the illuminance sensor, a memory unit 210 having a program for obtaining an optimal current value to be supplied to the LED, a calculation unit 220 which performs a calculation, and a current supplied to the LED It is composed of an input unit 230 that can be set, and also the communication unit 240 for communication with the indoor lighting device (100) is further installed.

As shown in FIG. 3, the indoor lighting device 100 receives power from a plurality of LEDs 110, a communication device 120 for communicating with the control device 200, and an SMPS to be supplied to the LEDs. The current control device 130 for controlling the current, the temperature sensor 140 for detecting the light emission temperature of the LED and the temperature generated from the printed circuit board (not shown) in which the LED is installed, and the communication line 300 Through the control of the control device 200 through the control unit 150 for controlling the entire component of the indoor lighting device.

When driving the indoor lighting device configured as shown in Figures 2 and 3, the LED 110 of the indoor lighting device is turned on to illuminate the room. In this case, the illuminance may be set to a value stored in the memory unit 210 of the control device 200 or a value input by the user. However, when a plurality of windows 2 are formed in the room as shown in FIG. 1, the illumination in the window and the illumination inside the room away from the window are different. In particular, when the sun rises, there is a large difference in illuminance between the windows and the inside of the room. Then, the illuminance sensors measure the illuminance of the room. At this time, when the illuminance value measured by the illuminance sensor located on the window side is higher than the set value or the value input by the user, the control device 200 controls the processing unit 150 of the indoor lighting device 100 through a communication line, The current controller 130 controls the current control unit 130 to reduce the amount of current supplied from the SMPA 400 to the LED 110 of the indoor lighting device such that the illumination value of the LED is equal to the illumination value detected by the illumination sensor. If the amount of light is so large that a desired illuminance value can be obtained without an LED, the LED is turned off to turn off the indoor lighting device. For example, in the case of the embodiment shown in FIG. 1, the indoor lighting devices 100'1, 100'4, 100'5, 100'8, 100'9, 100'12, 100'13 and 100'16 are turned on. Let's go.

On the other hand, if the illuminance value measured by the illuminance sensor inside the room is also higher than the set value or the value desired by the user, as described above, the control of the current control device controls the current control device to lower the illuminance of the indoor lighting device inside the room. On the contrary, if it is lower than the set value, the illuminance of the indoor lighting device is increased to the set value or a value desired by the user.

That is, based on the illuminance value obtained through the illuminance sensor at various places in the room, the most optimal illuminance is obtained by individually controlling the plurality of indoor lighting devices 100.

On the other hand, when the indoor lighting device using the LED for a long time, heat is generated in the printed circuit board is connected to the LED and the LED. Such heat may adversely affect the LED, which may degrade the performance of the LED or shorten the useful life of the LED. Therefore, it is desirable to suppress the heat generation of the LED. In order to suppress the heat generation of the LED, in the present invention, the temperature sensor 140 is installed inside the indoor lighting device 100 to continuously monitor the heat generated from the LED and the printed circuit board. Therefore, the control device 200 controls if the light emitting temperature of the LED detected by the temperature sensor is higher than the illuminance value detected by the illuminance sensor based on the value detected by the temperature sensor and the value detected by the illuminance sensor. The device controls the current control device to limit the current supplied to the LED to suppress the heat generation of the LED. Therefore, the LED is prevented from being degraded by heat, thereby ultimately ensuring the efficiency of the LED itself and also extending the useful life of the LED.

On the other hand, it has been described in such a way that the overall control of the LED of the indoor lighting device 100, that is, dimming. However, it is also possible to select and adjust the ellipses of the indoor lighting device individually or in groups.

4 is a view showing the configuration of the LED in the LED indoor lighting device using a communication line according to the present invention, the LED 110 is electrically connected to a plurality of groups, that is 110'1, 110'2, 110'3, 110 It can be connected to '4 and 110'5. That is, the LEDs in each group are connected to a common circuit and are simultaneously turned on and off. Accordingly, by selectively using the LED in the indoor lighting device, the use time of other LEDs not used is reduced, thereby extending the useful life of the LED.

Referring to Figures 1 and 4 when described in more detail as follows.

When the indoor lighting device 100 is turned on and the ambient light sensor 150 detects the ambient light, the control device 200 controls the current control device 130'1 to 130'5 based on the value detected by the light sensor. By controlling the current supplied to the LED through each of the indoor lighting device. In this case, the indoor lighting device does not control the entire LED of the indoor lighting device as described with reference to FIGS. 2 and 3, but controls the group of each LED. Therefore, when controlling the indoor lighting device because the ambient light is higher than the set value, the illumination of the indoor lighting device is controlled by turning off or dimming each LED group. Therefore, since the indoor lighting device does not use all of the LEDs, in the long term, this results in extending the useful life of the LEDs.

In the above description, a method of controlling illuminance of a plurality of indoor lighting devices installed in a large room has been described. However, in the present invention, a plurality of indoor lighting devices installed in an indoor room of a large building can be remotely controlled. Can be.

5 is a block diagram schematically showing the configuration of an indoor lighting device according to another embodiment of the present invention. As shown in FIG. 5, each floor of a large building includes an indoor lighting device 1000 according to the present invention for each floor. Installed in the office, and connected to one main control device 500 through the communication unit 240 of the control device 200 installed in these indoor lighting devices to remotely control the indoor lighting devices installed in each room of a large building. To control. Therefore, in general, the manager who manages a large building controls the indoor lighting device of the whole building using the main control device 500, but separately controls the indoor lighting device by using the control device 200 in each room. Can be. On the other hand, even if an error occurs in the control device 200 installed in each room is impossible to control the indoor lighting device 100 in the room, the main control device is connected to the control device via a communication line and the control device is connected to the indoor lighting device As it is connected, it is possible to remotely control the indoor lighting device from the main control device. Thus, dual control can be achieved and management becomes more convenient.

The main control device 500 may have the same configuration as the control device 200, and the optimum illuminance data for each floor and each room may be stored in the memory unit of the main control device. The controller can efficiently control the indoor lighting device 100 of each floor and each room.

The communication between the main control device, the control device and the lighting device is an intranet, i.e., an internal transmission network, and the internal transmission network is composed of RJ-11 or RJ-45, and the protocol used may be RS485 or RS232.

1 is a view schematically showing a state in which an indoor LED lighting device using a communication line in accordance with the present invention installed indoors,

Figure 2 is a block diagram showing the configuration of the LED indoor lighting device using a communication line according to the present invention,

3 is an enlarged view of portion A of FIG. 2,

4 is a view showing the configuration of the LED in the LED indoor lighting device using a communication line according to the present invention,

Figure 5 is a block diagram schematically showing the configuration of the indoor lighting device according to another embodiment of the present invention.

Claims (9)

An LED indoor lighting device using a communication line installed indoors such as a large office, the indoor lighting device, A number of indoor lighting devices installed on the ceiling of the room, a control device for controlling the indoor lighting device, a communication line connecting the indoor lighting device and the control device, and a ceiling or wall of the room separately from the indoor lighting device It consists of an illuminance sensor and SMPS for supplying power to the indoor lighting device, The control device is composed of a memory unit, a calculation unit for performing the operation, an input unit for setting the current supplied to the indoor lighting device, and a communication unit for communicating with the indoor lighting device, Each of the plurality of indoor lighting devices includes a plurality of LEDs, a communication device for communication with a control device, a current control device for controlling a current supplied to the LED by receiving power from the SMPS, and an LED emitting temperature and an LED LED indoor lighting using a communication line, comprising a temperature sensor for detecting a temperature generated from the printed circuit board is installed, and a processing unit for controlling the components of the entire indoor lighting device under the control of the control device through a communication line. Device. The method of claim 1, wherein the data stored in the memory includes data about an optimal illuminance value, data about a correlation value between the light emission temperature and the illuminance value of the LED, a value measured by a temperature sensor or an illuminance sensor, or both. A program for calculating the optimal current value supplied to the LED based on the data measured on the optimal current value to be supplied to the LED, the value measured through the temperature sensor or the illuminance sensor, or both. Indoor lighting device. The current control device of claim 2, wherein the control device controls the current control device based on a value detected by an illuminance sensor, or based on a value detected by a temperature sensor, or based on two values detected by an illuminance sensor and a temperature sensor. LED indoor lighting device, characterized in that for controlling the illumination of the indoor lighting device by controlling the current supplied to the LED. The indoor lighting device of claim 2, wherein the plurality of LEDs are electrically divided into a plurality of groups, and the LEDs of each group are electrically connected to each other. The method of claim 4, wherein the control device is based on the value detected by the illuminance sensor, or based on the value detected by the temperature sensor, or based on two values detected by the illuminance sensor and the temperature sensor. LED indoor lighting device, characterized in that by controlling the current control device to control the current supplied to the LED of each group by controlling the LED for each group to control the illumination of the indoor lighting device. A plurality of LED indoor lighting device using a communication line installed in a plurality of indoors, such as offices on each floor of the building, each of the indoor lighting device, It is installed on the ceiling or wall of the room separately from the indoor lighting device, a plurality of indoor lighting devices installed on the ceiling of each room, a control device that controls the indoor lighting device, a communication line connecting the indoor lighting device and the control device, and a separate indoor lighting device. It consists of an illuminance sensor and an SMPS for supplying power to the indoor lighting device, and each indoor lighting device is connected to the main control device through communication. The control device is composed of a memory unit, a calculation unit for performing the operation, an input unit for setting the current supplied to the indoor lighting device, and a communication unit for communicating with the indoor lighting device and the main control device, The main control device is composed of a memory unit, a calculation unit, an input unit and a communication unit of the same configuration as the control unit, Each of the plurality of indoor lighting devices includes a plurality of LEDs, a communication device for communication with a control device, a current control device for controlling a current supplied to the LED by receiving power from the SMPS, and an LED emitting temperature and an LED LED indoor lighting using a communication line, comprising a temperature sensor for detecting a temperature generated from the printed circuit board is installed, and a processing unit for controlling the components of the entire indoor lighting device under the control of the control device through a communication line. Device. The method of claim 6, wherein the memory unit of the main control device through the data on the optimum illuminance value for each room of each floor, the data of the correlation between the light emission temperature and the illuminance value of the LED, temperature sensor or illuminance sensor Program for obtaining the optimal current value supplied to the LED based on the data measured by the temperature sensor or the illuminance sensor, or the value measured through both the data on the optimal current value to supply the LED based on the measured value or both LED indoor lighting device, characterized in that the. The current control device of claim 7, wherein the main controller and the controller are configured based on a value detected by an illuminance sensor, or based on a value detected by a temperature sensor, or based on two values detected by an illuminance sensor and a temperature sensor. LED indoor lighting device, characterized in that to control the illumination of the indoor lighting device by controlling the current supplied to the LED control device. The communication system according to any one of claims 1 to 8, wherein the communication is composed of an internal transmission network such as an intranet, and the internal transmission network is comprised of RJ-11 or RJ-45, and the use protocol is RS485 or RS232. LED indoor lighting device.

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