KR20120087396A - led illumination lamp - Google Patents

Abstract

PURPOSE: An LED lighting device is provided to control to turn lights on and off by sensing a human body using a human detection sensor on the ceiling near a body of a main case formed on the indoor ceiling. CONSTITUTION: A main case(110) is fixed on a ceiling or a wall of the building. A reflector(120) is mounted on the middle part of the main case and reflects the light. A first LED lamp(130) and a second LED lamp(140) are combined with the main case and emits light. A detection sensor(150) is mounted on the ceiling and the wall and senses whether or not a human body exists. A controller controls the first LED lamp and the second LED lamp according to the result of the human detection from the detection sensor.

Description

LED illumination device

The present invention relates to a lighting device, and more particularly to an LED lighting device to reduce the power consumption.

In general, various lighting devices are used to be installed in indoor or outdoor advertisements or signs to identify images at day or night. These lighting devices use filament bulbs, fluorescent lights, neon signs or LEDs (Light Emitting Diodes).

In particular, the lighting device using the LED has the advantage that the life of the LED is semi-permanent, inexpensive, and low power consumption, the use is increasing.

Here, LED refers to a light emitting diode device, and has advantages such as fast processing speed and low power consumption of LED semiconductors, and has been spotlighted as a next-generation strategic product due to its environmentally friendly and high energy saving effect.

The LED device is composed of p-type and n-type semiconductors, and when voltage is applied, electrons and holes are combined to emit energy corresponding to the bandgap of the semiconductor in the form of light. It is a kind of optoelectronic device.

Recently, various colors of LED have been developed to enable natural color display, and are being applied to various places such as outdoor large billboards, traffic lights, automobile dashboards, home appliances, neon replacement signs, medical equipment, warnings and induction lamps.

In addition, the LED lighting device has been in the spotlight as a lighting device due to its low power consumption of about 10% to 15%, a semi-permanent life of more than 100,000 hours, and environmentally friendly characteristics compared to conventional incandescent or fluorescent lamps.

However, in the LED lighting apparatus according to the prior art, since all the arranged LEDs are lit at the same time, not only the shape of the LED is lit but also brightened momentarily when the LED is initially turned on, causing problems such as glare. It's happening.

The present invention is to solve the conventional problems as described above, when there is no human through the detection of the human body of the fluorescent lamps of the two lamps on one side and the other side of the fluorescent lamp 50% dimming to reduce power consumption LED lighting The purpose is to provide a device.

LED lighting apparatus according to the present invention for achieving the above object is a main body case having a socket at both ends of the inner side, a reflection shade mounted on the inner middle portion of the main body case to reflect light, and the reflection shade between First and second LED fluorescent lamps coupled to the main body case to emit light, a sensor attached to a ceiling or a wall adjacent to the main body case, and detecting a presence or absence of a human body; It is characterized in that it comprises a control unit for extinguishing any one of the LED fluorescent lamp of the first, second LED fluorescent lamp and dimming the other LED fluorescent lamp by 50%.

LED lighting device according to the present invention is equipped with two LED fluorescent lamps and the human body sensor installed on the ceiling and the main body case installed on the ceiling of the room, if there is no human through the detection of the human body of one of the two LED fluorescent lamps LED fluorescent lamp is turned on and other LED fluorescent lamp is dimmed by 50% to reduce power consumption.

1 is a perspective view schematically showing an LED lighting apparatus according to the present invention
Figure 2 is a block diagram schematically showing an LED lighting apparatus according to the present invention
3 is a configuration diagram of the sensor and the controller of FIG.
4 is a perspective view showing each LED fluorescent tube of FIG.
FIG. 5 is a cross-sectional view of an LED fluorescent lamp taken along line II-II ′ of FIG. 4.
6 is a perspective view showing another embodiment of the LED fluorescent lamp of FIG.
7 is a perspective view showing another embodiment of the LED fluorescent lamp of FIG.

Hereinafter, with reference to the accompanying drawings will be described in more detail the LED lighting apparatus according to the present invention.

1 is a perspective view schematically showing an LED lighting apparatus according to the present invention, Figure 2 is a block diagram schematically showing a LED lighting apparatus according to the present invention.

1 and 2, the LED lighting apparatus according to the present invention is mounted to the main body case 110 and the inner surface of the main body case 110, which is fixed to the ceiling or wall of the building and reflects light The first and second LED fluorescent lamps 130 and 140 coupled to the main body case 110 with the reflection shade 120 interposed between the main body case 110 and the ceiling or wall surface adjacent to the main body case 110. Attached to the detection sensor 150 for detecting the presence or absence of the human body, and receives the information from the sensor 150 to turn off any one of the first, the second LED fluorescent lamp (130, 140) LED fluorescent lamp in the absence of the human body and the other It comprises a control unit 160 for dimming the LED fluorescent lamp of 50%.

Here, a converter (not shown) for supplying power is mounted inside the main body case 110, and the controller 160 is integrally formed with the detection sensor 150 to control the converter.

The controller 160 turns off the first LED fluorescent lamp 130 when there is no human body according to the detection result of the sensor 150, and controls the brightness by dimming the second LED fluorescent lamp 140 by 50%. The brightness may be controlled by turning off the second LED fluorescent lamp 140 and dimming the first LED fluorescent lamp 130 by 50%.

That is, the controller 160 alternately turns off the first LED fluorescent lamp 130 and the second LED fluorescent lamp 140 on one side and dims the other 50% according to the detection of the human body by the detection sensor 150. It is possible to reduce the power consumption.

The main body case 110 has sockets 112 mounted on both ends thereof. Then, both terminals of the first and second LED fluorescent lights 130 and 140 are coupled to the socket 112, respectively, so that the first and second LED fluorescent lights 130 and 140 emit light.

The reflection shade 120 is made by bending a thin plate. In addition, the reflection shade 120 is formed to be smaller than the width of the main body case 110 is coupled to the inner middle of the main body case 110.

Therefore, the reflection shade 120 divides the inside of the main body case 110 into two parts, and the first and second LED fluorescent lamps 130 and 140 are positioned at respective partitioned positions.

Of course, in some cases, the reflection shade 120 may be further mounted so as to be divided into two or more parts.

The reflection shade 120 of this type may increase the illuminance of the first and second LED fluorescent lamps 130 and 140 by coating a reflective material having excellent reflectance to improve reflectance.

In this case, the reflective material may exhibit an excellent reflection effect even when coated only on at least a portion of the body case 110. In addition, it is possible to exhibit excellent reflection effect without using other materials of different materials.

As described above, the width of the reflector 120 may be narrowed to reduce the manufacturing cost of the reflector 120.

The detection sensor 150 detects the presence or absence of a human body and transmits the result to the controller 160, and the controller 160 transmits information from the detection sensor 150 to the first and second LED fluorescent lamps. One of the fluorescent lights 130 and 140 is turned off and the other is controlled to be 50% dimmed.

Here, the sensing sensor 150 is described to be installed in a position adjacent to the main body case 110, but is not limited to this may be attached to the surface of the main body case 110.

On the other hand, the control unit 160 is a converter, the converter can turn on each LED even if the power is input from either side of the socket of the fluorescent tube of the mercury discharge tube is already installed, the direction of coupling when the LED lighting device is installed in the frame There is no need to consider, it enhances the convenience of consumers, cuts off overvoltage and overcurrent of input power, removes surge voltage and noise from outside, and supplies constant constant current of constant size to the LED so that each LED blinks with constant illuminance. Bi-directional input power processing is enabled so that it can be turned on without lighting.

3 is a configuration diagram of the sensor and the control unit of FIG. 2.

As shown in FIG. 3, the detection sensor 150 includes an illumination sensor 151, a human body sensor 152, and an acoustic sensor 153. The controller 160 includes a dimming controller 161, The path setting section 162 and the power control section 163 are configured.

The illuminance sensor 151 is a sensor for detecting the illumination in the surrounding environment, the human body sensor 152 is a sensor for detecting the presence of a person in the surrounding environment, the sound sensor 153 Is a sensor that detects a specific preset sound in the surrounding environment.

The human body sensor 152 detects heat in the surrounding environment and outputs a human body detection signal. The human body sensor 152 is composed of a plurality of heat sensing cells to improve the sensing distance and the sensing angle. Each thermal sensor outputs a thermal signal and supplies it to the multiplexer. This thermal sensor can be configured as a thermopile sensor.

The multiplexer sequentially outputs the thermal sensing signals supplied in parallel from the thermal sensing cells in a time division manner and supplies them to the amplifier. The operational amplifier generates a human body detection signal by amplifying the heat detection signals sequentially supplied from the multiplexer, and supplies the human body detection signal to the controller 160.

The controller 160 sequentially compares the human body sensing signals supplied from the operational amplifier with the reference temperature data so that any one of the human body sensing signals is located within the range of the reference temperature data. If any human detection signal does not belong to the range of the reference temperature data, it is determined that no person exists in the surrounding environment.

The human body sensor 152 has a heat sensor as the main sensor, in order to increase the accuracy and reliability of the detection, the human body sensor 152 is one of ultrasonic sensors, Doppler sensors and infrared sensors in addition to the heat sensor. Any one or more may further include as an auxiliary sensor.

In addition, the human body sensor 152 according to the present invention may further include a motion sensor, the motion sensor detects movement in the surrounding environment, if there is movement, I judge it.

As described above, the human body sensor 152 may detect heat and movement together to more accurately detect the presence of a person in the surrounding environment.

The illuminance sensor 151, the human body sensor 152 and the acoustic sensor 153 may have the same detection range, each may have a different detection range.

Specifically, the dimming control unit 161 of the control unit 160 converts the illuminance of the surrounding environment in which the first and second LED fluorescent lamps 130 and 140 are installed from the detection result from the illuminance sensor 151, and converts the converted illuminance. The illuminance is adjusted based on the result and the preset reference illuminance.

For example, the dimming control unit 161 includes a memory in which a reference illuminance for a specific LED fluorescent lamp installed in a specific space at a specific time and weather is stored. The illuminance is adjusted such that the illuminance of the specific space is maintained at a preset reference illuminance according to the specific time and weather described above. In this case, the dimming controller 161 controls the operation of the power controller 163 to adjust or turn off the duty ratio of each driving current supplied to the first LED fluorescent lamp 130 or the second LED fluorescent lamp 140. .

In addition, the dimming control unit 161 determines the presence or absence of a person in the surrounding environment in which the light source unit is placed based on the detection result from the human body sensor 152, and according to the determination result, all the light sources provided in the light source unit Determine whether they are off and dimming. That is, when there is no person in a specific space, the first LED fluorescent lamp 130 is turned off to reduce power consumption, and the second LED fluorescent lamp 140 is dimmed by 50%.

If it is determined that a person exists in this particular space, the dimming control unit 161 controls the LED fluorescent lamp located in this space to irradiate light with a predetermined reference illuminance in the manner described above.

In addition, the dimming control unit 161 compares the sound in the surrounding environment in which the light source unit is placed with a preset reference sound based on the detection result from the sound sensor 153, and according to the comparison result Determine whether the light sources are off and dimming. For example, when a person within the detection range of the acoustic sensor 153 hits the applause three times, the acoustic sensor 153 supplies the detection result to the dimming controller 161 in response to the applause, and then the dimming controller 161 turns off or lights up all the fluorescent lamps in the space in which the first and second LED fluorescent lamps 130 and 140 are installed.

Meanwhile, the dimming controller 161 receives various information from the sensor 150 and outputs a low signal (that is, an unlit signal) together with a 50% dimming signal, and the path setting unit 162 receives the dimming controller. The two signals output from 161 are selectively supplied to the first LED fluorescent lamp 130 or the second LED fluorescent lamp 140.

The power control unit 163 receiving the two signals output from the path setting unit 162 supplies a 50% dimming signal to the first LED fluorescent lamp 130 or the second LED fluorescent lamp 140, and the first LED fluorescent lamp. The LED fluorescent light which does not receive the dimming signal from the 130 or the second LED fluorescent light 140 is automatically turned off.

Therefore, according to the result detected by the human body sensor 152 for the light source unit consisting of two LED fluorescent lamps, namely, the first and second LED fluorescent lamps 130 and 140, the first LED fluorescent lamp 130 is dimmed by 50% in the absence of the human body. By extinguishing the 2 LED fluorescent lamp 140 can save 50% to maximize the power saving efficiency.

FIG. 4 is a perspective view illustrating each LED fluorescent lamp of FIG. 1, and FIG. 5 is a cross-sectional view illustrating the LED fluorescent lamp along the line II-II ′ of FIG. 4.

As shown in FIGS. 4 and 5, the LED fluorescent lamp has a hemispherical heat dissipation plate 210 having a plurality of heat dissipation wings 211 in a length direction on a surface thereof, and the heat dissipation plate while being fastened to both sides of the heat dissipation plate 210. The light diffusing cover 220 having a hemispherical shape to form the internal space 216 together with the 210, and the space portion 216 between the heat sink 210 and the light diffusing cover 220 are arranged at regular intervals. A base board 240 formed of an insulating material while covering both ends of the light diffusion cover 220, including both ends of the heat dissipation plate 210 and the PCB board 230 having the plurality of LEDs 231 mounted thereon; It is configured to include a connection pin 241 made of a conductive material is formed at a predetermined interval in the form of protruding to the outer surface of the base 240 and inserted into the socket (not shown).

The heat sink 210 has a rib 212 protruding so as to extend to the heat dissipation wing 211 at the lower end on which the PCB substrate 230 is mounted, the rib 212 of the heat sink 210 Insert bolt insertion hole 213 is formed in the longitudinal direction is formed.

Here, the insert bolt insertion hole 213 is a hole into which an insert bolt (not shown) is inserted to fix the base 240 to the heat sink 210.

The heat dissipation plate 210 is configured to have a plurality of heat dissipation wings 211 in order to maximize the heat dissipation effect on the surface opposite to the surface on which the PCB substrate 230 is attached, so that the heat dissipation effect when the blue LED 231 emits light Can be maximized.

Between the insertion portions 214 formed at both ends of the heat dissipation plate 210, the plate 215 having a flat structure on the surface thereof and the space 216 above the plate 215 may be disposed between the insertion portions 214 formed on both ends of the heat sink 210. The rib 212 is formed to extend to the heat dissipation fin 211.

On the other hand, the space portion 216 may extend from the plate 215 to further configure a plurality of heat dissipation blades (not shown) may improve the heat dissipation effect.

The heat sink 210 is formed to have a predetermined length in a slim or stick type consisting of a semi-circular shape, and forms a main body of a lamp using the LED 231 in the present invention.

A converter (not shown) may be configured in the heat sink 210 or the light diffusion cover 220, which is arranged under the plate 215 and connected to the LED 231.

The converter can turn on each LED 231 even when power is input from either socket of the mercury discharge tube fluorescent lamp frame that is already installed, so it is not necessary to consider the coupling direction when installing the LED lamp to the frame, thereby enhancing consumer convenience. It cuts over voltage and over current of input power, removes surge voltage and noise from outside and supplies stable constant current of constant size to LED 231 so that each LED 231 can be turned on without blinking with constant illuminance. Bidirectional input power processing is enabled.

On the other hand, in the embodiment of the present invention has been described that the built-in converter, but not limited to this may be mounted on an external socket.

The LEDs 231 may be formed in a line on the PCB substrate 230, and further, the LEDs 231 may be arranged in a zigzag shape in both directions, or the members of the PCB substrate 230 may be flexible. The LED 231 may be arranged to form a constant gradient and have a plurality of rows on the PCB substrate 230 to extend the irradiation range.

Except for each LED 231 mounted portion of the PCB substrate 230, using a surface Ag, Al ₂ O ₃ , TiO ₂ , Al, PEN, PET using a white coating or a separate reflector attached Thus, the light source may be reflected when each LED 231 emits light.

The light diffusion cover 220 has a corresponding insertion portion 221 coupled to the insertion portion 214 formed at both ends of the heat dissipation plate 210 and has a hemispherical shape, and the thickness of both sides is relatively thinner than that of the upper center. Increasing the amount of light emitted to both sides is formed to extend the directivity angle of the light irradiated from the respective LEDs (231).

That is, the light diffusion cover 220 is formed in a hemispherical shape so as to be coupled to both ends of the heat dissipation plate 210, and the thickness of both sides is formed to be relatively thinner than the thickness of the upper center of the light diffusion cover 220. It is preferable to increase the transmission amount of light emitted to both sides of the cover 220 to increase the directivity angle of the light irradiated from the respective LEDs 231 to increase the lighting efficiency of the lamp.

And the configuration for coupling and separation of the heat sink 210 and the light diffusion cover 220 will be described together because it is implemented by the detachment means described below.

The detachment means has insertion portions 214 formed at both ends of the heat dissipation plate 210, and corresponding insertion portions 221 coupled to the insertion portion 214 are formed at both ends of the light diffusion cover 220. When the heat sink 210 and the light diffusion cover 220 are detached, the insertion part 214 and the corresponding insertion part 221 exert elasticity and are detached so that the heat sink 210 and the light diffusion cover 220 are separated. It is possible to ensure the ease of bonding and separation.

The base 240 is coupled to both ends of the heat sink 210 and the light diffusion cover 220 and is coupled to both ends thereof to fix them. Although the base 240 is described as an insulating material, the base 240 may be formed of a metal material in order to maximize the heat dissipation effect.

And the center of the base 240 is coupled to the connection pin 241 for supplying the power supplied from the outside to the lighting, in this case, the connection hole of the socket to be connected to the connection pin 241 is coated with a conductive material It is formed to enable the electrical connection to the LED lamp by the connection of the connection pin 241.

The insert bolt is inserted into a fastening hole (not shown) formed to correspond to the insert bolt insertion hole 213 through the surface of the base 240 to fix the base 240 to the heat sink 210. Fastening of the even more stable, even if the insert bolt is loosened and combined several times to prevent damage to the heat sink 210 made of aluminum.

In addition, a heat absorbing plate 250 made of a metal material may be separately configured between the PCB substrate 230 and the heat sink 210, wherein the heat absorbing plate 250 has a thickness of 0.2 mm and the LEDs. It serves to absorb heat generated from 231.

The heat absorbing plate 250 may be connected to the rear surface of the LED 231 through the PCB substrate 230 to transfer heat to the heat sink 210 when the LED 231 emits light.

The PCB substrate 230 uses an aluminum substrate having excellent thermal conductivity. In addition, the PCB substrate 230 may use a metal PCB substrate or a PCB substrate of a double copper foil structure or a flexible PCB substrate in order to proceed with heat dissipation efficiently.

On the other hand, the heat sink 210 and the light diffusion cover 220 in the LED fluorescent lamp according to the present invention has been described as a hemispherical shape as an example, but the shape can be arbitrarily changed according to the use, such as a rectangular or polygonal shape. .

The light diffusion cover 220 may contain a yellow phosphor, which may implement a white LED through wavelength conversion when the blue LED emits the blue LED using the LED 231 using a blue LED.

Except for each LED 231 mounted portion of the PCB substrate 130, using any one of the surface Ag, Al ₂ O ₃ , TiO ₂ , Al, PEN, PET to white coating or attach a separate reflector Thus, the light source may be reflected when each LED 231 emits light.

6 is a perspective view showing still another embodiment of the LED fluorescent lamp of FIG.

As shown in FIG. 6, the terminal pin 241 of the LED fluorescent lamp is not made of a metal material, but is made of an insulating material together with the base 240 and inserted into the socket 112 of the main body case 110. It serves to support the second LED fluorescent lamp (130,140).

At this time, the power supply penetrates one side of the base 240 and is connected to each of the LEDs 231 of FIG. 5, and a connector connected to an end of the conductive wire 260 to receive external power. The connection pin 270 is comprised.

In addition, a conductive wire 260 is connected through a portion where the base 240, the heat sink 210, and the light diffusion cover 220 are connected, and the conductive wire 260 is the PCB substrate (230 of FIG. 5). The power is applied to the connector connection pin 270 connected to each LED 231 mounted on the board or connected to the PCB board 230 to be connected to the outside to emit each LED 231.

The conductive wire 260 may be connected to each of the LEDs 231 mounted on the PCB substrate 230 through the center portion of the heat sink 210.

One end of the conductive wire 260 is connected to the connector connecting pin 270, which is connected to an external connector, the power applied through an external connector through each conductive wire 260 through each LED ( 231).

FIG. 7 is a perspective view illustrating still another embodiment of the LED fluorescent lamp of FIG. 1. FIG.

As shown in FIG. 7, the base 240 is made of an insulating material, and is formed in a protruding form at regular intervals on the outer surface of the base 240 to be inserted into the socket 112 of FIG. 1. Including a fixing pin 241 and a connecting pin 242 made of a conductive material formed in a shape protruding on the surface of the base 240 between the fixing pin 241 is inserted into the socket 112 Consists of.

Here, the base 240 and the fixing pin 241 is integrally formed, and is inserted into the socket 112 to support the first and second LED fluorescent lights 130 and 140. The connection pin 242 is inserted into the socket 121 and is supplied with power to emit the first and second LED fluorescent lamps 130 and 140.

On the other hand, the present invention described above is not limited to the above-described embodiment and the accompanying drawings, it is possible that various substitutions, modifications and changes within the scope without departing from the technical spirit of the present invention It will be apparent to those skilled in the art.

110: body case 120: reflector
130: first LED fluorescent tube 140: second LED fluorescent tube
150 detection sensor 160 control unit

Claims (8)

The main body case which has a socket in both ends of an inner side,
A reflection shade mounted on an inner middle portion of the main body case to reflect light;
First and second LED fluorescent lamps coupled to the main body case with the reflection shade therebetween to emit light;
A detection sensor attached to a ceiling or a wall adjacent to the main body case and detecting a presence of a human body;
Receiving information from the sensor, LED lighting apparatus comprising a control unit for extinguishing any one of the first, second LED fluorescent lamps in the absence of the human body and dimming the other LED fluorescent lamp 50%. The LED of claim 1, wherein the controller alternately turns off the first LED fluorescent lamp and the second LED fluorescent lamp and alternately performs 50% dimming according to a result of human body detection of the sensor. Lighting equipment. The method of claim 1, wherein the sensor detects the presence or absence of a human body and transmits the result to the controller, and the controller transmits information from the sensor to any one of the first and second LED fluorescent lamps. LED off, characterized in that the control to turn off the other 50% dimming. According to claim 1, wherein the sensor is an illumination sensor for detecting the illumination in the surrounding environment, a human body sensor for detecting the presence and movement of the human body in the surrounding environment, and predetermined preset in the surrounding environment LED lighting device, characterized in that consisting of a sound sensor for detecting sound. The method of claim 1, wherein the first and second LED fluorescent light is
A heat sink,
A light diffusion cover fastened to the heat sink to form a space part;
A PCB substrate coupled to the space part and mounted on the heat sink to mount a plurality of LEDs;
A base formed while covering both ends of the heat sink and the light diffusion cover;
LED lighting apparatus comprising a connection pin protruding on both sides of the base and inserted into the socket. The method of claim 5, wherein the fixing pins are formed on the outer surface of the base at regular intervals and protruded to form a protruding shape on the base surface between the fixing pins and a fixing pin made of an insulating material inserted into the socket. LED lighting apparatus comprising a connection pin made of a conductive material inserted into the socket. 6. The LED lighting device of claim 5, wherein the light diffusion cover contains a yellow phosphor, and the LED uses a blue LED. The LED lighting apparatus of claim 5, further comprising a heat absorbing plate disposed between the heat sink and the PCB substrate, wherein the heat absorbing plate is connected to the rear surface of the LED through the PCB substrate. .

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