KR20090044329A - Dynamic complex lighting fixture - Google Patents

Abstract

The dynamic composite lighting apparatus according to the present invention is composed of a point lighting unit in which a plurality of background light emitters are sequentially disposed on top of a background light unit and a background light unit, and the point light unit repeats blinking of a plurality of point light emitters sequentially with a stingray-shaped transmission cover. do. By sequentially irradiating blue light from a number of background emitters and irradiating light of various colors with a stingray-shaped transmissive cover from a number of point emitters, the dynamic compound illuminator provides the effect of stingrays moving on a wavy sea. can do.

Fixture, Backlight, Point Illuminator

Description

DYNAMIC COMPLEX LIGHTING FIXTURE}

The present invention relates to a composite lighting device, and more particularly, to a lighting device that can provide a dynamic aesthetic by repeatedly flashing a plurality of light emitters.

In recent years, as society develops, the quality of people's lives is rapidly improving. This improvement in quality of life has turned people's attention to improving the living environment in offices and homes. Accordingly, in recent years, interest in various factors that determine the residential environment is increasing. In particular, the lighting device of the various elements can provide various effects depending on the amount and color of the light, as well as providing light to brighten the darkness.

However, conventionally used lighting device only serves to provide a light indoors or at night. For example, incandescent lamps, fluorescent lamps, and three-wavelength lamps used indoors not only irradiate white light, but also have a simple appearance, and thus have no great effect on the interior.

Accordingly, people want lighting devices that can provide light to the room as well as provide interior effects.

On the other hand, companies that use lighting devices as an advertisement medium for promoting a product or a shop are also demanding lighting devices that attract the attention of consumers as the competition for competition among companies that use advertising lighting devices is fierce.

Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, and provides a dynamic composite lighting apparatus that can provide dynamic aesthetics and decorative effects by repeatedly flashing a plurality of light emitters sequentially. .

Dynamic composite lighting apparatus according to the present invention for achieving this object, the plurality of background light emitters, the plurality of background light emitters to sequentially represent the background movement by blinking, the plurality of background light emitters A background lighting unit including a first transmission cover for transmitting light; It is disposed in front of the first transmission cover, and includes a plurality of point emitters and a point cover through which the light irradiated from the plurality of point emitters in a specific shape, the plurality of point emitters are sequentially flashing light And a point lighting unit for transmitting the light passing through the point cover to express the specific shape as it is irradiated.

In this case, the background lighting unit may include a first frame having one side opened and a receiving space formed therein; A power supply unit applying power to the plurality of background light emitters; A control unit including a driving integrated circuit and controlling the blinking of the plurality of background light emitters by using the driving integrated circuit; And a coupling member coupling the first frame and the first transmission cover, wherein the plurality of background emitters are accommodated in the first frame at predetermined intervals, and the first transmission cover is an opening of the first frame. It is disposed on and coupled to the first frame.

In addition, the plurality of background emitters are characterized in that irradiated with blue (BLUE) light.

In addition, the background motion is characterized by representing the movement of the wave.

In addition, the plurality of background emitters may be any one of a fluorescent lamp, a light emitting diode, and an optical fiber lamp.

In this case, when the plurality of background emitters are light emitting diodes, the background lighting unit may include at least one light emitting substrate on which at least one light emitting diode is aligned.

In addition, when the plurality of background emitters are optical fiber lamps, the background lighting unit may include at least one light emitting substrate on which at least one optical fiber lamp is aligned.

The controller may further include a wireless communication module, and may receive a control signal of the background light emitter from an external device using the wireless communication module, and control the blinking of the background light emitter according to the received control signal.

At this time, the wireless communication module may be any one of a radio frequency identification (RFID) communication module, an ultra wide band (UWB) communication module, an infrared data (IrDA) communication module, a Bluetooth communication module, and a Zigbee communication module. Can be.

The point lighting unit may include a second frame having one side opened to form an accommodation space, and fixed to one side of the first transmission cover to block light of the plurality of background emitters; A power supply unit supplying power to the plurality of point emitters; A control unit including a driving integrated circuit and controlling blinking of the plurality of point emitters by using the driving integrated circuit; And a second transmissive cover coupled to the second frame and transmitting light emitted from the plurality of point emitters, wherein the plurality of point emitters are accommodated in a second frame, and the point transmissive cover is the second frame. Combined with the transmission cover is characterized in that for transmitting the light of the plurality of point emitters.

In this case, the point penetrating cover has a stingray shape, and the movement of the specific shape may express the stingray movement.

In addition, the plurality of point emitters may be disposed to be spaced apart from the direction in which the plurality of background emitters are stored, and may be disposed to face each other in two groups.

In addition, the plurality of point emitters may include light emitters that emit light of at least two colors.

In addition, the plurality of point emitters may be any one of a fluorescent lamp, a light emitting diode, and an optical fiber lamp.

In addition, when the plurality of point emitters are light emitting diodes, the point lighting unit may include at least one light emitting substrate on which at least one light emitting diode is aligned.

In addition, when the plurality of point emitters are optical fiber lamps, the point lighting unit may include at least one light emitting substrate on which at least one optical fiber lamp is aligned.

The controller may further include a wireless communication module, and may receive a control signal of the point emitter from an external device using the wireless communication module and control the blinking of the point emitter according to the received control signal.

At this time, the wireless communication module may be any one of a radio frequency identification (RFID) communication module, an ultra wide band (UWB) communication module, an infrared data (IrDA) communication module, a Bluetooth communication module, and a Zigbee communication module. Can be.

As described above, the dynamic composite lighting apparatus proposed by the present invention can provide dynamic aesthetics and decorative effects by repeatedly blinking a plurality of light emitters.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention. In describing the embodiments, descriptions of technical contents that are well known in the art to which the present invention pertains and are not directly related to the present invention will be omitted. This is to more clearly communicate without obscure the core of the present invention by omitting unnecessary description.

1 is a perspective view of a dynamic composite lighting apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the dynamic composite lighting device includes a background lighting unit 100 and a point lighting unit 300.

The background lighting unit 100 may include a plurality of background emitters that emit blue light, and the plurality of background emitters may be accommodated in diagonal lines. The background lighting unit 100 repeats the flashing sequentially from the light emitting body disposed on one side to the light emitting body located on the opposite side. Accordingly, the background lighting unit 100 may provide an effect that waves are generated in the sea by sequentially flashing the light emitting bodies irradiating blue light. Meanwhile, the background lighting unit 100 according to the present invention is described as a hexahedron as shown in FIG. 1, but the present invention is not limited thereto. That is, the background lighting unit 100 according to the present invention may be formed in various shapes such as a cylindrical or triangular cylindrical shape as shown in Figs. 2a and 2b.

At least one point lighting unit 300 is disposed on the top of the background lighting unit 100. The point lighting unit 300 includes a frame and a plurality of point emitters that block light emitted from the background lighting unit 100. Here, the plurality of point emitters may be divided into two groups, and each group may be disposed to face each other. The plurality of point emitters may be irradiated with light of a different color each time the flashing is sequentially performed using red, green, and blue light emitting diodes (Red, Green, Blue Light Emitting Diodes, RGB LEDs). In addition, the point lighting unit 300 includes a point transmitting cover in the form of a stingray. Accordingly, by repeatedly irradiating light on a plurality of point emitters and illuminating the stingray-shaped transmission cover, the dynamic composite lighting device may provide the effect of stingrays moving on a wavy sea. On the other hand, the point transmission cover according to the present invention has been described in the form of stingray, but the present invention is not limited thereto. That is, the point transmissive cover may be applied to any shape of the transmissive cover showing a particular shape.

Hereinafter, each configuration of the dynamic composite lighting apparatus according to the embodiment of the present invention will be described in detail with reference to FIGS. 1, 3, and 4. In the present embodiment, one point lighting unit 300 is disposed on the top of the background light list 100 as an example.

3 is an exploded perspective view of the dynamic composite lighting apparatus shown in FIG. 1, and FIG. 4 is a cross-sectional view of the dynamic composite lighting apparatus illustrated in FIG. 1.

Dynamic composite lighting apparatus according to an embodiment of the present invention is composed of a background lighting unit 100 and the point lighting unit 300.

The background lighting unit 100 is housed in the first frame 110, the first frame 110 having one side opened, and supplies power to the background light emitters 120a to 120h and the background light emitters 120a to 120h that irradiate light. The first power control unit 130, the first driving control unit 140 controlling the driving of the background light emitters 120a to 120h, and the opening of the first frame 110, and transmit the light of the background light emitting units 120a to 120h. The first transmission cover 150, the first frame 110 may include a coupling member (160a) for coupling to the ceiling or wall of the building.

In detail, the first frame 110 has a rectangular cylindrical shape having one side opened, and houses the background light emitters 120a to 120h, the first power supply unit 130, and the first driving control unit 140, and the external frame is impacted by an external impact. Protect from In addition, the first frame 110 has a hole 165a through which the coupling member 160a is inserted is formed at the rear of the opening. Accordingly, the first frame 110 may be fixed to the ceiling or the wall by using the coupling member 160a inserted into the hole 165a. In addition, a socket 170a may be formed in the first frame 110 to fix the background emitters 120a to 120h and to transfer the power supplied from the first power source 130 to the background emitters 120a to 120h. In addition, the first frame 110 forms the fixing member 175 on the rear surface of the opening to fix the coupling members 160a and 160b inserted in the first transmission cover 150 or the point lighting unit 300, thereby transmitting the first transmission. The cover 150 and the point lighting unit 300 may be firmly coupled to the background lighting unit 100.

The background light emitters 120a to 120h are received at predetermined intervals inside the first frame 110. For example, when the background emitters 120a to 120h are formed of fluorescent lamps, the fluorescent lamps may be mounted and accommodated in the sockets 170a of the first frame 110 at predetermined intervals. In addition, when the background light emitters 120a to 120h are configured of LEDs, as shown in FIG. 5, one light emitting substrate on which a plurality of LEDs are mounted may correspond to one background light emitter 120a. In addition, the light emitting substrate may be stored at a predetermined interval in the first frame 110 as in the case of the fluorescent lamp described above. In addition, the background light emitters 120a to 120h may be configured of optical fiber lamps.

In particular, the background emitters 120a to 120h sequentially repeat the processes of sequentially flashing from the first background emitter 120a to the eighth background emitter 120h under the control of the first driving controller 140. In addition, the background light emitters 120c and 120d positioned in the middle may be sequentially turned on from the background light emitters 120a and 120h disposed at both sides.

The first power supply unit 130 supplies power transmitted from the outside to the background light emitters 120a to 120h.

The first driving controller 140 controls each component of the background lighting unit 100 and includes an integrated circuit (IC) for controlling the blinking of the background light emitters 120a to 120h. For example, when a wireless communication module is provided in the first driving controller 140, the first driving controller 140 may control the background light emitters 120a to 120h by receiving a control signal from an external device (remote controller). . The external device includes a program for controlling the blink order, the blink time, and the like of the background light emitters 120a to 120h. That is, the first driving controller 140 controls the flashing order, the flashing time, and the like of the background light emitters 120a to 120h according to the control signal received from the external device. In this case, when the wireless communication module is provided in the first driving controller 140, radio such as RFID (Radio Frequency Identification), UWB (Ultra Wide Band), IrDA (Infrared Data), Bluetooth (Bluetooth), Zigbee, etc. The control signal can be received from an external device using a communication method.

The first transmission cover 150 is in the form of a plate that transmits the light of the background light emitters 120a to 120h and is disposed to face the opening of the first frame 110 so as to be coupled to the first frame 110. A plurality of holes 165b are formed in the first transmission cover 150. The coupling member 160a is inserted into the hole 165b to be fixed to the first frame 110, so that the first transmission cover 150 may be fixed to the first frame 110. In addition, an insertion hole 168 is formed on a surface of the first transmission cover 150. The second frame 310 of the point lighting unit 300 is inserted into the insertion hole 168. Here, the area of the insertion hole 168 is preferably formed to correspond to the size of the second frame (310).

Meanwhile, in the present invention, the first transmission cover 150 is described as an example of being coupled to the first frame 110 using the coupling member 160a, but the present invention is not limited thereto. That is, when the fastening portion is formed in the first transmission cover 150 and the first frame 110, the first transmission cover 150 and the first frame 110 may be coupled using the fastening portion.

The first transmission cover 150 may be formed of synthetic resin, glass, or the like. For example, when the first transmissive cover 150 is formed of acrylic in a synthetic resin, since the acryl has excellent light transmittance, the first transmissive cover 150 may transmit light emitted from the background light emitters 120a to 120h well. have. In addition, when the sanding (Sanding) processing on the surface of the first transmission cover 150, the first transmission cover 150 is because the light emitted from the background emitters (120a to 120h) refracted at various angles to transmit people It can prevent glare and provide the effect of indirect lighting.

The coupling member 160a is used as a member for fixing the first frame 110 to a wall or ceiling or for coupling the first frame 110 and the first transmission cover 150 to each other. Such a coupling member 160a may be used with bolts, screws, and the like. If bolts are used, nuts to secure the bolts are used as fastening members.

The point lighting unit 300 includes a second frame 310, point emitters 320a to 320d, a second power supply unit 330, a second driving control unit 340, a second transmission cover 350, and a point transmission cover 350. And coupling members 160b and 160c.

The second frame 310 has a rectangular cylindrical shape with one side opened and is inserted into an insertion hole 168 formed in the first transmission cover 150. In this case, a stepped portion is formed at the edge of the opening of the second frame 310 to prevent the second frame 310 from penetrating the insertion hole 168. The second frame 310 accommodates the point emitters 320a to 320d, the second power supply unit 330, and the second drive control unit 340, and protects them from external impact. In this case, the second frame 310 is preferably formed of a material for blocking the light emitted from the background light emitter (120a to 120h). For example, the second frame 310 may be formed of a metal material or an opaque synthetic resin having a predetermined thickness.

The second frame 310 has a hole 165c formed at a rear surface of the opening such that the coupling member 160b for fixing the second frame 310 is inserted into the background lighting unit 100. In addition, a socket 170b is formed in the second frame 310 to fix the point emitters 320a to 320d and to transfer the power supplied from the second power source 330 to the point emitters 320a to 320d.

The point emitters 320a to 320d are accommodated in the second frame 310 so as to be perpendicular to the direction in which the background emitters 120a to 120h are stored at regular intervals. For example, the plurality of point emitters 320a to 320d may be divided into two groups, and each group may be disposed to face each other. The point emitters 320a to 320d belonging to each group are repeatedly blinked sequentially. For example, when the RGB LEDs are used as the point emitters 320a to 320d, light of different colors may be irradiated each time the flashing is sequentially performed. In addition, the point emitters 320a to 320d may be formed of fluorescent lamps, optical fiber lamps, and the like, and a detailed description thereof will be omitted since it is similar to the background emitters 120a to 120h described above.

The second power supply unit 330 supplies the power transmitted from the outside to the point emitters 320a to 320d.

The second driving controller 340 controls the respective components of the point lighting unit 300 and includes a driving IC for controlling the blinking of the point emitters 320a to 320d. For example, when the wireless driving module is provided in the second driving controller 340, the second driving controller 340 may control the point emitters 320a to 320d by receiving a control signal from an external device (remote controller). . The external device includes a program for controlling the blink order, the blink time, and the like of the point emitters 320a to 320d. That is, the second driving controller 340 controls the flashing order, the flashing time, and the like of the point emitters 320a to 320d according to a control signal received from an external device. In this case, when the wireless communication module is provided in the second driving controller 340, radio such as RFID (Radio Frequency Identification), UWB (Ultra Wide Band), IrDA (Infrared Data), Bluetooth (Bluetooth), Zigbee (Zigbee), etc. The control signal can be received from an external device using a communication method.

The second transmissive cover 350 is a plate shape that transmits light emitted from the point emitters 320a to 320d and is disposed to face the opening of the second frame 310 so as to be coupled to the second frame 310. A plurality of holes 165d into which the coupling member 160b for coupling the second frame 310 and the second transmission cover 350 is inserted are formed in the second transmission cover 350. The second transmission cover 350 may be formed of synthetic resin, glass, or the like.

The point transmissive cover 360 has a shape that can provide an aesthetic and is disposed on an upper portion of the second transmissive cover 350. In addition, the point transmissive cover 360 may be formed with a hole 165e such that the coupling member 160c may be coupled to the second frame 310 or the second transmissive cover 350. The point penetrating cover 360 has a protrusion having a tail shape at one vertex on a plate having a rhombus shape having a bend formed at its center as shown in FIGS. 1, 3, and 4. Accordingly, the point transmissive cover 360 transmits the light of the point emitters 320a to 320d, which are repeatedly blinking, so that the point transmitting cover 360 may feel like a stingray moving to people. In addition, the point penetrating cover 360 may be sanded the surface to provide an anti-glare and indirect lighting effect.

The coupling members 160b and 160c may combine the second frame 310, the second transmission cover 350, and the point transmission cover 360 to prevent separation and separation between these components. In addition, when the second frame 310 is fixed to the first transmissive cover 150, the coupling member 160b is inserted into the hole 165c formed in the second frame and thus the hole 165b of the first transmissive cover 150. Is inserted). In this case, when the fixing member 175 is formed in the first frame 110, the coupling member 160b may be fixed to the fixing member 175 by passing through the hole 165a of the first transmission cover 150. By using the fixing member 175, the coupling between the point lighting unit 300 and the background lighting unit 100 can be secured.

As described above, the dynamic composite lighting apparatus according to the present invention may sequentially flash a plurality of light emitters and irradiate light to a transparent cover in which some light emitters have a specific formation, thereby providing a dynamic aesthetic and indoor interior effects.

As described above, in the detailed description of the present invention has been described with respect to specific embodiments, various modifications are of course possible without departing from the scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

1 is a perspective view of a dynamic composite lighting apparatus according to an embodiment of the present invention.

2A and 2B are exemplary views illustrating various forms of a background lighting unit according to an embodiment of the present invention.

3 is an exploded perspective view of the dynamic composite lighting apparatus shown in FIG.

4 is a cross-sectional view of the dynamic composite lighting apparatus shown in FIG.

5 is an exemplary view showing various forms of a background light emitter according to an embodiment of the present invention.

Claims (19)

In the composite lighting device, A background lighting unit including a plurality of background emitters, the plurality of background emitters sequentially blinking to express a background movement, and including a first transmission cover which transmits light emitted from the plurality of background emitters; It is disposed in front of the first transmission cover, and includes a plurality of point emitters and a point cover through which the light irradiated from the plurality of point emitters in a specific shape, the plurality of point emitters are sequentially flashing light And a point lighting unit for transmitting light passing through the point cover to express the specific shape of the movement as it is irradiated. The method of claim 1, The background lighting unit, A first frame having one side opened and a receiving space formed therein; A power supply unit applying power to the plurality of background light emitters; A control unit including a driving integrated circuit and controlling the blinking of the plurality of background light emitters by using the driving integrated circuit; Further comprising: a coupling member for coupling the first frame and the first transmission cover, The plurality of background light emitting body is received at a predetermined interval in the first frame, the first transparent cover is a dynamic composite lighting device, characterized in that coupled to the first frame is disposed in the opening of the first frame. The method of claim 2, The plurality of background light emitter is a dynamic composite lighting device, characterized in that to irradiate blue (BLUE) light. The method of claim 3, The background motion is dynamic composite lighting device characterized in that to represent the movement of the wave. The method of claim 2, The plurality of background light emitter is a dynamic composite lighting device, characterized in that any one of a fluorescent lamp, a light emitting diode, an optical fiber lamp. The method of claim 5, The plurality of background emitters are light emitting diodes, The backlight unit includes at least one light emitting substrate on which at least one light emitting diode is arranged. The method of claim 5, The plurality of background emitters are optical fiber lamps, The backlight unit includes at least one light emitting substrate on which at least one optical fiber lamp is arranged. The method of claim 2, The control unit further comprises a wireless communication module, And receiving a control signal of the background light emitter from an external device using the wireless communication module, and controlling the blinking of the background light emitter according to the received control signal. The method of claim 8, The wireless communication module is any one of a radio frequency identification (RFID) communication module, an ultra wide band (UWB) communication module, an infrared data (IrDA) communication module, a Bluetooth communication module, and a Zigbee communication module. Dynamic composite lighting system. The method of claim 1, The point lighting unit, A second frame having one side opened to form an accommodation space and fixed to one side of the first transmissive cover to block light of the plurality of background emitters; A power supply unit supplying power to the plurality of point emitters; A control unit including a driving integrated circuit and controlling blinking of the plurality of point emitters by using the driving integrated circuit; And a second transmission cover coupled to the second frame and transmitting light emitted from the plurality of point emitters. And the plurality of point emitters are accommodated in a second frame, and the point transmissive cover is coupled to the second transmissive cover to transmit the light of the plurality of point emitters. The method of claim 10, The point penetrating cover has a stingray shape, The specific shape of the movement is a dynamic composite lighting device, characterized in that for representing the movement of the stingray. The method of claim 10, The plurality of point illuminators are disposed so as to be spaced apart from the direction in which the plurality of background illuminators are housed. The method of claim 10, The plurality of point emitters are divided into two groups, characterized in that the dynamic composite lighting device arranged to face. The method of claim 10, The plurality of point emitters are dynamic composite lighting device, characterized in that consisting of a light emitting for irradiating at least two colors of light. The method of claim 10, The plurality of point light emitter is a dynamic composite lighting device, characterized in that any one of a fluorescent lamp, a light emitting diode, an optical fiber lamp. The method of claim 15, The plurality of point emitters are light emitting diodes, The point lighting unit includes at least one light emitting substrate in which at least one light emitting diode is aligned. The method of claim 15, The plurality of point emitters are optical fiber lamps, The point lighting unit includes at least one light emitting substrate in which at least one optical fiber lamp is aligned. The method of claim 10, The control unit further comprises a wireless communication module, And receiving a control signal of the point emitter from an external device using the wireless communication module, and controlling the blinking of the point emitter according to the received control signal. The method of claim 18, The wireless communication module is any one of a radio frequency identification (RFID) communication module, an ultra wide band (UWB) communication module, an infrared data (IrDA) communication module, a Bluetooth communication module, and a Zigbee communication module. Dynamic composite lighting system.

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