KR20140023504A - Optical semiconductor based illuminating apparatus - Google Patents

Abstract

The present invention relates to an optical semiconductor based lighting device comprising at least one clamping unit formed along the length direction of a race way; a housing which includes a power supply device arranged in the upper side and a light emitting module having a plurality of semiconductor light elements formed in a row in the lower side and is detached to the clamping unit; a first ceiling unit for finishing both ends of the housing; a second ceiling unit which is arranged between both edges of an optical member arranged in the bottom surface of the housing and the housing and covers the upper part and the lower part of both edges of the optical member; a wireless communication part for receiving a dimming signal through a wireless communication network to output the received dimming signal to the power supply device; the power supply device for receiving alternating current power, converting the alternating current power to direct current power to be supplied to the light emitting module and controlling illumination of the light emitting module according to the dimming signal inputted by the wireless communication part; and the light emitting module which is connected to the power supply device and is driven according to the control of the power supply device. [Reference numerals] (1000) Lighting device; (610) Rectifying part; (620) Dimming control part; (630) Constant current control part; (640) Wireless communication part; (650) Wireless controller; (660) Wireless sensor; (700) Light emitting module

Description

[0001] OPTICAL SEMICONDUCTOR BASED ILLUMINATING APPARATUS [0002]

The present invention relates to an optical semiconductor-based lighting device, and more particularly, to an optical semiconductor-based lighting device that can be improved in installation convenience and stability by using a wired standard power supply and a wireless communication module with a dimming control function. It is about.

Recently, various efforts for energy saving have been made worldwide. As part of efforts to save energy, various technologies have been developed to reduce power consumption of lighting devices installed in buildings, street lights, houses, and the like. In order to reduce the power consumption of the lighting device, various dimming control techniques have been developed for selectively turning on / off the lighting device as needed or adjusting the illuminance of the lighting device according to the surrounding brightness. For dimming control, the dimming signal is input to the lighting device as an analog output, and the lighting device receives it and adjusts the brightness. In the prior art, a dimming controller and a lighting device for outputting a dimming signal according to a user's operation are connected through a wired cable. Accordingly, as the length of the wired cable becomes longer, contact resistance increases and noise may be generated. As a result, the dimming signal may be affected by noise, and thus the dimming control desired by the user may not be achieved. In addition, as the wired cable is used, there is an inconvenience in installing the lighting device and the dimming controller, and there is a problem in that the installation position is limited.

In order to solve this problem, a wireless dimming control technology has been developed and used to replace the conventional wired communication method. 1 is a block diagram showing a schematic configuration of a radio control lighting apparatus according to the prior art. As shown in FIG. 1, the wireless control lighting apparatus 10 according to the related art may include a power supply device 20, a wireless communication unit 30, and a light emitting module 60.

The power supply device 20 converts the AC power applied by being connected to _AC power (V _AC ) into a DC power suitable for driving the light emitting module 60 and outputs the DC power to the wireless communication unit 30 and outputs the wireless communication unit 30. The wireless communication module 40 receives and outputs a dimming signal transmitted from the wireless controller 70, and the dimming control unit 50 of the wireless communication unit 30 processes DC power applied based on the received dimming signal to emit light. Configured to perform dimming control by supplying to module 60. However, in the case of the wireless control lighting apparatus 10 according to the related art of the prior art, although it is possible to solve the problem of the wired communication method as described above, since it is configured to perform dimming control in the wireless communication unit 30, When a failure occurs in the communication unit 30 itself, or when the wireless communication between the wireless communication unit 30 and the wireless controller 70 is not smooth, the power supply to the light emitting module 60 itself is cut off so that the lighting device 10 There is a problem that does not work.

An object of the present invention is to solve the above-mentioned problems of the prior art.

One object of the present invention, by using a wired standard power supply and a wireless communication module with a built-in dimming control function, optical semiconductor-based lighting using a wired standard power supply capable of dimming control can be improved installation convenience and stability It is to provide a device.

In addition, another object of the present invention is to provide an optical semiconductor-based lighting apparatus that can stably provide illumination regardless of whether the wireless communication unit is operating.

In order to achieve the above-described object of the present invention and to achieve the specific effects of the present invention described below, the characteristic structure of the present invention is as follows.

According to an aspect of the present invention, an optical semiconductor-based lighting device, comprising: a clamping unit formed at least one along the longitudinal direction of a raceway; A housing having a power supply device disposed above and a light emitting module having a plurality of semiconductor optical elements arranged in a row below, the housing being detachable from the clamping unit; First sealing units closing both ends of the housing; A second sealing unit disposed between both edges of the optical member disposed on the bottom of the housing and the housing, and surrounding upper and lower edges of both edges of the optical member; A wireless communication unit receiving a dimming signal through a wireless communication network and outputting the received dimming signal to a power supply device; A power supply device which receives AC power and converts the power into DC power and supplies the light to the light emitting module, and controls the illuminance of the light emitting module according to a dimming signal input from the wireless communication unit; And a light emitting module connected to the power supply device and driven under the control of the power supply device.

The above-described power supply apparatus includes: a rectifying unit configured to generate a DC power by full-wave rectifying and stabilizing the AC power; A constant current control unit controlling the current flowing through the light emitting module to be constantly maintained at a predetermined constant current value; And a dimming control unit for controlling the illuminance of the light emitting module according to the dimming signal output from the wireless communication unit.

In addition, the above-described power supply device may be configured to control the driving of the light emitting module according to a preset reference value when the dimming signal from the wireless communication unit is not input.

In addition, the above-described dimming control unit may be configured to control the illumination of the light emitting module according to the analog illumination control method.

In addition, the above-described dimming control unit may be configured to control the illuminance of the light emitting module according to a pulse width modulation (PWM) illuminance control scheme.

On the other hand, the above-described wireless communication unit further receives the illumination information through the wireless communication network and outputs to the power supply device, the power supply device based on at least one of the dimming signal, the illumination information, the illumination intensity of the light emitting module It can be configured to control.

On the other hand, the above-described wireless communication unit may be provided outside the optical semiconductor-based lighting device.

According to the present invention, by using the wired standard power supply device and the wireless communication module with the built-in illuminance control function, the effect of improving the installation and control convenience and stability of the optical semiconductor-based lighting device can be expected.

In addition, according to the present invention can be expected to provide a stable lighting regardless of the operation of the wireless communication unit for receiving a dimming signal through a wireless communication network.

1 is a block diagram of a radio control lighting apparatus according to the prior art.
2 is a block diagram of an optical semiconductor-based lighting device having a wireless control function according to an embodiment of the present invention.
Figure 3 is an exploded perspective view showing the overall configuration of an optical semiconductor-based lighting device including a power supply according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION The following detailed description of the invention refers to the accompanying drawings that show, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with an embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. Accordingly, the following detailed description is not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims, along with the full range of equivalents to which such claims are entitled. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

[Preferred Embodiment of the Present Invention]

2 is a block diagram illustrating an optical semiconductor-based lighting apparatus having a wireless control function according to an exemplary embodiment of the present invention. Hereinafter, with reference to the accompanying drawings, it will be described in detail the configuration and function of the optical semiconductor-based lighting apparatus according to an embodiment of the present invention.

As shown in FIG. 2, the optical semiconductor-based lighting apparatus having a wireless control function according to the present invention may include a power supply device 600, a wireless communication unit 640, and a light emitting module 700.

First, the wireless communication unit 640 according to the present invention is configured to perform wireless data communication with the wireless controller 650 and / or the wireless sensor 660 through a wireless communication network. The wireless communication unit 640 may be configured to perform wireless data communication using one of various known short-range wireless communication methods such as infrared communication, Bluetooth communication, Zigbee communication, and wireless LAN communication. The wireless communication unit 640 receives the dimming signal transmitted from the wireless controller 650 and / or the illumination information of the illumination target area transmitted from the wireless sensor 660 according to a user's operation, and receives the received dimming signal and / or illuminance. The information is output to the power supply device 600. Meanwhile, FIG. 2 illustrates an embodiment in which the wireless communication unit 600 according to the present invention is provided inside the optical semiconductor-based lighting apparatus 1000, but is not limited thereto. It may be provided in. When the wireless communication unit 600 is provided outside the optical semiconductor-based lighting device 1000, the wireless communication unit 600 and the optical semiconductor-based lighting device 1000 are connected through a wired cable, but moisture or foreign matter does not penetrate. It is desirable to be configured to allow for confidentiality.

The light emitting module 700 includes a plurality of semiconductor optical elements 701 such as a light emitting cell, an LED element, an LED package, an LED chip, and an LED array, and receives DC power from the power supply device 600 to emit light. It will be apparent to those skilled in the art that the type, number, and arrangement of the semiconductor optical devices 701 constituting the light emitting module 700 may be variously changed as necessary. Hereinafter, the LED device will be described for convenience of description and understanding. It will be described with reference to the light emitting module 700 configured using.

On the other hand, the power supply 600 according to the present invention is largely configured to perform two functions. First, the power supply device 600 is connected to an external AC power supply source (for example, a commercial AC power supply of 220V, etc.) to receive AC power VAC, and applies the applied AC power to the light emitting module 700. It converts into a DC power source suitable for driving to supply the light emitting module 700. In addition, the power supply 600 according to the present invention receives the dimming signal and / or illuminance information output from the wireless communication unit 640, based on the input dimming signal and / or illuminance information of the light emitting module 700 It is configured to perform a dimming control function for controlling the illuminance.

In order to perform the above functions, the power supply device 600 according to the present invention may include a rectifier 610, a constant current controller 630, a dimming controller 620.

The rectifier 610 performs a function of full-wave rectifying the applied AC power to convert it into DC power. The rectifier 610 may be a bridge diode type rectifier circuit configured using a bridge diode which is generally used, but is not limited thereto. Various full wave rectifier circuits may be applied to the rectifier 610 of the present invention. have. In addition, the front end of the rectifier 610 may further include a noise filter (not shown) for removing the noise contained in the AC power source and a fuse circuit for preventing the introduction of overcurrent, the rear end of the rectifier 610 Stabilization circuit (not shown), such as a smoothing capacitor for the removal of the power factor correction circuit (not shown) for compensating the power factor may be further included. Since the structure and function itself of the rectifier 610 adopts a known technique, a detailed description thereof will be omitted.

The constant current controller 630 is configured to sense a current value flowing in the light emitting module 700 and to perform a function of controlling the current flowing in the light emitting module 700 to be maintained at a set constant current value.

The dimming controller 620 is configured to control the illuminance of the light emitting module 700 according to the dimming signal and / or illuminance information input from the wireless communication unit 640. In general, dimming control for the light emitting module 700 including a plurality of LEDs may be performed by adopting one of two methods. The dimming control unit 620 according to the present invention may also be configured to perform dimming control according to one of the two methods described below.

1. Dimming control unit (analog type dimming control) according to the first embodiment

The dimming controller 620 according to the first embodiment of the present invention is configured to perform dimming control by controlling the magnitude of the forward current flowing through the light emitting module 700, that is, the current value in an analog manner. When the dimming signal is input from the wireless communication unit 640, the dimming controller 620 determines the level of the current value sensed by the constant current controller 630, and the dimming level of the dimming signal input by the constant current controller 630. As a result, the constant current controller 630 is controlled to increase or decrease the value of the current flowing through the light emitting module 700.

In a similar manner, when the illumination information is input from the wireless communication unit 640, the dimming controller 620 calculates a dimming level based on the current illuminance information according to the dimming control setting information and a preset algorithm, and applies the calculated dimming level to the calculated dimming level. As described above, the dimming control is performed by controlling the constant current controller 630 to increase or decrease the current value flowing through the light emitting module 700.

Meanwhile, according to the present invention, the dimming control may be performed by directly increasing or decreasing the magnitude of the DC voltage applied to the light emitting module 700 without directly controlling the current flowing through the light emitting module 700.

2. Dimming control unit (PWM (Pulse Width Modulation) type dimming control) according to the second embodiment

The dimming controller 620 according to the second embodiment of the present invention is configured to control the illuminance of the light emitting module 700 by using a pulse width modulation method. The dimming control of the PWM method refers to a dimming control method of controlling illuminance of the light emitting module 700 by turning on / off the DC power supplied to the light emitting module 700 according to the PWM signal. Accordingly, when the dimming signal and / or illuminance information is input from the wireless communication unit 640, the dimming control unit 620 according to the second embodiment of the present invention may perform the PWM signal based on the input dimming signal and / or the illuminance information. By adjusting the duty ratio, the dimming controller is performed.

In addition, unlike the conventional wireless control lighting apparatus according to the prior art as described with reference to FIG. It is configured to continue supplying the DC power to the 700. In order to perform this function, the power supply device 600 according to the present invention basically supplies a DC power to the light emitting module 700 according to a preset reference value, and dimming signal from the wireless communication unit 640 and / or Only when the illumination information is input, it is configured to perform dimming control. Further, once a dimming signal and / or illuminance information is input and dimming control is performed based thereon, before another dimming signal and / or illuminance information is newly input, the dimming level and / or illuminance information is applied to the dimming level based on the previous dimming signal and / or illuminance information. Accordingly, the light emitting module 700 may be configured to control driving of the light emitting module 700.

Of course, according to the configuration of the embodiment, the power supply device 600 according to the present invention monitors the state of the wireless communication unit 640, if it is determined that a failure occurs in the wireless communication unit 640, the preset reference value Accordingly, the light emitting module 700 may be configured to control the operation of the light emitting module 700. For example, when the preset reference value is set to 80% of the maximum dimming level, the power supply device 600 is determined to have a failure in the wireless communication unit 640, or is determined to have a failure in wireless communication. In this case, the dimming control is performed so that the dimming level of the light emitting module 700 is 80%. It will be apparent to those skilled in the art that these reference values can be set variously as needed. In addition, various known techniques may be used to determine whether a failure of the wireless communication unit 640 occurs.

On the other hand, the power supply 600 according to the present invention as described above may be implemented using a standard power supply for the wire with a dimming control function. That is, the biggest technical feature of the optical semiconductor-based lighting apparatus 1000 according to the present invention, using a standard wired power supply with a dimming control function and a wireless communication unit that can receive a dimming signal, simple and easy It is possible to configure the optical semiconductor-based lighting device with a wireless control function, and through this configuration, even if a failure occurs in the wireless communication unit 640, or even if a failure in the wireless communication is to continue to provide lighting. It is in making it possible.

Meanwhile, the wireless controller 650 and the wireless sensor 660 illustrated as the optical semiconductor based lighting apparatus 1000 in FIG. 2 perform wireless data communication with the wireless communication unit 640 of the optical semiconductor based lighting apparatus 1000. It is configured to. In the case of the wireless controller 650, the dimming signal input according to a user's or manager's operation is transmitted to the optical semiconductor-based lighting apparatus 1000. The wireless sensor 660 is installed in a predetermined area where dimming is performed by the optical semiconductor based lighting apparatus 1000 to sense the current illuminance of the dimming region and transmit the sensed illuminance information to the optical semiconductor based lighting apparatus 1000. It is composed.

3 is an exploded perspective view showing the overall configuration of an optical semiconductor-based lighting apparatus according to the present invention. Hereinafter, with reference to FIG. 3, the configuration and function of the optical semiconductor-based lighting apparatus according to the present invention will be described in detail.

As shown in the present invention, the housing 500 is detachably coupled to the raceway 400, and the first sealing unit 100 and the second sealing unit 200 are provided in the housing 500. It can be seen that it is a structure that enables confidentiality.

At least one clamping unit 300 is formed along the longitudinal direction of the raceway 400 to be fastened to the housing 500.

The housing 500 includes a light emitting module 700 having a power supply device 600 disposed at an upper side thereof and a plurality of semiconductor optical devices 701 arranged at a lower side thereof, and being detached from the clamping unit 300.

The first sealing unit 100 is to close both ends of the housing 500 to prevent the penetration of moisture and foreign matter.

The second sealing unit 200 is disposed between both edges of the optical member 800 that closes the bottom of the housing 500 and the housing 500, and surrounds both upper and lower edges of the optical member 800. Together with the first sealing unit 100 is to prevent the penetration of moisture and foreign matter into the housing 500.

It is to be understood that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention.

As described above, the clamping unit 300 is a means for allowing the housing 500 to be easily coupled to the raceway 400. The clamping unit 300 is coupled to the bottom of the raceway 400 to detach the upper both sides of the housing 500. It is preferable to include the clamp 310.

Specifically, the clamping unit 300 is coupled to the bottom surface of the raceway 400 and the upper and lower upper fasteners 320 are coupled through the clamp 310 and formed on the outer circumferential surface of the upper fasteners 320. The thread and the lower fixture 330 is to be coupled.

Here, an embodiment in which the spacer 340 for maintaining a gap may be further applied to the top or bottom surface of the clamp 310.

At this time, the clamp 310 is to be specifically coupled to the housing 500 by the second fixing piece 312 extends from both edges of the first fixing piece 311 is coupled to the bottom surface of the raceway 400 .

In addition, the clamp 310 extends from the end edge of the second fixing piece 312 and the clamping hook corresponding to the shape of the fixing groove 501 formed along the longitudinal direction of the housing 500 on both upper sides of the housing 500. 312 'is formed.

The clamping hook 312 ′ is preferably formed to be inclined upwardly toward the upper surface of the housing 500 so that the clamping hook 312 ′ can be firmly secured to the housing 500.

Meanwhile, as described above, the housing 500 provides a space in which the first and second sealing units 100 and 200 are mounted, and has a structure including the first body 510 and the second body 520. I can figure it out.

That is, the first body 510 is a member of both ends through which the upper surface is coupled to the clamping unit 300, the power supply device 600 is embedded, and the light emitting module 700 is provided on the bottom surface thereof, and the second body 520. Extends inclined from both side edges of the bottom of the first body 510 to be coupled to both edges of the optical member 800, and serves as a reflector.

For reference, in the drawing, the light emitting module 700 is shown to be arranged in a pair on a straight line parallel to the bottom surface of the power supply device 600, that is, a '-' shape, but is not limited thereto, and the first body Deformation and application to vary the range of light irradiation by forming the bottom of the first body 510 to be inclined 'V' in response to the structural features of the second body 520 extending inclined from both edges of the 510 Of course it is possible.

Here, the first sealing unit 100 closes the area formed by the housing 500 and the optical member 800, and the second sealing unit 200 has an end edge and the optical member 800 of the second body 520. ) Will be placed on the edge of.

At this time, the first sealing unit 100 together with the end cap 110 coupled to both ends of the housing 500, the first packing 120 is disposed between the end cap 110 and both ends of the housing 500. It is to include.

The end cap 110 closes the area formed by the first body 510, the second body 520, and the optical member 800.

The first packing 120 has at least one communication groove 122 accommodating the cable 900 connecting the PSU 600 and the light emitting module 700 to be in close contact with the optical member 800.

That is, the first packing 120 is disposed along the edge formed by the second body 520 and the optical member 800.

In addition, the first packing 120 extends from one side edge of the first packing 120 and is preferably provided with a finishing piece 123 at the end of the removable connecting piece 121.

The finishing piece 123 has an auxiliary groove 122 ′ having a shape corresponding to the communication groove 122, and removes the connecting piece 121 to separate the first piece from the first packing 120 to wrap the cable 900. Done.

In the drawings, the connecting piece 121 and the finishing piece 123 are connected to the first packing 120, but when the first sealing unit 100 is actually coupled to the housing 500, the connecting piece 121 is removed. The finishing piece 123 is in close contact with the first packing 120 to fasten the end cap 110 to the housing 500.

On the other hand, the second sealing unit 200 includes a second packing 210 surrounding the locking hook 810 extending inclined upwardly from the edge of the optical member 800.

The second packing 210 preferably includes at least one or more protrusion pieces 220 formed from an outer surface and closely attached to the housing 500 to be elastically deformed.

The protrusion piece 220 maintains airtightness between the optical member 800 and the second body 520 while facilitating fastening with the optical member 800, as well as shock or vibration caused by the housing 500 and the optical member 800. It also plays a role of preventing direct communication between the.

The housing 500 has a contact groove 522 recessed along the longitudinal direction of the housing 500 at the inner end of the second body 520 for coupling the optical member 800 and the second sealing unit 200, Preferably, the hook 810 and the second packing 210 are accommodated in the tight groove 522.

Here, the second main body 520 preferably further includes a locking step 522 'extending upwardly inclined from an edge of the lower end of the close contact groove 522 so that the second packing 210 is not separated.

At this time, the end of the engaging hook 810 is facing the engaging jaw 522 ', the second packing 210 is between the upper side of the engaging jaw 522' and the end of the engaging hook 810 and the contact groove 522 By being disposed in the second unit 200 wraps the upper side and the lower side of the edge of the optical member 810 as a whole it is possible to maintain a more secure airtight.

As described above, it can be seen that the present invention has a basic technical idea to provide an optical semiconductor-based lighting device that enables easy installation and construction, as well as reliable confidentiality.

For those skilled in the art within the scope of the basic technical idea of the present invention, the clamping unit 300 according to the above-described embodiment is omitted, and the housing 500 is directly bolted to the raceway 400. Although not directly fixed in the drawing, or in particular in the drawings, instead of the clamping unit 300 may implement a pendant type lighting device connecting the raceway 400 and the housing 500 by various means such as wire or chain. Of course, various modifications and applications are also possible.

1000: Optical semiconductor based lighting device 600: Power supply
610: rectifier 620: dimming controller
630: constant current control unit 640: wireless communication unit
700: light emitting module

Claims (6)

In the optical semiconductor-based lighting device,
At least one clamping unit formed along a length direction of a raceway;
A housing having a power supply device disposed above and a light emitting module having a plurality of semiconductor optical elements arranged in a row below, the housing being detachable from the clamping unit;
First sealing units closing both ends of the housing;
A second sealing unit disposed between both edges of the optical member disposed on the bottom of the housing and the housing, and surrounding upper and lower edges of both edges of the optical member;
A wireless communication unit receiving a dimming signal through a wireless communication network and outputting the received dimming signal to a power supply device;
A power supply device which receives AC power and converts the power into DC power and supplies the light to the light emitting module, and controls the illuminance of the light emitting module according to a dimming signal input from the wireless communication unit; And
And a light emitting module connected to the power supply and driven under the control of the power supply.
The method according to claim 1,
The power supply device includes:
A rectifier for full-wave rectifying and stabilizing the AC power to generate a DC power;
A constant current control unit controlling the current flowing through the light emitting module to be constantly maintained at a predetermined constant current value; And
And a dimming control unit for controlling the illuminance of the light emitting module according to the dimming signal output from the wireless communication unit.
The method according to claim 2,
The dimming control unit is an optical semiconductor-based lighting device, characterized in that for controlling the illuminance of the light emitting module according to the analog illuminance control method.
The method according to claim 2,
The dimming control unit is an optical semiconductor-based lighting device, characterized in that for controlling the illuminance of the light emitting module according to the PWM (Pulse Width Modulation) illumination control method.
The method according to claim 1,
The wireless communication unit further receives the illumination information through the wireless communication network and outputs to the power supply device,
And the power supply device controls the illuminance of the light emitting module based on at least one of the dimming signal and the illuminance information.
The method according to claim 1,
And the wireless communication unit is provided outside the optical semiconductor based lighting device.

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