KR102454650B1 - Light Reflecting Device For Natural Light Of Embedded Type And Its Manufacturing Method - Google Patents

Abstract

The present invention relates to a light reflecting device for natural light, and more particularly, it is possible to improve sunlight inflow performance by reflecting incident sunlight into a room regardless of the position or altitude of the sun and allowing the sunlight to flow into the room. It relates to an embedded light reflection device for natural lighting and a manufacturing method thereof.

Description

Light Reflecting Device For Natural Light Of Embedded Type And Its Manufacturing Method

The present invention relates to a light reflecting device for natural light, and more particularly, it is possible to improve sunlight inflow performance by reflecting incident sunlight into a room regardless of the position or altitude of the sun and allowing the sunlight to flow into the room. It relates to an embedded light reflection device for natural lighting and a manufacturing method thereof.

The natural lighting device is a device that introduces sunlight into the room through the windows installed adjacent to the outside air. It is an eco-friendly device that can transmit sunlight and save lighting energy through efficient indoor inflow.

In general, the shape of the natural lighting device can be divided into a buried type that coincides with a finished surface on which it is installed, and a protruding type that protrudes from the finished surface in a dome-like shape.

In the case of the buried type, since it matches the finished surface, it can be applied in various forms to buildings because there is no external protrusion. have.

However, the conventional buried-type natural lighting device has a structure that allows only passive lighting through a large hole through a window through which sunlight is incident, and a simple light collection structure that transmits only a part of the incoming sunlight through a light transmission means. There was a problem that the size of the window to be increased had to be increased.

In addition, the conventional buried-type natural lighting device has a problem in that it is difficult to secure indoor illuminance due to the fact that the angle and direction of the incoming sunlight change with time according to the altitude and azimuth of the sun, except for the location where the sun is culminating. .

As devised to solve the above problems, the object of the present invention is to reflect the incident sunlight into the room regardless of the position or altitude of the sun and to introduce the sunlight into the room, so it is possible to improve the solar inflow performance. It is an object of the present invention to provide an embedded light reflection device for natural lighting and a method for manufacturing the same.

As devised to achieve the above object, a buried type light reflection device for natural light according to the present invention includes: a frame 10 formed in an opening (A) of a ceiling through which sunlight is introduced; including a reflective member 20 mounted in the frame; The reflective member 20 is formed such that the unit reflective unit 20a having a hexagonal empty space therein is continuously arranged to form a pattern, so that sunlight can be introduced into the interior regardless of the position or altitude of the sun do it with

The unit reflection unit 20a includes first and second connection surface reflectors 211 and 212 spaced apart from each other and disposed to face each other and a virtual line orthogonal to a virtual line connecting the first and second connection surface reflection units. 3rd and 4th connecting surface reflecting parts 213 and 214 spaced apart on a line; and first to fourth unit surface reflection units 221 to 224 respectively connected between the first to fourth connection surface reflection units 211 to 214 .

Here, the first to fourth connecting surface reflecting units 211 to 214 and the first to fourth connecting surface reflecting units 221 to 224 are connected to the inside through four unit surface reflecting units 221 to 224, respectively. A hexagonal empty space is formed; The first to fourth connecting surface reflectors 211 to 214 are all arranged to face the same direction and arranged to have a constant inclination θ with the floor level.

the four unit surface reflection units 221 to 224 are connected from the upper end to the lower end of the connecting surface reflection unit and the neighboring reflection unit to have an inclination; The height of the four unit surface reflectors 221 to 224 is configured to be 1/2 of the height of the connection surface reflector, so that the height of the two unit surface reflectors is the same as the height of the connection surface reflector.

the unit reflection unit 20a is configured to share one connecting surface reflection unit with an adjacent unit reflection unit and is extended in the biaxial direction; One unit reflection unit 20a is configured to share one of the first to fourth connection surface reflection units with four adjacent unit reflection units.

On the other hand, in the method for manufacturing an embedded light reflection device for natural light according to the present invention, unit reflection units 20a having a hexagonal empty space therein are continuously arranged to form a pattern, so that sunlight is emitted regardless of the position or altitude of the sun. A method of manufacturing an embedded light reflecting device for natural light, comprising a reflecting member that can be introduced therein; preparing a plate-shaped reflective member base material and specifying and displaying a bending line (R) and a cutout (C) to distinguish each component constituting a unit reflective unit; cutting the cutout (C); and forming a three-dimensional pattern in which unit reflection units are continuous by folding up and down along a bending line (R) so that a space due to the cutout (C) is formed in a hexagon.

The reflective member base material is made of a flexible material so that it can be freely bent, and a reflective film is attached or a reflective coating is formed on the base material.

The step of forming the continuous three-dimensional pattern of the unit reflection unit is performed by bending the unit reflection unit 220 while folding all the connecting surface reflection units 210 to have an inclination θ in the same direction. ) In a state in which a hexagonal shape is formed inside, the bottom surfaces of all the connecting surface reflection units 210 are spread out in a shape that touches the floor, and the unit reflection unit 20a is continuously formed to form a three-dimensional pattern.

As described above, the buried-type light reflecting device for natural light and the manufacturing method thereof according to the present invention reflect the incident sunlight into the room regardless of the position or altitude of the sun and allow the sunlight to flow into the room. There is an excellent effect that can improve the

In addition, since a complex three-dimensional pattern structure can be easily manufactured only by cutting and bending, an excellent effect of reducing the manufacturing cost and increasing the yield occurs.

1 is a block diagram schematically illustrating an embedded light reflection device for natural light according to a preferred embodiment of the present invention.
Figure 2 is a cross-sectional view and a plan view of the light reflection device of Figure 1,
FIG. 3 is an exploded perspective view of the light reflection device of FIG. 1 .
4 schematically shows a reflective member according to a preferred embodiment of the present invention.
Figure 5 schematically shows the inflow of sunlight through the reflection member according to the position of the sun according to a preferred embodiment of the present invention.
6 schematically illustrates a method of manufacturing a reflective member according to a preferred embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

1 is a block diagram schematically illustrating an embedded light reflection device for natural light according to a preferred embodiment of the present invention.

FIG. 2 is a cross-sectional view and a plan view of the light reflecting device of FIG. 1 , and FIG. 3 is an exploded perspective view of the light reflecting device of FIG. 1 .

1 to 3, the light reflecting device for natural light according to a preferred embodiment of the present invention includes a frame 10 formed in an opening A of a ceiling through which sunlight is introduced, and a reflective member 20 mounted in the frame. It may be composed of

Basically, the present invention can be applied to a buried type natural lighting device in which it is difficult to introduce sunlight into the interior.

In addition, a transparent upper protective panel 30 and a lower protective panel 40 are further installed on the frame 10 on which the reflective member 20 is mounted to protect the reflective member and prevent foreign substances from entering the inside. It may be configured to include, and the side of the opening (A) may be configured to include an optical fiber 50 for reflecting light downward.

Here, the opening A may be configured in various shapes such as a circle, a polygon, and an irregular shape, but in the case of an angled shape, light loss due to the angle may occur, so it is preferable to have a circular shape.

The frame 10 is coupled to the upper edge of the side of the opening, and may have the same shape as the shape of the opening. That is, when the shape of the opening is circular, the frame may also be configured in a circular shape.

The frame 10 serves as a fixing frame for fixing the reflective member 20 .

In addition, the upper protection panel 30 may be made of transparent tempered glass or reinforced plastic, and may be composed of multiple panels to enhance durability.

More specifically, the upper protection panel 30 may be configured in a form in which a color or pattern printed glass (Silk screen painted glass) is combined between two tempered glass as shown in FIGS. 1 to 3 . .

Here, the upper protection panel 30 is formed to be larger than the frame 10 , and the opening to which the upper protection panel 30 is coupled is also formed to be larger than the opening through which the frame 10 is installed, so that the upper protection panel 30 is formed to be larger than the frame 10 . It may be configured to be stably fixed.

And, as shown in FIG. 2B , the upper protection panel 30 or the lower protection panel 40 may further include a fall prevention bar 50 to prevent the reflective member 20 from falling downward.

In addition, when the upper protection panel 30 is installed in a place where people pass, it may be configured to further include a non-slip coating as shown in FIG. 2B to prevent slipping.

In addition, the reflective member 20 serves to increase the amount of incoming sunlight by reflecting sunlight downwards.

4 schematically shows a reflective member according to a preferred embodiment of the present invention.

Referring to FIG. 4 , the reflective member 20 according to the present invention may be configured to have a unit pattern shape in which a unit reflective unit 20a having a hexagonal space therein is continuously coupled in vertical and horizontal directions. .

More specifically, the unit reflection unit 20a is a virtual line connecting the first and second connection surface reflectors 211 and 212, which are spaced apart from each other and disposed to face each other at a predetermined interval, and the first and second connection surface reflection units. The third and fourth connecting surface reflectors 213 and 214 spaced apart from each other on an orthogonal imaginary line and the first to fourth connecting surface reflectors 211 to 214, respectively, are connected between the four unit surface reflectors [th 1 to 4 unit surface reflectors 221 to 224].

Through the four unit surface reflection parts 221 to 224 respectively connected between the first to fourth connection surface reflection parts 211 to 214 and the first to fourth connection surface reflection parts 221 to 224, a hexagonal shape inside An empty space may be formed.

In addition, the first to fourth connecting surface reflectors 211 to 214 may be disposed to face the same direction and to have a constant inclination θ with the floor level.

In addition, the four unit surface reflectors 221 to 224 may be configured to be inclined by being connected from the upper end to the lower end of the connecting surface reflector and the neighboring reflector.

Here, the height H of the four unit surface reflectors 221 to 224 is configured to be 1/2 of the height of the connecting surface reflector, so that the height H of the two unit surface reflectors is the height of the connecting surface reflector. It can be configured to be the same as

The height (H) and the inclination (θ) of the unit surface reflector may be variously changed according to the size and design specifications of the opening.

More specifically, the four unit surface reflection units are connected to the first unit surface reflection unit 221 and the third connection surface connected to the upper portion of the first connection surface reflection unit 211 and the lower portion of the third connection surface reflection unit 213 . The second unit surface reflection unit 222 connected to the upper portion of the reflection unit 213 and the lower portion of the second connection surface reflection unit 212, the lower portion of the second unit surface reflection unit 212 and the fourth connection surface reflection unit ( 214) the third unit surface reflection unit 223 connected to the upper portion, the fourth unit surface reflection unit 224 connected to the lower portion of the fourth connection surface reflection unit 214 and the first unit surface reflection unit 211 to the upper portion; may be included.

In the reflective member 20, the unit reflective units 20a as described above are continuously arranged in the two-axis direction (X-axis, Y-axis) to form a pattern. The unit reflection unit 20a is a three-dimensional pattern rather than a plane, and the Z axis should be considered, but for convenience of description, it will be expressed as extending in two directions of the X axis and the Y axis in the drawing.

Here, the adjacent unit reflection units 20a are configured to share one connection surface reflection unit, and thus may be extended in the biaxial direction. Accordingly, one unit reflection unit 20a may be configured to share one of the first to fourth connection surface reflection units with four adjacent unit reflection units.

As a result, as a pattern is formed, the connection surface reflection unit is shared with the neighboring unit reflection units. However, it is not shared when there is no neighboring unit reflection unit such as an edge.

Figure 5 schematically shows the inflow of sunlight through the reflection member according to the position of the sun according to a preferred embodiment of the present invention.

Referring to FIG. 5 , since the unit reflective unit of the reflective member is disposed to have a hexagonal shape therein, no matter what direction the sunlight is introduced, it can reflect the sunlight downward and introduce it.

That is, regardless of whether the sun is in the east or in the west, the reflection unit may reflect sunlight and introduce it into the interior.

In addition, even when the sun is in the southernmost position, since the unit reflection unit is disposed to have an inclination θ, not only direct light but also sunlight can be reflected and introduced therein.

Hereinafter, a method of manufacturing a reflective member according to the present invention will be described.

The reflective member according to the present invention has a problem in that it is very difficult to manufacture because it has a three-dimensional pattern shape in which three-dimensional unit reflection units are continuously formed.

The present invention has derived a method for manufacturing a three-dimensional pattern-shaped reflective member by cutting and folding the plate-shaped reflective member base material so that the three-dimensional pattern-shaped reflective member can be manufactured more easily.

6 schematically illustrates a method of manufacturing a reflective member according to a preferred embodiment of the present invention.

Referring to FIG. 6 , first, a plate-shaped reflective member base material is prepared, and a bending line R and a cut-out portion C are specifically marked to distinguish each component constituting the unit reflective unit.

The bending line means a folded portion, and the cut-out means a cut portion.

When the bending line R and the cutout C are displayed as described above, the space between the bending line R and the cutout C may be specified as the connection surface reflector 210 or the unit surface reflector 220 . can

The height H of the unit surface reflector 220 may be variously changed according to design specifications.

Here, the reflective member base material may be made of a flexible material so as to be freely bent, and may be prepared by attaching a reflective film or forming a reflective coating on the base material.

And the cutout (C) is cut.

Here, the cutout C serves to separate the boundary between each connection surface reflector and the unit surface reflector.

When the cutout (C) is cut as described above, the space due to the cutout (C) is folded up and down along the bending line (R) to form a hexagon.

At this time, if the unit surface reflection unit 220 is bent while all the connection surface reflection units 210 are folded to have an inclination θ in the same direction, all connection surfaces are formed in a hexagonal shape inside the unit reflection unit 20a. A three-dimensional pattern in which the unit reflection unit 20a is continuously formed may be formed as the bottom surface of the reflection unit 210 is spread in a shape in contact with the floor.

Here, a three-dimensional pattern can be freely formed according to the length (D) of the height (H) and the cutout portion (C) of the unit surface reflective part 220, and the inclination (θ) can be variously adjusted.

When the three-dimensional pattern by the unit reflective unit 20a of the reflective member 20 is completed as described above, the reflective member 20 is cut to correspond to the size of the frame, and the cut reflective member 20 is mounted on the frame. .

Here, the cutout (C) is cut in a state in which the reflective member base material indicated by specifying the bending line (R) and the cutout (C) is cut in advance according to the size of the frame, and the bending line (R) is bent Thus, it is possible to manufacture a reflective member having a three-dimensional pattern in which the unit reflective unit 20a is continuously repeated.

When the reflective member base material is cut in advance according to the size of the frame, since the size is reduced in the process of being transformed into a three-dimensional pattern while bending the bending line (R), the connecting surface reflective part 210 is inclined in the same direction (θ) It can be cut larger than the actual frame size in consideration of the size that is reduced due to the degree of bending and bending.

In the detailed description of the present invention described above, it has been described with reference to the preferred embodiment of the present invention, but the protection scope of the present invention is not limited to the above embodiment, and those of ordinary skill in the art It will be understood that various modifications and variations of the present invention can be made without departing from the spirit and scope of the present invention.

10: frame 20: reflective member
30: upper protection panel 40: lower protection panel
50: light pipe

Claims (8)

a frame 10 formed in the opening (A) of the ceiling through which sunlight is introduced;
including a reflective member 20 mounted in the frame;
The reflective member 20 is formed such that the unit reflective unit 20a having a hexagonal empty space therein is continuously arranged to form a pattern;
The unit reflection unit 20a is
The first and second connecting surface reflectors 211 and 212 spaced apart from each other and disposed to face each other and a third spaced apart and arranged on an imaginary line orthogonal to an imaginary line connecting the first and second connecting surface reflectors and 4 connecting surface reflection units 213 and 214;
first to fourth unit surface reflection units 221 to 224 respectively connected between the first to fourth connection surface reflection units 211 to 214;
Through the four unit surface reflection parts 221 to 224 respectively connected between the first to fourth connection surface reflection parts 211 to 214 and the first to fourth connection surface reflection parts 221 to 224, a hexagonal shape inside an empty space is formed;
the first to fourth connecting surface reflectors 211 to 214 are all arranged to face the same direction and arranged to have a constant inclination θ with the floor level;
The four unit surface reflectors 211 to 214 are
It is connected from the upper end to the lower end of the connecting surface reflector and the neighboring reflector and is configured to have an inclination;
The height of the four unit surface reflectors 221 to 224 is configured to be 1/2 of the height of the connecting surface reflector, so that the height of the two unit surface reflectors is equal to the height of the connecting surface reflector, so that the position of the sun or A buried type light reflection device for natural light, characterized in that it can introduce sunlight into the interior regardless of altitude.
delete delete delete The method of claim 1,
the unit reflection unit 20a is configured to share one connecting surface reflection unit with an adjacent unit reflection unit and is extended in the biaxial direction;
One unit reflection unit (20a) is an embedded light reflection device for natural light, characterized in that it is configured to share one of the first to fourth connecting surface reflection units with four adjacent unit reflection units.
The unit reflection unit 20a having a hexagonal empty space therein is continuously arranged to form a pattern, and the buried type natural light includes a reflective member capable of introducing sunlight into the interior regardless of the position or altitude of the sun. A method of manufacturing a reflective device;
preparing a plate-shaped reflective member base material and specifying and displaying a bending line (R) and a cutout (C) to distinguish each component constituting a unit reflective unit;
cutting the cutout (C);
forming a three-dimensional pattern in which unit reflection units are continuous by folding up and down along a bending line (R) so that a space due to the cutout (C) is formed in a hexagon;
The step of forming a continuous three-dimensional pattern of the unit reflection unit
When the unit surface reflection unit 220 is bent while all the connection surface reflection units 210 are folded to have an inclination θ in the same direction, all connection surface reflection units ( forming a three-dimensional pattern in which the unit reflective unit 20a is continuously formed while the bottom of the 210 is spread in a shape in contact with the floor;
The method of manufacturing a buried type light reflection device for natural light, characterized in that the three-dimensional pattern can be freely formed by adjusting the inclination (θ), the length of the cutout (C), and the height (H) of the unit surface reflection unit 220 .
7. The method of claim 6,
The reflective member base material is
A method for manufacturing a buried type light reflecting device for natural light, characterized in that it is made of a flexible material so that it can be freely bent, and a reflective film is attached or a reflective coating is formed on a base material.
delete

Images