KR101610187B1 - Lighting assembly for multi-direction illuminating - Google Patents

Abstract

The present invention provides a lighting assembly for multi-direction illumination, including: a hollow type housing; a lighting unit comprising a first light source which is arranged in the housing and outputs a first light, and a second light source outputting a second light; an internal reflection unit which is installed to surround the first light in the housing, and comprises a first reflector which is an inner surface formed to reflect the first light, and a second reflector which is an outer surface formed to reflect the second light in a different direction from the first light; an elevation unit to drive the housing by elevation; and an external reflection unit to reflect the second light toward the first light by adjusting an angle as to a wide wall of the housing during the elevation of the housing. The lighting assembly of the present invention can control a lighting area selectively.

Description

LIGHTING ASSEMBLY FOR MULTI-DIRECTION ILLUMINATING [0002]

The present invention relates to a multi-directional light-emitting assembly.

In general, in a lighting apparatus such as a fluorescent lamp and a lamp, a lamp is disposed inside a reflection plate, and the light irradiated from the lamp is reflected on the reflection plate and output to the outside. Therefore, the area where the light emitted from the lamp is output to the outside can be determined according to the shape and structure of the reflector. This reflector is fixedly mounted so that the outer area illuminated by the lamp is always confined to a specific area.

In this way, if the lighting area is limited, the lighting area does not cause a problem in a room where only a person lives, but a problem may arise in a space where a large number of people live together. For example, a person who does not want to light and a person who does not light can be located in the same space for the same reasons as sleeping during a community life. In this case, the conventional lighting apparatus performs illumination for the same area, so that selective illumination for a specific area or personnel is impossible. Therefore, a solution to this problem is required.

It is an object of the present invention to provide a multi-directional light emitting assembly capable of selectively controlling an illumination area.

According to an aspect of the present invention, there is provided a multi-directional light-emitting assembly including: a hollow housing; A light emitting unit disposed in the housing and including a first light source for outputting the first light and a second light source for outputting the second light; A first reflection surface provided to surround the first light in the housing and configured to reflect the first light and a second reflection surface formed to reflect the second light in a direction different from the first light, An inner reflection unit having two reflection surfaces; A lifting unit for lifting and lowering the housing; And an external reflection unit that is angularly adjusted with respect to a side wall of the housing when the housing is lifted or lowered, and reflects the second light toward the first light side.

Here, the light emitting unit may be installed on the ceiling of the housing, and the internal reflection unit may have the shape of a horn extending from the ceiling of the housing toward the bottom of the housing.

Here, the housing may be formed in a hexahedron, and the internal reflection unit may be formed in a quadrangular pyramid shape that connects the four corners of the bottom face of the hexahedron to the light emitting unit.

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Here, the housing may include a hollow frame surrounding the housing and allowing the housing to pass through the lifting and lowering unit.

Here, the external reflection unit may include: a reflection plate rotatably installed on a side wall of the housing, the reflection plate being located in the frame; And an elastic pressing body for elastically supporting the reflection plate with respect to the housing, and pressing the reflection plate toward the frame.

Here, the control unit may operate at least one of the lifting unit and the light emitting unit according to an operation command. And a receiving unit for receiving the operation command.

Here, the receiving unit may include an acoustic receiver, and the control unit may distinguish between the sound generated once within the set time and the sound generated a plurality of times, and each of the sounds may be recognized as another one of the operation commands.

According to the multi-directional light-emitting assembly according to the present invention configured as described above, the illumination region can be selectively controlled.

Further, the illumination region can be controlled by the lifting unit and the angle-controlled external reflecting unit in accordance with the rising and falling of the housing.

Further, the light emitting assembly has a receiving unit for communicating with an external terminal, and can be remotely controlled by an external terminal.

In addition, the light emitting assembly may include an acoustic receiver and may be operated according to acoustic information generated from the outside.

1 is a perspective view illustrating an outer structure of a multi-directional light emitting assembly 100 according to an embodiment of the present invention.
2 is a cross-sectional view taken along line II-II in FIG. 1 to explain the lifting structure of the multi-directional light emitting assembly 100 according to an embodiment of the present invention.
3 is a cross-sectional view illustrating the internal structure of the housing 110 of the multi-directional light-emitting assembly 100 according to an embodiment of the present invention.
4 to 6 are cross-sectional views illustrating a method in which a multi-directional light-emitting assembly 100 'according to another embodiment of the present invention is provided with an external reflection unit 190 and operated accordingly.
7 is a block diagram illustrating a receiving unit 220 of a multi-directional illuminable light emitting assembly 100 "and a control method therefor according to another embodiment of the present invention.

Hereinafter, a multi-directional light emitting assembly according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations.

1 is a perspective view illustrating an outer structure of a multi-directional light-emitting assembly 100 according to an exemplary embodiment of the present invention. FIG. 2 is a perspective view illustrating a multi-directional light-emitting assembly 100 according to an exemplary embodiment of the present invention. 3 is a cross-sectional view taken along the line II-II in FIG. 1 for explaining the lifting structure of the multi-directional light emitting assembly 100 according to the embodiment of the present invention. Fig.

1 to 3, the light emitting assembly 100 is installed in a penetrating region of a building ceiling board RB, and is lifted and lowered in a vertical direction E according to a user's operation, .

The light emitting assembly 100 may include a housing 110, a light emitting unit 130, an internal reflecting unit 150, a lifting unit 170, and a frame 180.

The housing 110 is formed of a hexahedron having a hollow structure having a ceiling 111, a bottom 113 and side walls 115. For example, the housing 110 may be formed in a box shape.

The ceiling 111 may be coated with a reflective material to reflect the light of the light emitting unit 130 described later.

The bottom 113 and the side wall 115 are made of a transparent material so that the light generated inside is transmitted through the bottom 113 and the side wall 115 to be output to the outside.

The light emitting unit 130 includes a first light source 131 and a second light source 136 installed in the housing 110, more specifically, the ceiling 111 of the housing 110, can do.

The first light source 131 is installed at the center of the ceiling 111 and irradiates the first light L1 in the direction of the bottom 113.

3, the second light sources 136 are installed on the ceiling 111 so as to be symmetrical with respect to the first light source 131, and irradiate the second light L2 in the direction of the bottom 113 do.

The internal reflection unit 150 is means for outputting the first light L1 and the second light L2 of the light emitting unit 130 in different directions. The internal reflection unit 150 may be formed in a tubular shape. Such a tubular shape may be a horn enlarged toward the bottom 113 from the ceiling 111 of the housing 110 so as to enclose the first light L1. The internal reflection unit 150 may be a square pyramid that connects the four corners of the bottom 113 of the housing 110 to the first light source 131 of the light emitting unit 130. In this case, as shown in FIG. 3, the inner reflection unit 150 may be formed as a quadrangular pyramid having an opening at its end, and the first light L1 of the first light source 131 may be reflected through the opening.

The inner reflection unit 150 includes a first reflection surface 151 which is an inner surface, and a second reflection surface 156 which is an outer surface. Therefore, as described above, the first light L1 is incident on the first reflecting surface 151 of the reflecting unit and is output toward the bottom 113 of the housing 110. [ The second light L2 is reflected by the second reflecting surface 156 formed to be inclined and is output in the direction of the side wall 115. The first light L1 and the second light L2 are output by the internal reflection unit 150 in the direction of the bottom 113 and the direction of the side wall 115 which are different from each other.

The elevating unit 170 may include a motor 171 and a wire 176 as shown in FIG. 2 as means for moving the housing 110 up and down. Accordingly, when the driving force is generated, the motor 171 can control the length of the wire 176 connected to the housing 110 to move the housing 110 up and down in the vertical direction. At this time, when the housing 110 is lifted or lowered, a clearance may be formed between the housing 110 and the ceiling board RB when the housing 110 is completely detached from the ceiling board RB. Although not shown in the figure, the housing 110 may further include a separation preventing unit for preventing separation of the housing 110 from the ceiling board RB when the housing 110 is lifted or lowered. The housing 110 is connected to the housing 110 and the motor 171 by a means such as a chain or a rotary saw, Up and down.

The frame 180 may be installed along the perimeter of the through-hole of the ceiling board RB in which the housing 110 is accommodated. The frame 180 is formed of an elastic body having heat dissipation properties so as to prevent frictional heat generated by friction with the housing 110 or damage caused by light emitted from the light emitting unit 130 and to apply an impact to the housing 110 . In order to minimize friction with the housing 110, a plurality of rollers may be provided in a region of the frame 180 that contacts the housing 110.

In the method of operating the light emitting assembly 100 having such a configuration, the entirety of the housing 110 may be exposed to the outside after the initial housing 110 completely deviates from the ceiling board RB. In this case, when the light emitting unit 130 is lit, the first light source 131 is reflected by the inner reflecting unit 150 in the direction of the bottom 113, and the second light source is reflected by the inner reflecting unit 150 in the direction of the side wall 115 do. Accordingly, the first light L1 and the second light L2 can be outputted from the entire direction of the housing 110 except for the direction of the ceiling 111. [ In this case, the light emitting assembly 100 can illuminate the maximum area.

Thereafter, the housing 110 can be raised and lowered in the direction of the ceiling board RB according to an intended operation of the user. In this case, since the bottom 113 of the housing 110 is continuously exposed to the outside, the first light L1 emitted from the first light source 131 is output to the outside. However, as the housing 110 is lifted and lowered, the side wall 115 is gradually housed in the ceiling board RB from the top. The second light L2 of the second light source 136 reflected by the inner reflection unit 150 in the direction of the side wall 115 is reduced in the light output to the outside in proportion to the lifting and lowering of the housing 110. [

If the lifting and lowering of the housing 110 is such that the housing 110 is completely housed in the ceiling board RB, the bottom 113 of the housing 110 is still exposed to the outside, so that the output of the first light L1 remains unchanged. However, since the side wall 115 is completely received in the ceiling board RB, the second light L2 reflected in the direction of the side wall 115 is outputted only in the ceiling board RB and is not output to the space where the user is present Do not.

Accordingly, the light output to the outside can be controlled according to the rising and falling of the light emitting assembly 100.

 It is possible to consider not only the control of the illumination area by the above-described configuration and operation method but also the additional configuration and operation method. This is a controllable method that can further improve the operational diversity of the light emitting assembly 100.

For example, it has been described that the housing 110 is fully lowered and the entire area of the housing 110 is exposed to the outside. At this time, the first light source 131 and the second light source 136 can be selectively controlled to control the illumination area and the brightness.

When the power supply of the first light source 131 is stopped when the housing 110 is completely lowered, light output by the second light source 136, that is, only in the direction of the side wall 115 of the housing 110 . Therefore, since the light in the direction of the floor 113 is not illuminated, if the above-described light control is performed in the space having the bunk bed, the influence on the lighting on the bunk bed or the living room can be minimized. Also, since the second light sources 136 are formed as a pair, only one of the pair is selectively turned on / off to further define the illumination area.

On the contrary, when the power of the second light source 136 is stopped and only the power supply of the first light source 131 is performed, it is possible to selectively illuminate the bottom 113 direction.

Further, at the time of the maximum lift of the housing 110, since the side wall 115 is completely accommodated in the ceiling board RB, the output of the second light source 136 is meaningless at this time. Therefore, a sensing unit or the like for sensing the maximum lift of the housing 110 is added to automatically turn off the second light source 136 according to the detection result of the sensing unit, thereby preventing unnecessary power wastage.

The structure and operation method of the multi-directional light emitting assembly 100 have been described above. 4 to 5, the structure and operation method of the light emitting assembly 100 including the external reflection unit 190 will be described in detail.

4 to 6 are cross-sectional views illustrating a method in which a multi-directional light-emitting assembly 100 'according to another embodiment of the present invention is provided with an external reflection unit 190 and operated accordingly.

The light emitting assembly 100 'in this figure is substantially the same as the light emitting assembly 100 of the previous embodiment but differs in that an external reflecting unit 190 is provided on the side wall 115 of the housing 110.

Referring to FIGS. 4 to 6, the light emitting assembly 100 'is angularly adjusted with respect to the side wall 115 of the housing 110 when the housing 110 is lifted and lowered, And an external reflection unit 190 for reflecting the light L2 toward the first light L1.

The external reflection unit 190 may include a reflection plate 191, a rotation coupling portion 193, and an elastic pressing body 196.

The reflective plate 191 is rotatably mounted on the side wall 115 of the housing 110 and may be positioned within the frame 180. In other words, the reflection plate 191 is formed in a plate shape corresponding to each side wall 115, and the inner surface facing the light emitting unit 130 is formed of a reflection surface coated with a reflective material.

The reflection plate 191 may include a plate projection 192 protruding from the end.

The plate projection 192 can be brought into contact with the frame 180 to make the reflector plate 190 vertical when the housing 110 is fully received in the ceiling board RB. Accordingly, the reflection plate 190 is disposed to be horizontal to the side wall 115 to completely block the external output of the second light L2. At this time, it is preferable that the plate projection 192 is projected so as to be inclined for smooth contact with the frame 180.

The rotary coupling portion 193 is a means for rotating the reflection plate 191 coupled to the housing 110 and may be formed as a rotary body such as a hinge. Therefore, the rotation coupling portion 193 is installed in the region of the ceiling 111 that is in contact with the side wall 115 and is coupled with each reflection plate 191, thereby rotating the reflection plate 191 about the rotation coupling portion 193 Lt; / RTI >

The elastic pressing body 196 elastically supports the reflecting plate 191 with respect to the housing 110 so that the reflecting plate 191 can be pressed toward the frame 180. Here, as shown in FIG. 4, the elastic pressing body 196 may be made of an elastic body such as a spring.

In the light emitting assembly 100 'having the external reflection unit 190 as described above, the degree of development of the external reflection unit 190 is changed as the housing 110 moves up and down. The external output of the light irradiated by the second light source 136 and output in the direction of the side wall 115 by the internal reflection unit 150 can be controlled by the external reflection unit 190. [

The operation of the light emitting assembly 100 'will be described with reference to FIGS. 4 through 6. FIG.

4 is a state in which the housing 110 is fully lowered and the side walls 115 of the housing 110 are all exposed to the outside. In this case, the reflection plate 191 provided on the side wall 115 is deployed in the direction of the frame 180 by the pressure of each elastic pressing body 196. When the reflective plate 191 is developed to be horizontal with respect to the frame 180, the side wall 115 of the housing 110 is exposed to the outside, so that the second light L2 can be output in the direction of the side wall 115. Accordingly, the light emitting assembly 100 'can emit light to illuminate the whole of the bottom 113 direction and the side wall 115 direction.

5 shows a case where the housing 110 shown in Fig. 4 is raised and lowered partially by the elevating unit 170 in the direction of the ceiling board RB. In this case, the reflection plate 191 is urged by the portion in contact with the frame 180 and is rotated by a predetermined angle toward the side wall 115.

When the reflection plate 191 is rotated in the direction of the side wall 115, the angle formed by the reflection plate 191 and the side wall 115 becomes narrower depending on the degree of rotation. The second light L2 transmitted through the side wall 115 is reflected by the reflection plate 191 and the optical path is changed in the direction in which the first light L1 advances.

6 shows a case in which the housing 110 of Fig. 5 is completely housed in the ceiling board RB by the elevating unit 170. Fig. In this case, the plate protrusion 192, which is the end of the reflection plate 191 which has been fully expanded in Fig. 4, is fixed by the frame 180. Fig. Accordingly, the reflection plate 191 is rotationally disposed so as to be substantially horizontal to the side wall 115. At this time, since each of the sidewalls 115 is entirely surrounded by the reflection plate 191, the second light L2 can not be outputted through the sidewall 115. The light emitting assembly 100 can output only the first light L1 through the bottom 113 of the housing 110 to the outside.

The light emitting assembly 100 'according to the above-described construction and operation method can control the illumination region by retroreflecting the second light L2 by an angle corresponding to the ascending / descending height of the housing 110.

Hereinabove, the light emitting assembly 100 having the external reflection unit 190 will be described. In FIG. 7, the control relationship of the light emitting assembly 100 "having the receiving unit 220 will be described.

7 is a block diagram illustrating a receiving unit 220 of a multi-directional illuminable light emitting assembly 100 "and a control method therefor according to another embodiment of the present invention.

As shown, the light emitting assembly 100 "is substantially the same as the light emitting assemblies 100 and 100 'of the previous embodiment but further includes a control unit 210, a receiving unit 220, and a memory 230 There is a difference.

The control unit 210 can operate at least one of the elevation unit 170 and the light emission unit 130 according to an operation command.

The receiving unit 220 may include a communication unit (not shown) and an acoustic receiver (not shown).

The communication unit is means for receiving a predetermined operation command from an external terminal. Accordingly, it is possible to receive an operation command for the elevation unit 170 and the light emitting unit 130 from the user terminal.

The sound receiver is a means for receiving sound generated outside the light emitting assembly 100 ". Accordingly, when a user's body sound or machine sound occurs in the space where the light emitting assembly 100 " is installed, have.

The memory 230 is a means for storing an operation command received through the receiving unit 220 and an acoustic signal received through the acoustic receiver.

According to the light emitting assembly 100 having such a structure, the receiving unit 220 can receive an operation command for the elevating unit 170 and the light emitting unit 130 from the user terminal through the communication unit. In other words, the user transmits an operation command related to the ascending / descending degree of the elevation unit 170 and the on / off of the light emitting unit 130 through his / her terminal. The operation command thus received by the communication unit is stored in the memory 230. Thereafter, the control unit 210 refers to the memory 230 and controls driving of the elevation unit 170 and the light emission unit 130 in accordance with the reference result.

Further, when the receiving unit 220 is configured as an acoustic receiver, the user can control the elevating unit 170 and the light emitting unit 130 by generating a specific sound. The acoustic receiver receives the sound generated by the user and stores it in the memory 230. The control unit 210 may distinguish between sounds generated once within a set time and sounds generated a plurality of times by referring to sounds stored in the memory 230 and recognize the sounds as different operating commands.

For example, when the user performs the applause once, the control unit 210 can refer to the sound to light the light emitting unit 130 because the sound is generated one time.

In addition, when the user jumps twice, the control unit 210 may turn off the light emitting unit 130 referring to the sound because a plurality of sounds will be generated.

In addition, when a predetermined word is received through the acoustic receiver, the control unit 210 may compare the predetermined word with a predetermined reference word, and may control the elevation unit 170 and the light emission unit 130 according to the comparison result .

The multi-directional light-emitting assembly as described above is not limited to the configuration and operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100, 100 ', 100 ": light emitting assembly 180: frame
110: housing 190: external reflection unit
111: Ceiling 191: Reflecting plate
113: bottom 193:
115: side wall 196: elastic pressing body
130: light emitting unit 210: control unit
131: first light source 220: receiving unit
136: second light source 230: memory
150: internal reflection unit RB: ceiling board
151: first reflection surface L1: first reflection
156: second reflection surface L2: second light
170: Lift unit
171: Motor
176: Wire

Claims (8)

A hollow housing;
A light emitting unit disposed in the housing and including a first light source for outputting the first light and a second light source for outputting the second light;
A first reflection surface provided to surround the first light in the housing and configured to reflect the first light and a second reflection surface formed to reflect the second light in a direction different from the first light, An inner reflection unit having two reflection surfaces;
A lifting unit for lifting and lowering the housing; And
And an external reflecting unit that is angularly adjusted with respect to a side wall of the housing when the housing is lifted and thereby reflects the second light toward the first light side.
The method according to claim 1,
Wherein the light emitting unit is mounted on a ceiling of the housing,
Wherein the internal reflection unit has the form of a horn extending from the ceiling of the housing toward the bottom of the housing.
3. The method of claim 2,
The housing is formed in a hexahedron,
Wherein the internal reflection unit is formed in a quadrangular pyramid shape that connects the four corners of the bottom face of the hexahedron to the light emitting unit.
delete The method according to claim 1,
And a hollow frame surrounding the housing and through which the housing passes when lifted by the lifting unit.
6. The method of claim 5,
The external reflection unit includes:
A reflective plate rotatably mounted on a side wall of the housing, the reflective plate positioned within the frame; And
And an elastic pressing body for elastically supporting the reflection plate with respect to the housing and pressing the reflection plate toward the frame.
The method according to claim 1,
A control unit for operating at least one of the lifting unit and the light emitting unit according to an operation command; And
Further comprising a receiving unit for receiving the operating command.
8. The method of claim 7,
The receiving unit includes:
An acoustic receiver,
Wherein the control unit comprises:
And distinguishes between the sound generated once within the set time and the sound generated plural times, and recognizes each of the sounds as the other of the operation commands.

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