KR101526261B1 - The smart led lighting with air sterilization - Google Patents

Abstract

The present invention relates to a smart LED lighting apparatus having an air sterilization function, which is configured to solve problems of the conventional LED lighting apparatuses that the conventional LED lighting apparatuses just light up surroundings thereof with LED lights through a dimming function, but since the conventional LED lighting apparatus does not have an additional heat dissipating means, crazing or whitening phenomenon can occur on the surface of a diffusion plate which diffuses LED lights to the outside, due to the high temperature, and that the conventional LED lighting apparatuses do not have a self-air sterilization function such that additional air sterilizer needs to be prepared in places such as hospitals or nursery facilities in which air sterilization is necessary, thereby taking long period of time for installation and increasing costs. More specifically, the smart LED lighting apparatus according to the present invention comprises: a cross-shaped main body (100); an impact air sterilizer (200); cross-shaped hybrid LED modules (300); a smart controller (400). Accordingly, the smart LED lighting apparatus is capable of, primarily and secondarily sterilizing indoor air through a UV LED formed therein while emitting LED lights, being automatically driven according to sensed indoor illumination and air contamination, thereby creating a comfortable and clean indoor environment, and forcibly dissipating heat generated from the cross-shaped hybrid LED modules through a suction fan and convection circulation. Thus, the lifetimes of an RGB LED chip and a UV LED chip can be improved as much as 70%, compared to those of the conventional LED lighting apparatuses, and a brightness and colors can be customized to fit the lighting mood of a user.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a smart LED lamp having an air sterilizing function,

In the present invention, it is possible to sterilize the indoor air through the UV LED in the LED lamp itself, and to generate the smell in the sterilized indoor air while emitting the LED light, To a smart LED luminaire having an air sterilizing function that can be automatically driven.

Currently, discharge lamps such as fluorescent lamps, incandescent lamps, and halogen lamps are used as indoor light sources for homes and offices.

Since such a discharge lamp has a high driving voltage, energy consumption due to the step-up of power is large, and discharge gas such as mercury, which is harmful to the human body or the environment, is discharged at the time of disposal, which causes environmental pollution and can not be recycled.

In particular, the European Union prohibits the use of harmful substances such as lead, mercury, cadmium, hexavalent chromium (Cr6 +), PBB (polybromide binpenyl) and PBDE (polybrominated diphenyl ether) Establishment of Waste Electrical and Electronic Equipment Directive (WEEE), which allows producers to bear the cost of recycling of hazardous substances (RoHS (Restriction of Use of Hazardous Substances) and waste electrical and electronic products. And it has been implemented since July 1, 2006.

In addition, with the rapid development of LED (light emitting diode) related technology, white LEDs emitting white light by using blue LEDs and phosphors have appeared, Small size, low power consumption, semi-permanent life span, environment friendly light source that does not emit harmful waves such as ultraviolet rays, and does not use mercury and discharge gas. It is widely regarded as a viable means to replace existing lighting sources. have.

Accordingly, an LED lighting device has been proposed as an illumination device that uses an LED that replaces a lighting device such as a fluorescent lamp currently used as a light source.

However, conventional LED luminaires merely illuminate the surroundings through LED light through dimming function, there is no separate heat dissipation means, and the diffuse plate surface diffusing the LED light externally causes a residue or whitening due to high temperature .

In addition, since the conventional LED lamp does not have an air sterilizing function by itself, a separate air sterilizer is required in places such as a hospital or a nursing home where sterilization of the air is required, thus requiring a long installation time and a high cost.

Korean Patent Registration No. 10-1248152

In order to solve the above problems, in the present invention, the indoor air can be sterilized by the LED lamp itself through the UV LED while emitting the LED light, and can be automatically driven according to the indoor illumination sensing and the air pollution sensing The heat generated from the cruciform hybrid LED module can be forcibly dissipated through the suction fan and the convection circulation, and the air sterilizing function which can adjust the brightness and color of the lighting by 1: 1 customized according to the user's lighting mood And a smart LED luminaire having a plurality of LEDs.

In order to achieve the above object, a smart LED lamp having an air sterilizing function according to the present invention

A cross-shaped body 100 formed in a cross shape and protecting and supporting each device by external pressure,

An impact air sterilizer installed at one side of the inner space at the center intersection of the cross-shaped body to suck indoor air to induce impact on the UV LED at the upper side to sterilize the primary air and then discharge the air to the cross- 200,

Shaped cross-shaped hybrids that are disposed at one side of the cross-shaped body and are cross-shaped and sterilize the primary air through the impact air sterilizing unit while the LED light is emitted according to the control signal of the smart control unit, An LED module 300,

The impact air sterilizer, and the cross-shaped hybrid LED module are connected to each other, and the smart controller 400 controls the overall operation of each device.

As described above, according to the present invention, it is possible to sterilize the indoor air through the UV LED in the LED lamp itself, while emitting the LED light, and it is excellent in compatibility, It is possible to extend the range by more than 80%, and it can be driven automatically according to the indoor illumination sensing and air pollution sensing to create a pleasant and clean indoor atmosphere, and the heat generated from the cruciform hybrid LED module can be circulated through the suction fan and the convection circulation The life of the RGB LED chip and the UV LED chip can be improved by 70% compared to the conventional one, the smell can be generated in the first and second sterilized indoor air, and moreover, 1: 1 customized to match the brightness and color can be adjusted to have a good effect.

1 is a perspective view showing components of a smart LED lamp 1 having an air sterilizing function according to the present invention,
2 is an exploded perspective view showing components of a smart LED lamp 1 having an air sterilizing function according to the present invention,
3 is a block diagram showing the components of the impact air sterilizer according to the present invention,
FIG. 4 is a block diagram showing the components of the matrix type UVLED module according to the present invention,
FIG. 5 is a block diagram illustrating components of a cross-shaped hybrid LED module according to the present invention.
6 is a block diagram illustrating components of a first hybrid LED module according to the present invention.
FIG. 7 is a block diagram illustrating components of a first hybrid LED driving driver unit according to the present invention;
8 is a circuit diagram showing components of the first, second, third, and fourth UV LED driver IC portions according to the present invention,
FIG. 9 is a block diagram illustrating components of a first RGB LED driving driver according to the present invention.
10 is a block diagram illustrating components of a second hybrid LED module according to the present invention.
11 is a block diagram illustrating components of a second hybrid LED driver driver unit according to the present invention.
12 is a block diagram illustrating components of a second RGB LED driving driver according to the present invention.
13 is a block diagram illustrating components of a third hybrid LED module according to the present invention.
FIG. 14 is a block diagram illustrating components of a third hybrid LED driver driver unit according to the present invention;
15 is a block diagram illustrating components of a third RGB LED driver according to the present invention.
16 is a block diagram illustrating components of a fourth hybrid LED module according to the present invention,
17 is a block diagram illustrating components of a fourth hybrid LED driver section according to the present invention.
18 is a block diagram illustrating components of a fourth RGB LED driving driver according to the present invention.
19 is a block diagram showing components of a smart control unit according to the present invention,
FIG. 20 is a flowchart illustrating an operation procedure of a smart LED lamp having an air sterilizing function according to the present invention,
FIG. 21 is a cross-shaped hybrid LED module according to the present invention, in which the LED light is emitted according to the control signal of the smart control unit, the primary air is sterilized through the impact air sterilizing unit, the remaining air is sterilized through the UV LED, One embodiment showing the ejection of sterilized air and fragrance is also shown.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a perspective view illustrating components of a smart LED lamp 1 having an air sterilizing function according to the present invention, which includes a cross-shaped body 100, an impact air sterilizer 200, a cruciform hybrid LED module 300 ), And a smart control unit 400.

First, a cross-shaped body 100 according to the present invention will be described.

The cross-shaped body 100 has a cross shape and serves to protect and support each device with external pressure.

As shown in FIG. 2, the impact air sterilizer is formed on one side of the inner space at the center intersection of the cross-shaped body, the cruciform hybrid LED module is formed in a cross shape on the basis of the impact air sterilizer, and the matrix- And a smart control unit is formed on one side of the module.

When viewed from the front, the first hybrid LED module is formed on one side of the left side of the cross-shaped body, the second hybrid LED module is formed on one side of the right side of the cross-shaped body when viewed from the front, When viewed from the front, the third hybrid LED module is formed on one side of the front surface of the cross-shaped body, and the fourth hybrid LED module is formed on one side of the rear surface of the cross-shaped body when viewed from the front side.

Next, the impact air sterilizer 200 according to the present invention will be described.

The impact air sterilizer 200 is installed on one side of the internal space of the center crossing portion of the cross body to suck indoor air to induce impact on the upper UV LED side to sterilize the primary air, Respectively.

3, the sterilizing body 210, the suction fan 220, the suction motor unit 230, the matrix UVLED module 240, and the perfume module 250 are configured as shown in FIG.

First, the sterilization body 210 according to the present invention will be described.

The sterilizing body 210 has a rectangular block structure in which the inner upper end is blocked and the lower end is penetrated and the inner side faces connected to the cruciform hybrid LED module are all penetrated to protect and support each device from external pressure.

A suction fan is formed on a lower side, a suction motor is formed on a rotary shaft of the suction fan, and a matrix UVLED module is formed on an upper end of the suction motor.

Second, the suction fan 220 according to the present invention will be described.

The suction fan 220 is positioned at a lower end of the sterilizing body so as to suck indoor air to induce impacts toward the upper matrix type UVLED module.

This is configured such that one side of the rotating shaft is connected to the suction motor unit.

Third, the suction motor unit 230 according to the present invention will be described.

The suction motor unit 230 is connected to one side of the rotation shaft of the suction fan and generates a driving force according to a control signal of the smart control unit.

This is configured to adjust the forward / reverse rotation direction and rotation speed in accordance with the control signal of the smart control unit.

Fourth, the matrix type UVLED module 240 according to the present invention will be described.

The matrix-type UVLED module 240 is positioned at one side of the upper end of the internal space of the sterilizing body and is driven according to a control signal of the smart control unit to sterilize the indoor air impacted from the suction fan through the UVLED light.

As shown in Fig. 4, this is constituted by a matrix-type UVLED chip 241 and a matrix-type UVLED chip driver IC 242.

The matrix type UVLED chip 241 is driven in accordance with the control signal of the matrix type UVLED chip driver IC to sterilize the indoor air impacted from the suction fan through the UVLED light

It is constructed and arranged on a matrix-type UVLED substrate.

Here, the matrix type UVLED substrate has a plurality of air holes formed on the surface thereof, and guides a perfume generated from a perfume module located at one side of the upper side into a lower direction through an air hole.

The matrix type UVLED chip driver IC 242 sets 200 to 300 nm of the wavelengths generated in the matrix type UVLED chip to the first channel, sets the second channel to 301 to 400 nm, And setting a channel of 501 nm to 600 nm to the fourth channel and then controlling to drive any one of the four channels so that the constant current source of the linear type and the constant voltage source of the switch type are integrated into one chip, .

Fifth, the fragrance module 250 according to the present invention will be described.

The perfume module 250 is detachably installed on one side of the upper side of the matrix-type UVLED module, and functions to generate a perfume in the room air sterilized through the matrix-type UVLED module.

It consists of a solid square panel structure and is formed in a detachable manner.

As described above, since the perfume module according to the present invention is constructed, the perfume can be generated in the room air sterilized by the matrix type UVLED module, and the room air can be automatically made pleasant and fragrant It has good effect.

Next, the cross-shaped hybrid LED module 300 according to the present invention will be described.

The cross-shaped hybrid LED module 300 is installed at one side of the cross-shaped body and is formed in a cross shape. The LED light is emitted according to the control signal of the smart control unit, and the air is sterilized by the primary air through the impact air sterilizer, To act as a secondary air disinfection.

As shown in FIG. 5, the first hybrid LED module 310, the second hybrid LED module 320, the third hybrid LED module 330, and the fourth hybrid LED module 340 are configured.

First, the first hybrid LED module 310 according to the present invention will be described.

The first hybrid LED module 310 is installed on one side of the left side of the cruciform body when viewed from the front and emits light of RGB LED according to the control signal of the smart control unit and is sterilized by the primary air through the impact air sterilizer It receives air and serves to sterilize secondary air through UV LED.

As shown in FIG. 6, the first hybrid LED driving driver 312, the first hybrid LED chip 313, the first diffusion cover 314, the first discharge unit 315).

[First module main body 311]

The first module main body 311 has a straight shape and protects and supports each device from external pressure.

This is formed by inserting a rubber packing member between the contact surface and the surface.

The rubber packing member is formed in the first module body to prevent foreign matter from entering the space inside the module body and to create a natural circulation atmosphere between the intake fan and the exhaust through the convection phenomenon.

[First hybrid LED  Driving driver section 312]

The first hybrid LED driving driver 312 may be formed in a shape of a rectangle on one side of the inner space of the first module body and may include at least one of the first RGB LED chip and the first UV LED chip And to select and drive it.

As shown in FIG. 7, this includes a first RGB LED driver 312a and a first UV LED driver 312b.

The first RGB LED driving driver 312a drives the first RGB LED chip.

9, the first fuse portion 312a-1, the first NTC thermistor portion 312a-2, the first surge observer portion 312a-3, the first EMI line filter portion 312a -4), and a first bridge rectifier 312a-5.

The first fuse portion 312a-1 serves to protect the circuit by blocking an overcurrent flowing along one side of the LED lamp socket.

The first NTC thermistor part 312a-2 causes a voltage to flow into the circuit while gradually reducing the resistance of the first NTC thermistor part 312a-2.

The first surge observer unit 312a-3 serves to filter electrical noise generated in the current flowing into the first fuse unit and the first NTC thermistor unit.

The first EMI line filter unit 312a-4 serves to remove noise of a commercial AC power source that has passed through the first surge observer.

The first bridge rectifier 312a-5 rectifies the voltage output from the first EMI line filter unit to DC voltage, and then supplies the voltage to the RGB LED chip.

The first UV LED driving driver 312b drives the first UV LED chip.

As shown in Fig. 8, this includes a first UV LED driver IC portion 312b-1.

The first UV LED driver IC unit sets 200 to 300 nm of the wavelengths generated in the first UV LED chip to a first channel, sets 301 to 400 nm to a second channel, sets 401 to 500 nm to a third channel , 501 nm to 600 nm are set as the fourth channel, and then any one of the four channels is selected and driven to control the selection and control of the constant-current source of the linear system and the constant voltage source of the switch system in one chip .

[First hybrid LED  Chip section 313]

The first hybrid LED chip unit 313 includes a first hybrid LED driving driver unit and a bidirectional PCB substrate. A plurality of first RGB LED chips 313a are formed in a line along a center line of the bidirectional PCB substrate. A plurality of first UV LED chips 313b are formed on both sides of one RGB LED chip to generate RGB LED light or UV LED sterilizing light.

[First diffusion cover (314)]

The first diffusion cover 314 is formed on the front surface of the first hybrid LED chip unit to guide the indoor air that has been firstly sterilized through the first UVLED module of the impact air sterilizing unit to the first hybrid LED chip unit , And diffuse the emitted RGB LED light to the outside.

[First discharge portion 315]

The first exhaust unit 315 may include a plurality of exhaust holes formed on one side of the rear end side of the first diffusion cover and a second sterilized indoor air through the first UV LED chip of the first hybrid LED chip unit through the exhaust hole And conveys it to the outside using the convection phenomenon.

The indoor air that is secondarily sterilized through the first discharge portion can be discharged to the outside by the use of the convection phenomenon because the rubber packing member is inserted and sealed between the contact surface and the surface of the first module body, And a plurality of exhaust holes are formed along the side surface of the exhaust pipe.

Second, the second hybrid LED module 320 according to the present invention will be described.

The second hybrid LED module 320 is installed on one side of the right side of the cross-shaped body when viewed from the front, and emits lights of RGB LED according to the control signal of the smart control unit, and sterilizes the primary air through the impact air sterilizer And serves to sterilize secondary air through UV LED.

10, the second module main body 321, the second hybrid LED driving driver unit 322, the second hybrid LED chip unit 323, the second diffusion cover 324, the second discharge unit 325).

[Second Module Main Body 321]

The second module main body 321 has a straight shape and protects and supports each device from external pressure.

This is formed by inserting a rubber packing member between the contact surface and the surface.

The rubber packing member is formed in the second module body to prevent foreign matter from entering the space inside the module body and to create a natural circulation atmosphere between the intake fan and the exhaust through the convection phenomenon.

[Second hybrid LED  Driver Driver Unit 322]

The second hybrid LED driving driver 322 may be formed in a linear shape on one side of the inner space of the second module body and may include at least one of the second RGB LED chip and the second UV LED chip in accordance with a control signal of the smart controller And to select and drive it.

As shown in FIG. 11, the second RGB LED driving driver 322a and the second UV LED driving driver 322b are configured.

The second RGB LED driver 322a drives the second RGB LED chip.

As shown in FIG. 12, the second fuse portion 322a-1, the second NTC thermistor portion 322a-2, the second surge observer portion 322a-3, the second EMI line filter portion 322a -4) and a second bridge rectifying section 322a-5.

The second fuse portion 322a-1 serves to protect the circuit by blocking an overcurrent flowing along one side of the LED lamp socket.

When the second NTC thermistor 322a-2 has a high resistance among the initial voltages passing through the second fuse portion, if the voltage can not flow into the circuit, the voltage is gradually introduced into the circuit while gradually reducing the resistance.

The second surge observer section 322a-3 serves to filter electrical noise generated in the current flowing into the second fuse section and the second NTC thermistor section.

The second EMI line filter unit 322a-4 serves to remove the noise of the commercial AC power that has passed through the second surge observer.

The second bridge rectifier 322a-5 rectifies the voltage output from the second EMI line filter unit to DC voltage, and then supplies the voltage to the second RGB LED chip.

The second UV LED driving driver 322b drives the second UV LED chip.

As shown in Fig. 8, the second UV LED driver IC portion 322b-1 is included.

The second UV LED driver IC unit sets 200 to 300 nm of the wavelength generated in the second UV LED chip to a first channel, sets 301 to 400 nm to a second channel, sets 401 to 500 nm to a third channel, After setting 501 to 600 nm as the fourth channel, control is performed so that any one of the four channels is selected and driven, and both the constant current source of the linear type and the constant voltage source of the switch type are used. Integrated on the chip to control the selection.

[Second hybrid LED  Chip portion 323]

The second hybrid LED chip portion 323 includes a second hybrid LED driver driver portion and a bidirectional PCB substrate. A plurality of second RGB LED chips are formed in a line along a center line of the bidirectional PCB substrate. A plurality of second UV LED chips are formed to generate RGB LED light or UV LED sterilizing light.

[Second diffusion cover 324]

The second diffusion cover 324 is formed on the front surface of the second hybrid LED chip unit to guide the indoor air that has been firstly sterilized through the second UVLED module of the impact air sterilizer to the first hybrid LED chip unit , And diffuse the emitted RGB LED light to the outside.

[Second discharge portion 325]

The second discharge portion 325 forms a plurality of exhaust holes on one side of the rear end side of the second diffusion cover and conveys the second sterilized indoor air through the UV LED chip of the second hybrid LED chip portion through the exhaust hole, And discharging it to the outside.

In this case, the indoor air that is secondarily sterilized through the second discharge portion can be discharged to the outside by the convection phenomenon because the rubber packing member is inserted and sealed between the contact surface and the surface of the second module body, And a plurality of exhaust holes are formed along the side surface of the exhaust pipe.

Third, the third hybrid LED module 330 according to the present invention will be described.

The third hybrid LED module 330 is installed on one side of the front surface of the cross-shaped body when viewed from the front. The third hybrid LED module 330 emits light of RGB LED according to the control signal of the smart control unit and is sterilized by the primary air through the impact air sterilizer It receives air and serves to sterilize secondary air through UV LED.

13, the third module main body 331, the third hybrid LED driving driver section 332, the third hybrid LED chip section 333, the third diffusion cover 334, the third discharge section 335).

[Third Module Main Body 331]

The third module main body 331 is formed in a linear shape and protects and supports each device from external pressure.

This is formed by inserting a rubber packing member between the contact surface and the surface.

The rubber packing member is formed in the second module body to prevent foreign matter from entering the space inside the module body and to create a natural circulation atmosphere between the intake fan and the exhaust through the convection phenomenon.

[Third hybrid LED  Driving Driver Unit 332]

The third hybrid LED driving driver unit 332 is formed in a linear shape on one side of the inner space of the third module main body and controls the third RGB LED chip and the third UV LED chip according to a control signal of the smart control unit And to select and drive it.

As shown in FIG. 14, this includes a third RGB LED driver 332a and a third UV LED driver 332b.

The third RGB LED driver driver 332a drives the third RGB LED chip.

15, the third fuse portion 322a-1, the third NTC thermistor portion 332a-2, the third surge observer portion 332a-3, the third EMI line filter portion 332a -4), and a third bridge rectifying section 332a-5.

The third fuse portion 332a-1 serves to protect the circuit by blocking the overcurrent flowing along the LED lamp socket on one side.

The third NTC thermistor portion 332a-2 causes a voltage to be introduced into the circuit while gradually reducing the resistance when the voltage of the third NTC thermistor portion 332a-2 passes through the third fuse portion.

The third surge observer section 332a-3 serves to filter the electrical noise generated in the current flowing into the third fuse section and the third NTC thermistor section.

The third EMI line filter unit 332a-4 serves to remove the noise of the commercial AC power source that has passed through the third surge observer.

The third bridge rectifying unit 332a-5 rectifies the voltage output from the third EMI line filter unit to DC voltage, and supplies the voltage to the third RGB LED chip.

The third UV LED driving driver 332b drives the third UV LED chip.

As shown in Fig. 8, this includes a third UV LED driver IC portion 332b-1.

The third UV LED driver IC unit sets 200 nm to 300 nm of the wavelength generated in the third UV LED chip to a first channel, sets 301 nm to 400 nm to a second channel, sets 401 nm to 500 nm to a third channel , 501 nm to 600 nm are set as the fourth channel, and then any one of the four channels is selected and driven to control the selection and control of the constant-current source of the linear system and the constant voltage source of the switch system in one chip .

[Third hybrid LED  Chip unit 333]

The third hybrid LED chip unit 333 includes a third hybrid LED driving driver unit and a bidirectional PCB substrate. A plurality of third RGB LED chips are formed in a line along a center line of the bidirectional PCB substrate. A plurality of third UV LED chips are formed on both sides of the chip to generate RGB LED light or UV LED sterilizing light.

[Third diffusion cover (334)]

The third diffusion cover 334 is formed on the front surface of the third hybrid LED chip unit to guide the indoor air that has been firstly sterilized through the third UVLED module of the impact air sterilizer to the third hybrid LED chip unit , And diffuse the emitted RGB LED light to the outside.

[Third Discharging Unit 335]

The third discharge portion 335 is formed by forming a plurality of exhaust holes on one side of the rear end side of the third diffusion cover and supplying the second sterilized indoor air through the third UV LED chip of the third hybrid LED chip portion through the exhaust hole And conveys it to the outside using the convection phenomenon.

The room air sterilized secondarily through the third outlet can be discharged to the outside by the convection phenomenon because the rubber packing member is inserted and sealed between the contact surface and the surface of the third module body, And a plurality of exhaust holes are formed along the side surface of the exhaust pipe.

Fourth, the fourth hybrid LED module 340 according to the present invention will be described.

The fourth hybrid LED module 340 is installed at one side of the rear end face of the cross-shaped body when viewed from the front, and emits light of RGB LED according to the control signal of the smart control unit, and is sterilized by the primary air through the impact air sterilizer It receives air and serves to sterilize secondary air through UV LED.

16, the fourth module main body 341, the fourth hybrid LED driving driver unit 342, the fourth hybrid LED chip unit 343, the fourth diffusion cover 344, the third discharge unit 345).

[Fourth module main body 341]

The fourth module main body 341 has a straight shape and protects and supports each device from external pressure.

This is formed by inserting a rubber packing member between the contact surface and the surface.

The rubber packing member is formed in the fourth module body to prevent foreign matter from entering the space inside the module body and to create a natural circulation atmosphere between the intake fan and the exhaust through the convection phenomenon.

[Fourth hybrid LED  Driving Driver Unit 342]

The fourth hybrid LED driving driver 342 is formed in a linear shape on one side of the inner space of the fourth module main body and controls the fourth RGB LED chip and the fourth UV LED chip according to the control signal of the smart control unit And to select and drive it.

As shown in FIG. 17, this is constituted by a fourth RGB LED driver 342a and a fourth UV LED driver 342b.

The fourth RGB LED driving driver 342a drives the fourth RGB LED chip.

As shown in FIG. 18, the fourth fuse portion 342a-1, the fourth NTC thermistor portion 342a-2, the fourth surge observer portion 342a-3, the fourth EMI line filter portion 342a -4), and a fourth bridge rectifying section 342a-5.

The fourth fuse portion 342a-1 serves to protect the circuit by blocking the overcurrent flowing along the LED lamp socket on one side.

The fourth NTC thermistor portion 342a-2 causes the voltage to flow into the circuit while gradually reducing the resistance when the resistance of the initial voltage passing through the fourth fuse portion 342 is high and the voltage can not flow into the circuit.

The fourth surge observer portion 342a-3 serves to filter electrical noise generated in the current flowing into the fourth fuse portion and the fourth NTC thermistor portion.

The fourth EMI line filter unit 342a-4 serves to remove noise of a commercial AC power source that has passed through a fourth surge observer.

The third bridge rectifier 342a-5 rectifies the voltage output from the fourth EMI line filter unit to DC voltage, and supplies the voltage to the fourth RGB LED chip.

The fourth UV LED driving driver 342b drives the fourth UV LED chip.

As shown in Fig. 8, this includes a fourth UV LED driver IC portion 342b-1.

The fourth UV LED driver IC unit sets 200 to 300 nm of the wavelength generated in the fourth UV LED chip to the first channel, sets 301 to 400 nm to the second channel, sets 401 to 500 nm to the third channel , 501 nm to 600 nm are set as the fourth channel, and then any one of the four channels is selected and driven to control the selection and control of the constant-current source of the linear system and the constant voltage source of the switch system in one chip .

[Fourth hybrid LED  Chip portion 343]

The fourth hybrid LED chip unit 343 includes a third hybrid LED driving driver unit and a bi-directional PCB substrate. A plurality of fourth RGB LED chips are formed in a line along a center line of the bi-directional PCB substrate. A plurality of fourth UV LED chips are formed on both sides of the chip to generate RGB LED light or UV LED sterilizing light.

[Fourth diffusion cover (344)]

The fourth diffusion cover 344 is formed on the front surface of the fourth hybrid LED chip unit to guide the indoor air that has been primarily sterilized and remained through the fourth UVLED module of the impact air sterilizing unit to the fourth hybrid LED chip unit , And diffuse the emitted RGB LED light to the outside.

[Fourth Exhaust Portion 345]

The fourth discharge unit 345 includes a plurality of exhaust holes formed on one side of the rear end side of the fourth diffusion cover and a second sterilized indoor air through the fourth UV LED chip of the fourth hybrid LED chip unit through the exhaust hole And conveys it to the outside using the convection phenomenon.

In this case, the indoor air that is secondarily sterilized through the fourth discharge portion can be discharged to the outside by the convection phenomenon because the rubber packing member is inserted and sealed between the contact surface and the surface of the fourth module body, And a plurality of exhaust holes are formed along the side surface of the exhaust pipe.

Next, the smart control unit 400 according to the present invention will be described.

The smart control unit 400 is connected to the impact air sterilizing unit and the cruciform hybrid LED module, and controls the overall operation of each device.

It consists of a one-chip microcomputer.

The one-chip microcomputer is connected to a light intensity sensor for sensing the illuminance of an indoor space on one side of the input terminal, and an air pollution measuring sensor for sensing air contamination of the indoor space is connected to another input terminal. A WiFi communication module is connected to one side of the terminal to form a local area network through another neighboring smart LED luminaire and an identification ID or to transmit the operation state of a smart LED luminaire currently driven to a remote control server do.

The smart control unit 400 may be configured to select one of the RGB LED emission mode 410, the UV LED sterilization mode 420, and the hybrid mode 430, as shown in FIG.

The RGB LED emission mode 410 drives the first, second, third, and fourth RGB LED driver drivers of the cross-type hybrid LED module to emit LED lights through the first, second, third, and fourth RGB LED chips .

The UV LED disinfection mode 420 drives the matrix type UVLED chip driver IC so that the indoor air impacted from the suction fan is firstly sterilized through the UVLED light and then the first, The air is sterilized by the primary air and the remaining air is received, and the secondary air is sterilized through the UV LED.

The hybrid mode 430 simultaneously drives the RGB LED emission mode and the UV LED sterilization mode.

In addition, the first, second, third, and fourth module bodies according to the present invention are characterized by being made of a heat-resisting, durable, lightweight aluminum alloy material.

The first, second, third, and fourth module main bodies may be formed of at least one of Cu 0.05 wt%, Si 0.25 wt%, Mg 0.05 wt%, Zn 0.05 wt%, Mn 0.05 wt%, Fe 0.40 wt%, Ti 0.03 wt% Pure Al-based Al 1050 having a composition of 5.0 to 17 wt.% Of Si and 0.1 to 5.0 wt.% Of Cu was added thereto in an electric furnace at a temperature of 700 to 750 占 폚 to add 10 The alloy is made of an Al-Si-Cu alloy prepared by mechanically stirring for 15 minutes and injecting a molten metal into a casting mold, the Al-Si-Cu alloy being surface-coated,

The coating treatment is a heat treatment of graphite oxide prepared by mixing _{3 to} 10 wt% of graphite, 75 to 85 wt% of a solution obtained by mixing sulfuric acid and nitric acid at 7: 3 vol%, and 10 to 30 wt% of oxidizing agent KClO ₃ at 1,000 ° C. The obtained graphene is coated with a coating solution prepared by blending the graphene with water containing sodium dodecyl as a spraying agent in a ratio of 1: 1.

The pure aluminum-based Al 1050 has a composition of 0.05 wt% of Cu, 0.25 wt% of Si, 0.05 wt% of Mg, 0.05 wt% of Zn, 0.05 wt% of Mn, 0.40 wt% of Fe, 0.03 wt% of Ti and 98.72 wt% Having excellent corrosion resistance, high thermal conductivity and electrical conductivity, and excellent workability.

In the present invention, a ternary alloy of Al-Si-Cu excellent in thermal conductivity and mechanical properties is manufactured using Al 1050 of pure aluminum which is excellent in thermal conductivity and electrical conductivity, It accomplishes.

In addition, the present invention provides a lightweight aluminum alloy excellent in heat radiation property and durability due to high thermal conductivity by finishing the surface of a ternary alloy of Al-Si-Cu excellent in thermal conductivity by graphen coating.

As a concrete example of the coating solution, graphite oxide prepared by mixing ₃ wt% of graphite, 80 wt% of a solution obtained by mixing sulfuric acid and nitric acid at 7: 3 vol%, and 17 wt% of an oxidizing agent KClO ₃ was heat- The graphene is mixed with water containing a spraying agent sodium dodecyl at a weight ratio of 1: 1 to prepare a coating solution.

Specifically, in order to remove the oxide film and contaminants formed on the aluminum surface layer, the contamination layer was removed using a # 600 to # 2000 sand paper, followed by ultrasonic washing in an acetone solvent for 10 minutes. do.

The coating is sprayed at an injection rate of 200 μl / min using an ESC (Electro Spray Coating) apparatus, and the injection amount is 0.25 ml / cm 2 to 1 ml / cm 2.

After the coating is completed, heat treatment is performed at 500 ° C for 5 minutes to evaporate the impurities.

Hereinafter, a specific operation process of the smart LED lamp having the air sterilizing function according to the present invention will be described.

First, the cross-shaped body is installed on the ceiling or side wall of the indoor space.

Next, the smart control unit receives the control signal from the remote control server through the WiFi communication module and applies power to each device to drive it.

Next, as shown in FIG. 20, the impact air sterilizer sucks indoor air to induce impact on the UV LED at the upper side to sterilize the primary air, and then discharge the air to the cross-type hybrid LED module through convection.

At this time, fragrance is generated in sterilized indoor air in the perfume module 250.

Next, as shown in FIG. 21, in the cruciform hybrid LED module, the LED light is emitted according to the control signal of the smart control unit, and the primary air is sterilized through the impact air sterilizer and the remaining air is sterilized through the UV LED .

At this time, the secondary sterilized air and the fragrance are discharged.

Finally, the smart control unit receives the external control signal and the control signal of the control server, turns off the RGB LED emission mode, and sterilizes the indoor air first and secondarily through only the pure UV LED sterilization mode.

1: Smart LED luminaire 100: Cross-shaped body
200: Impact air sterilizer 300: Cross-shaped hybrid LED module
400: Smart control unit

Claims (7)

A cross-shaped body 100 formed in a cross shape and protecting and supporting each device by external pressure,
An impact air sterilizer installed at one side of the inner space at the center intersection of the cross-shaped body to suck indoor air to induce impact on the UV LED at the upper side to sterilize the primary air and then discharge the air to the cross- 200,
Shaped cross-shaped hybrids that are disposed at one side of the cross-shaped body and are cross-shaped and sterilize the primary air through the impact air sterilizing unit while the LED light is emitted according to the control signal of the smart control unit, An LED module 300,
An impact air sterilizer, and a cross-shaped hybrid LED module are connected to each other to control the overall operation of each device.
The apparatus according to claim 1, wherein the impact air sterilizer (200)
A sterilizing body 210 having a rectangular block structure with an inner upper end blocked and a lower end penetrated and connected to the cruciform hybrid LED module so as to protect and support each device from external pressure,
A suction fan 220 positioned at a lower end side of the sterilizing body and sucking indoor air to induce an impact to the upper matrix type UVLED module,
A suction motor unit 230 connected to one side of the rotary shaft of the suction fan to generate a driving force in accordance with a control signal of the smart control unit,
A matrix type UVLED module 240 which is positioned at an upper side of the upper space of the inner space of the sterilizing body and is driven according to a control signal of the smart control unit to sterilize the indoor air impacted from the suction fan through the UVLED light,
And a perfume module (250) detachably attached to one side of the upper side of the matrix type UVLED module to generate a perfume in sterilized indoor air through the matrix type UVLED module.
The hybrid vehicle according to claim 1, wherein the cross-shaped hybrid LED module (300)
When viewed from the front, it is installed on one side of the left side of the cross-shaped body, and it emits the RGB LED light according to the control signal of the smart control unit, receives the air which is sterilized by the primary air through the impact air sterilizer, A first hybrid LED module 310 for sterilizing air,
When viewed from the front, it is installed on one side of the right side of the cross-shaped body, and it emits the RGB LED light according to the control signal of the smart control unit, receives the air that has been sterilized by the primary air through the impact air sterilizer, A second hybrid LED module 320 for sterilizing,
When viewed from the front, it is installed on one side of the cross section of the cross-shaped body, and it emits the RGB LED light according to the control signal of the smart control unit, receives the air that has been sterilized by the primary air through the impact air disinfection unit, A third hybrid LED module 330 for air sterilization,
When viewed from the front, it is installed on one side of the rear side of the cross-shaped body, and it emits the RGB LED light according to the control signal of the smart control unit, receives the air that has been sterilized by the primary air through the impact air sterilizer, And a fourth hybrid LED module (340) for air sterilization.
4. The system of claim 3, wherein the first hybrid LED module (310)
A first module body 311 formed in a straight shape and protecting and supporting each device from external pressure,
A first hybrid LED driving driver unit 312 for selectively driving at least one of the first RGB LED chip and the first UV LED chip in accordance with a control signal of the smart control unit, )Wow,
A plurality of first RGB LED chips are formed in a line along a center line of the bidirectional PCB substrate and a plurality of first UV LED chips are formed on both sides of the RGB LED chip A first hybrid LED chip part 313 for generating RGB LED light or UV LED sterilizing light,
The first hybrid LED chip portion is formed on the front surface of the first hybrid LED chip portion to guide the indoor air that is firstly sterilized and remained through the first UVLED module of the impact air sterilizer to the first hybrid LED chip portion, A first diffusion cover 314 for spreading the light,
A plurality of exhaust holes are formed on one side of the rear end side of the first diffusion cover, and a first discharge, which discharges the indoor air that has been secondarily sterilized through the UV LED chip of the first hybrid LED chip portion through the exhaust hole, (315). ≪ RTI ID = 0.0 > 31. < / RTI >
5. The LED driving device according to claim 4, wherein the first hybrid LED driving driver (312)
A first fuse portion 312a-1 for protecting the circuit by blocking an overcurrent flowing along one side of the LED lamp socket,
A first NTC thermistor part 312a-2 for allowing the voltage to flow into the circuit while gradually reducing the resistance when the resistance of the initial voltage passing through the first fuse part is large and the voltage can not flow into the circuit,
A first fuse unit, a first surge observer unit 312a-3 for filtering electrical noise generated in the current flowing into the first NTC thermistor unit,
A first EMI line filter unit 312a-4 for removing noise from a commercial AC power source that has passed through the first surge observer,
And a first RGB LED driving driver 312a composed of a first bridge rectifier 312a-5 for rectifying the voltage output from the first EMI line filter unit to DC voltage and supplying the voltage to the RGB LED chip Smart LED light fixture with air sterilization feature.
The method of claim 5, wherein the first UV LED driver driver (312a)
A wavelength of 200 nm to 300 nm is set as a first channel, a wavelength of 301 nm to 400 nm is set as a second channel, a wavelength of 401 nm to 500 nm is set as a third channel, and a wavelength of 501 nm to 600 nm is set as a fourth channel And then selects one of the four channels to be driven, and controls both the linear constant current source and the switchable constant voltage source. And a first UV LED driver IC unit integrated and integrated with the chip for selective control.
5. The module according to claim 4, wherein the first module body (311)
Pure Al-based Al 1050 having a composition of 0.05 wt% of Cu, 0.25 wt% of Si, 0.05 wt% of Mg, 0.05 wt% of Zn, 0.05 wt% of Mn, 0.40 wt% of Fe, 0.03 wt% of Ti and 98.72 wt% After dissolving in an electric furnace at 700 to 750 ° C., 5.0 to 17 wt% of Si and 0.1 to 5.0 wt% of Cu are added thereto, and mechanical stirring is performed for 10 to 15 minutes so that the additional elements are uniformly distributed in the molten metal. The Al-Si-Cu alloy is made of an Al-Si-Cu alloy prepared by injecting a molten metal into the casting mold,
The coating treatment is a heat treatment of graphite oxide prepared by mixing _{3 to} 10 wt% of graphite, 75 to 85 wt% of a solution obtained by mixing sulfuric acid and nitric acid at 7: 3 vol%, and 10 to 30 wt% of oxidizing agent KClO ₃ at 1,000 ° C. And the coated graphene is coated with a coating solution prepared by blending the synthesized graphene with water containing sodium dodecyl as a spraying agent in a weight ratio of 1: 1.

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