KR102670052B1 - Light device having anti-glare function through a pluratlity of elevating reflectors - Google Patents

Abstract

The present invention relates to a lighting device with an anti-glare function, comprising: a light emitting unit provided by installing a plurality of LED modules on a circuit board; a diffusion plate disposed at a predetermined distance below the light emitting unit and causing diffusion of light emitted from the LED module; The first optical device is made of an optical film made of polyester and is arranged at a predetermined distance below the diffusion plate, and has a plurality of protruding prism structures on which the surface on which the light passing through the diffusion plate is incident protrudes toward the diffusion plate. Sheet; A first diffuse reflection plate made of a hollow, cylindrical aluminum plate that surrounds a side surface of an open space spaced apart from the light emitting unit and the diffusion plate, and has a concave-convex structure that causes diffuse reflection on the inner side along the upper and lower height directions; A second plate is made of a hollow, cylindrical aluminum plate that surrounds the side surface of the spaced open space between the diffusion plate and the first optical sheet, and has a concave-convex structure that causes diffuse reflection on the inner side along the vertical and horizontal height directions. reflector; and a housing provided in a cylindrical shape with a predetermined internal installation space with an open lower side, to accommodate and install the light emitting unit, diffusion plate, first optical sheet, first diffuse reflection plate, and second diffuse reflection plate within the installation space. Includes.

Description

A lighting device with an anti-glare function through multiple reflectors that can be raised and lowered {LIGHT DEVICE HAVING ANTI-GLARE FUNCTION THROUGH A PLURATLITY OF ELEVATING REFLECTORS}

The present invention relates to a lighting device with an anti-glare function.

In the case of a lighting device that irradiates light and provides light of a certain illuminance, light of various wavelengths is output. Among these, when light of a harmful wavelength that causes discomfort to the eyes continues to irritate the eyes, the light provided from the lighting device is interrupted. People feel glare, which often causes great discomfort.

Since the problem of glare caused by lighting devices ultimately affects the formation of human fatigue, various anti-glare functions have been developed to solve this problem and are currently being applied to lighting devices.

For example, a technology that installs a type of reflective polarization filtering panel at the tip of the light source to allow vertical light, which is good light, to pass through, but reflects harmful light, which can cause eye fatigue and glare, and then converts it back to vertical light and outputs it. , Instead of directly outputting light to the space where lighting is desired, a variety of technologies have been developed, ranging from technologies that enable indirect light irradiation by providing light in the direction opposite to the space requiring light using a reflector. there is.

In relation to this, prior literature on the prior art that has been prepared to provide an anti-glare function through an indirect form of light irradiation includes Korean Patent Publication No. 10-2016-0050526 titled “Anti-glare lighting device using an LED reflector” (hereinafter, (referred to as ‘prior art’).

However, in the case of existing lighting devices equipped with an anti-glare function, including the prior art, the light is irradiated indirectly or the amount of light is lowered to maintain a balance between the sufficient light output function that must be provided as basic lighting and the anti-glare function of the output light. There was a problem in that functionality could not be established and the characteristics were biased towards one side.

In addition, in the case of lighting devices equipped with an existing anti-glare function, including the prior art, the level and area to which the function is applied in providing the anti-glare function are already fixed and set during the installation process of the device, so the lighting device There was a problem in that the anti-glare function could not be provided variably in response to the position of the person within the installed lighting space.

The present invention was created to solve the above problems, and the purpose of the present invention is to not only provide an anti-glare function in harmony with the basic function of providing lighting, but also to provide an anti-glare function to the location of people in the space where the lighting device is installed. The aim is to provide a lighting device in which the level and area of the anti-glare function can be variably applied in response.

In order to achieve the above object, a lighting device with an anti-glare function of the present invention includes a light emitting unit provided by installing a plurality of LED modules on a circuit board; a diffusion plate disposed at a predetermined distance below the light emitting unit and causing diffusion of light emitted from the LED module; The first optical device is made of an optical film made of polyester and is arranged at a predetermined distance below the diffusion plate, and has a plurality of protruding prism structures on which the surface on which the light passing through the diffusion plate is incident protrudes toward the diffusion plate. Sheet; A first diffuse reflection plate made of a hollow, cylindrical aluminum plate that surrounds a side surface of an open space spaced apart from the light emitting unit and the diffusion plate, and has a concave-convex structure that causes diffuse reflection on the inner side along the upper and lower height directions; A second plate is made of a hollow, cylindrical aluminum plate that surrounds the side surface of the spaced open space between the diffusion plate and the first optical sheet, and has a concave-convex structure that causes diffuse reflection on the inner side along the vertical and horizontal height directions. reflector; and a housing provided in a cylindrical shape with a predetermined internal installation space with an open lower side, to accommodate and install the light emitting unit, diffusion plate, first optical sheet, first diffuse reflection plate, and second diffuse reflection plate within the installation space. Includes.

And the lighting device with the anti-glare function is made of an optical film made of polyester, is placed at a predetermined distance below the first optical sheet, and is connected and installed to protrude below the installation space of the housing, and is located in the central area. The surface on which the light passing through the first optical sheet is incident has a concave structure, and the outer extension area, which is bent upward at an angle of 20 to 30 degrees from the central area and extends radially, has a concave structure and has a concave structure. a second optical sheet having a convex structure on the surface on which light is incident; and a Barrisol film having a cylindrical shape with an open upper side and a predetermined internal receiving space, which wraps around the outer circumference of the second optical sheet and accommodates the second optical sheet in the internal receiving space. It may further include an anti-glare sheet connected and installed below the housing.

Here, the housing has a cylindrical shape with the lower side open so that the installation space is provided inside, and the side wall portion corresponding to the side edge area based on the overall shape is divided at regular intervals to form at least two reflector lifting portions. wealth; At least two or more first reflectors installed in a form that can be raised and lowered in a first reflector receiving groove provided to be open at the lower side of each of the at least two or more reflector lifting portions partitioned on the side wall of the body portion; And a second reflector installed in a liftable form in a second reflector receiving groove provided to open the lower side of each of the two or more first reflectors. The lighting device with the anti-glare function includes a side wall portion of the body portion. At least two or more lifting portions of the reflector partitioned on each side are installed on one side, and are connected to the first reflector and the second reflector, so as to raise and lower the state of the first reflector and the second reflector from the first reflector receiving groove according to a lifting command. It may further include a lifting control unit that controls the lifting state of the second reflector from the receiving groove.

In addition, the lighting device with the anti-glare function is connected to and installed in correspondence with the lifting control unit installed for each of the reflector lifting parts on one side of each of the at least two reflector lifting parts partitioned on the side wall of the body, and has a predetermined It further includes a motion sensor unit that detects movement within the detection area, wherein the lifting control unit lowers at least one of the first and second reflectors when movement within the detection area is detected by the motion sensor unit connected to each other. It can be moved.

In addition, the motion sensor unit detects movement within a predetermined detection area and calculates the separation distance of the object whose movement is detected, and the lifting control unit calculates the separation distance of the object whose motion is detected calculated through the motion sensor unit. If it falls within the set first separation distance reference range, the first reflector is moved downward from the first reflector receiving groove, and the lifting control unit determines that the separation distance of the object whose movement is detected calculated through the motion sensor unit is the first reflector. 1 If it falls within the preset second separation distance reference range, which is shorter than the separation distance reference range, the first reflector is moved downward from the first reflector receiving groove, and then the second reflector is moved from the second reflector receiving groove. It can be moved downward.

According to the present invention, the following effects are achieved.

First, an anti-glare function can be appropriately provided in harmony with the basic function of providing lighting through LED light irradiation.

Second, the level and area of the anti-glare function can be variably applied in response to the position of the person in the space where the lighting device is installed.

Third, by providing a stable and sufficient anti-glare function, the fatigue on the eyes of people located around the lighting device can be clearly reduced.

Figure 1 is a perspective view showing a lighting device with an anti-glare function according to the present invention.
Figure 2 is a cross-sectional view showing the cross-sectional shape of the lighting device with an anti-glare function according to the present invention in the width direction.
Figure 3 is a perspective view showing an embodiment of the first and second reflector lifting controls of the lighting device with an anti-glare function according to the present invention.
Figures 4 and 5 are conceptual diagrams illustrating the control form of raising and lowering the first and second reflectors according to the position and separation distance of a person in the lighting space of the lighting device with an anti-glare function according to the present invention.

Preferred embodiments of the present invention will be described in more detail with reference to the attached drawings, but already well-known technical parts will be omitted or compressed for brevity of explanation.

<Description of lighting device with anti-glare function>

1 to 3, the lighting device 100 with an anti-glare function of the present invention includes a light emitting unit 110; diffusion plate 120; First optical sheet 130; Second optical sheet 140; First diffuse reflection plate (150); second diffuse reflection plate (160); Anti-glare sheet 170; housing (180); Lifting control unit 191; Motion sensor unit 192; and a command receiver 193.

The light emitting unit 110 is a light emitting component provided by installing a plurality of LED modules 112 on the circuit board 111, and is a switch or remote control connected wired or wirelessly through a command receiving unit 193 to be described below. The LED module 112 is turned on or off according to the light irradiation ON/OFF control command signal input from.

The diffusion plate 120 is disposed below the light emitting unit 110 at a predetermined interval and corresponds to an optical film that causes diffusion of light emitted from the LED module 112, and has a plate structure filled with diffusion beads. It is equipped with

Here, the light emitted from the LED module 112 hits the diffusion beads filled in the diffusion plate 120 and is directed downward with a high illuminance value and excellent refractive transmittance and diffuse transmittance.

This diffusion plate 120 is made of polycarbonate (PC), and preferably has a thickness of 10 to 15 mm.

Furthermore, a first diffuse reflection plate 150 is installed on the side of the open space spaced apart from the light emitting unit 110 and the diffusion plate 120, so that the light irradiated from the light emitting unit 110 and transmitted through the diffusion plate 120 The light sources that spread laterally in the middle cause diffuse reflection to take the form of soft light, and the light that has undergone this diffuse reflection is allowed to transmit through the diffusion plate 120.

More specifically, the first diffuse reflection plate 150 is made of an aluminum plate having a hollow cylindrical shape, and is installed to surround the side perimeter of the open space spaced apart from each other between the light emitting unit 110 and the diffusion plate 120.

In addition, an uneven structure that causes diffuse reflection along the upper and lower height directions is formed on the inner surface of the side wall portion corresponding to the side edge area based on the overall shape of the first diffuse reflection plate 150, thereby providing the diffuse reflection effect of light projected to the side as described above. Let it be lost.

The first optical sheet 130 is made of a milky-white polyester optical film and is placed below the diffusion plate 120 at a predetermined distance. The surface on which the light passing through the diffusion plate 120 is incident is shown in Figure 2. As shown, it has a plurality of protruding prism structures protruding toward the diffusion plate.

Here, the structure of the upper side corresponding to the side of the diffusion plate 120 of the first optical sheet 130 has a structure in which hemispherical protrusions protrude upward, lowering the light intensity to a certain level, especially causing glare. It is important to lower the light intensity to a certain level in the area where the light distribution angle is 60 degrees to 90 degrees and in the area between ??60 degrees and ??90 degrees.

In addition, the structure of the upper surface corresponding to the diffusion plate 120 side of the first optical sheet 130 has a hemispherical protrusion protruding upward, so that the light incident through the diffusion plate 120 is maximized. This is also to prevent it from spreading in any direction.

Furthermore, a second diffuse reflection plate 160 is installed on the side of the open space spaced apart from the diffusion plate 120 and the first optical sheet 130 to transmit through the diffusion plate 120 to the first optical sheet 130. Among the light incident on the light sources that spread laterally, cause diffuse reflection to take the form of soft light, and the light that has undergone this diffuse reflection is allowed to transmit through the first optical sheet 130.

More specifically, the second diffuse reflection plate 160 is made of an aluminum plate with a hollow cylindrical shape, and is installed to surround the side perimeter of the mutually spaced open space between the diffusion plate 120 and the first optical sheet 130. do.

In addition, the second diffuse reflection plate 160 has an uneven structure that causes diffuse reflection along the upper and lower height directions on the inner surface of the side wall corresponding to the side edge area based on the overall shape, thereby providing the diffuse reflection effect of light projected to the side as described above. Let it come true.

As shown in Figure 1, the housing 180 is a body that forms the overall external structure and has a predetermined internal installation space with the lower side open, and is equipped with the light emitting unit 110 and the diffusion plate ( 120), the first optical sheet 130, the second optical sheet 140, the first diffuse reflection plate 150, and the second diffuse reflection plate 160 are accommodated and installed in the installation space.

In addition, as shown in FIG. 1, on the outer lower side of the housing 180, a second optical sheet 140 and an anti-glare sheet 170, which will be described below, are exposed and installed in a downward protruding shape.

The second optical sheet 140 is another optical sheet made of polyester optical film, arranged at a predetermined distance below the first optical sheet, and connected to protrude below the installation space of the housing 180. , This is a configuration designed to adjust the refraction state of light differently for each area so that light can be more concentrated in the center and less light concentrated on the sides.

More specifically, as shown in Figure 2, the second optical sheet 140 has a concave structure on the surface on which the light passing through the first optical sheet 130 is incident, so it is a plane that refracts the light coming toward the center outward. It consists of a central area 141 of the same shape as a concave lens and an outer extension area 142 that is bent upward at an angle of 20 to 30 degrees from the central area 141 and extends radially.

Here, the surface on which the light passing through the first optical sheet 130 of the outer expansion area 142 is incident has a convex structure to refract the light coming from the outside toward the center.

The anti-glare sheet 170 corresponds to a Barrisol film provided in a cylindrical shape with a predetermined receiving space with an open upper side inside, and wraps around the outer circumference of the second optical sheet 140 and accommodates the inside. It is connected and installed below the housing 180 to accommodate the second optical sheet in the space.

Here, the anti-glare sheet 170 is a stretch sealing film made of Barrisol film over the entire shape and tightly covered on a separate cylindrical frame, and finally accommodates the second optical sheet 140 on the inside. The light passing through the second optical sheet 140 is output to the outside through the anti-glare sheet 170, making it possible to provide a lighting function.

In addition, as the light passing through the second optical sheet 140 finally passes through the anti-glare sheet 170, the light spreads and diffuses, further reinforcing the anti-glare function.

Through the characteristics of the optical system formed inside and below the outside of the housing 180, the lighting device 100 of the present invention primarily provides an anti-glare function over the entire lighting area at a certain level, Furthermore, it includes various configurations partitioned on one side of the housing 180 to provide a selective anti-glare function that corresponds to and takes into account the location of the person receiving the lighting.

Specifically, the housing 180 has a cylindrical shape with the lower side open so that an installation space is provided inside, and the side wall portion corresponding to the side edge area based on the overall shape is divided at regular intervals to form at least two reflector lifting portions 182A to 182A. Based on the body portion 181 forming 182F), at least two or more reflectors 182 that can be raised and lowered are individually provided for each partitioned area.

Here, the reflector 182 is preferably composed of a first reflector (182a) and a second reflector (182b) based on the vertical direction, and the second reflector (182b) is in a form that can be lifted up and down inside the first reflector (182a). The first reflector 182a is accommodated and installed inside each of the reflector lifting portions 182A to 182F of the body 181 in a form that can be raised and lowered.

First, the first reflector 182a is installed in a manner that can be raised and lowered within the first reflector receiving groove 181H, which is provided to open the lower side of each of at least two reflector lifting parts 182A to 182F partitioned on the side wall of the body. In this way, at least two or more are provided corresponding to the number of divisions of the reflector lifting portions 182A to 182F.

Next, the second reflector 182b is installed in a liftable manner within the second reflector receiving groove 182H, which is provided to be open at the lower side of each of the two or more first reflectors 182a, and is installed in a liftable manner, and the reflector lifting portions 182A to 182F ), there are at least two or more to correspond to the number of sections.

The liftable connection structure of the first reflector 182a within the first reflector receiving groove 181H and the liftable connection structure of the second reflector 182b within the second reflector receiving groove 182H are located inside the groove. A method of raising or lowering the reflector using a separate motor driving means along the rail provided in the reflector, allowing it to be lifted up and down using a hydraulic device or a small piston and cylinder device, or stretching or winding the rope members connected to both sides of the top according to the rotation of the motor. It can be applied in a variety of ways based on various known technologies, such as lifting and lowering.

The lifting control unit 191 is installed on one side of each of the at least two reflector lifting parts 182A to 182F partitioned on the side wall of the body, and is connected to the first reflecting plate 182a and the second reflecting plate 182b to respond to lifting commands. Accordingly, the elevation state of the first reflector plate (182a) from the first reflector plate receiving groove (181H) and the elevation state of the second reflector plate (182b) from the second reflector plate receiving groove (182H) are adjusted.

These lifting control units 191 are provided in at least two numbers so that they can be installed in each part corresponding to the number of divisions of the reflector lifting parts 182A to 182F.

Moreover, when the first reflector (182a) and the second reflector (182b) are moved upward as much as possible through the elevation control unit 191, they are below the reflector elevation portion (182F) like the specific reflector elevation portion (182F) shown in Figures 1 and 3. As no reflector 182 comes down, the lighting function by light output to the outside through the anti-glare sheet 170 is provided as is.

In addition, when the first reflector (182a) and the second reflector (182b) are moved downward as much as possible through the elevation control unit 191, they are moved below the reflector elevation portion (182A) like the specific reflector elevation portion (182A) shown in Figures 1 and 3. As both the first reflector (182a) and the second reflector (182b) come down to block most of the light output to the outside through the anti-glare sheet (170), lighting is provided to a certain area on the side where the corresponding reflector elevation portion (182A) is located. It is rarely provided.

Specifically, as shown in Figure 5, the lifting control unit 191 controls the first reflector 182a and the second reflector ( By adjusting the elevation state of 182b), the level of lighting restriction through reflection of light output to the outside through the anti-glare sheet 170 is varied.

In addition, depending on the implementation, the position and distance of a person who moves is automatically detected through the motion sensor unit 192, and the first reflector plate 182a is detected from the first reflector receiving groove 181H through the lift control unit 191. The elevation state and the elevation state of the second reflector 182b can be adjusted from the second reflector receiving groove 182H.

For this purpose, the motion sensor unit 192 corresponds to a lifting control unit 191 installed for each of the reflector lifting parts (182A to 182F) on one side of at least two or more reflecting plate lifting parts (182A to 182F) partitioned on the side wall of the body. It is connected and installed, and detects movement within a predetermined detection area.

Furthermore, the motion sensor unit 192 corresponds to a sensing module that detects movement within a predetermined detection area and then calculates the separation distance of the object whose movement was detected.

These motion sensor units 192 are provided in at least two pieces so that they can be installed in each part corresponding to the number of divisions of the reflector lifting parts 182A to 182F.

Accordingly, as shown in FIG. 4, a motion sensor having a respective detection area for each of the divided reflector lifting portions 182A to 182F of the body portion 181 within a specific lighting area T where the lighting device 100 is installed The unit 192 continuously senses the presence of a person (P) moving within its detection area, and through this, the lifting control unit 191 detects movement within the detection area from the motion sensor unit 192 connected to each other. In this case, at least one of the first reflector (182a) and the second reflector (182b) is moved downward to block some or most of the light output to the outside through the anti-glare sheet 170, thereby reducing the level of lighting limitation through light reflection. It will be controlled.

Specifically, as shown in Figure 4, when the motion sensor unit 192 installed on the specific reflector lifting part 182A detects the presence of a person (P) within its detection area, the lifting control unit connected to the motion sensor unit 192 (191) lowers and moves at least one of the first reflector (182a) and the second reflector (182b) installed within the specific reflector lifting part (182A) to the area on the side of the specific reflector lifting part (182A) within the lighting area (T). is made into a lighting restriction area (DT) so that light is limited to only the side where the person is standing, and the remaining area becomes a lighting provision area (LT).

Furthermore, if the separation distance of the objects (P1, P2) whose movement is detected calculated through the motion sensor unit 192 falls within the preset first separation distance reference range, the lift control unit 191 The first reflector 182a is moved downward from the receiving groove 181H.

At the same time, the lifting control unit 191 sets the preset second separation distance reference range so that the separation distance of the objects (P1, P2) whose movement is detected calculated through the motion sensor unit 192 is shorter than the upper first separation distance reference range. If it falls within the range, the first reflecting plate 182a is moved downward from the first lifting plate receiving groove 181H, and then the second reflecting plate 182b is moved downward from the second lifting plate receiving groove 182H.

In other words, if the separation distance is long, lighting limitation is performed using only the first reflector (182a), and if the separation distance is close, lighting limitation is performed using both the first reflector (182a) and the second reflector (182b). I do it.

Specifically, as shown in Figure 5, the separation distance of the person (P1) detected by the motion sensor unit 192 installed in a specific reflector lifting part 182A is determined by the motion sensor unit installed in a specific reflector lifting part 182C ( Since it is far compared to the separation distance of the person (P2) detected by 192), only the first reflector (182a) is lowered so that only the light directed to the side among the light output to the outside through the anti-glare sheet (170) is reflected. A specific area within the lighting area (T) on the side of the reflector lifting portion (182A) is made into a lighting partial restriction area (DT1).

In addition, as shown in Figure 5, the separation distance of the person (P2) detected by the motion sensor unit 192 installed in a specific other reflector lifting part 182C is the motion sensor unit 192 installed in a specific reflector lifting part 182A. ) is closer than the separation distance of the detected person (P1), so both the first reflector (182a) and the second reflector (182b) are lowered to reflect all the light output to the outside through the anti-glare sheet (170). By doing so, the area on the side of the specific other reflector lifting part (182C) within the lighting area (T) becomes the overall lighting restriction area (DT2).

The embodiments disclosed in the present invention are not intended to limit but illustrate the technical idea of the present invention, and the scope of the technical idea of the present invention is not limited by these examples. The scope of protection should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of the present invention.

100: Lighting device with anti-glare function
110: light emitting part
111: circuit board 112: LED module
120: diffusion plate
130: first optical sheet
140: Second optical sheet
141: central area 142: outer extended area
150: 1st diffuse reflection plate
160: 2nd diffuse reflector
170: Anti-glare sheet
180: housing
181: Body 181H: First reflector receiving groove
182a: first reflector 182H: second reflector receiving groove
182b: second reflector
191: Lifting control unit
192: Motion sensor unit
193: Command reception unit

Claims (4)

A light emitting unit provided by installing a plurality of LED modules on a circuit board;
a diffusion plate disposed at a predetermined distance below the light emitting unit and causing diffusion of light emitted from the LED module;
The first optical device is made of an optical film made of polyester and is arranged at a predetermined distance below the diffusion plate, and has a plurality of protruding prism structures on which the surface on which the light passing through the diffusion plate is incident protrudes toward the diffusion plate. Sheet;
A first diffuse reflection plate made of a hollow, cylindrical aluminum plate that surrounds a side surface of an open space spaced apart from the light emitting unit and the diffusion plate, and has a concave-convex structure that causes diffuse reflection on the inner side along the upper and lower height directions;
A second plate is made of a hollow, cylindrical aluminum plate that surrounds the side surface of the spaced open space between the diffusion plate and the first optical sheet, and has a concave-convex structure that causes diffuse reflection on the inner side along the vertical and horizontal height directions. reflector;
A housing provided in a cylindrical shape with an open lower side and a predetermined internal installation space to accommodate and install the light emitting unit, a diffusion plate, a first optical sheet, a first diffuse reflection plate, and a second diffuse reflection plate within the installation space;
It is made of an optical film made of polyester, is placed at a predetermined distance below the first optical sheet, is connected and installed to protrude below the installation space of the housing, and the central area is where the light passing through the first optical sheet is incident. The surface has a concave structure, and in the outer expanded area, which is bent upward at an angle of 20 to 30 degrees from the central area and extends radially, the surface on which the light passing through the first optical sheet is incident has a convex structure. optical sheet; and
The housing is provided with a Barrisol film having a cylindrical shape with an open upper side and a predetermined internal receiving space, and wraps around the outer circumference of the second optical sheet to accommodate the second optical sheet in the internal receiving space. Includes an anti-glare sheet connected and installed below,
The housing has a cylindrical shape with an open lower side so that the installation space is provided inside, and the side wall portion corresponding to the side border area based on the overall shape is divided at regular intervals to form at least two reflector lifting portions, including a body portion; At least two or more first reflectors installed in a liftable form in a first reflector receiving groove provided to be open at the lower side of each of the at least two or more lifting portions of the reflector formed on the side wall of the body, and a lower side of each of the two or more first reflectors. Characterized in that it includes a second reflector installed in a liftable form within the second reflector receiving groove provided to be open.
A lighting device with an anti-glare function through multiple reflectors that can be raised and lowered. delete delete delete

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