KR101585514B1 - A day-light apparatus - Google Patents

Abstract

It is easy to mount main mirror (or primary mirror) and secondary mirror (or secondary mirror), and it is convenient to adjust the position of optical fiber and reflectors when installing the solar light device, A solar light illuminating apparatus has a merit that a large amount of light can be used as illumination under the same conditions by a reflector structure in which light reflected from a secondary reflector is efficiently transmitted to an optical fiber.

Description

A day-light apparatus

The present invention relates to a solar light illuminating apparatus, and more particularly, to a sunlight illuminating apparatus which can precisely adjust a position of a secondary reflector for receiving light from a primary reflector, The present invention relates to a solar light illumination device having a structure.

The solar lighting device refers to a device that uses solar light as natural light by guiding the sunlight to a place where sunlight does not easily reach, such as an indoor space or a basement inside the building.

This method is more advantageous than the fixed-type solar lighting device capable of passively acquiring only the sunlight incident on the mining section at a specific angle in that the sun can positively acquire the sunlight as long as it is located in the cenosphere Have.

The minerals for obtaining the sunlight are usually made of a method using a lens and a method using a reflecting mirror. Here is a typical example of a mirror. That is, the main mirror condenses incident sunlight into a spot of a predetermined size, and the auxiliary mirror located at a predetermined distance from the central portion of the main mirror reflects the sunlight reflected from the main mirror, The optical fiber formed in the central portion receives sunlight and transmits it to the illumination space (indoor space).

It is very difficult to equip the structure with the same dimensions as the designed dimensions because of the speciality of the solar lighting system installed outdoors when performing the construction to adjust the spacing between the main mirror and the auxiliary mirror. That is, it is easy to mount the main mirror (or primary mirror) and the secondary mirror (or secondary mirror), and a device capable of adjusting the distance between the two mirrors has been proposed.

Also, we propose a reflector structure for transmitting the light reflected from the secondary reflector to the optical fiber efficiently, and a shape of the primary reflector for maximizing the amount of reflected light due to the installation of a plurality of primary reflectors.

Registered Patent No. 10-1188515 (filed on April 4, 2012)

The present invention proposes a device capable of easily adjusting the distance between the main mirror (or primary mirror) and the auxiliary mirror (or secondary mirror), and at the same time, the light reflected from the secondary mirror is effectively transmitted to the optical fiber And a shape of a primary reflector for maximizing the amount of reflected light due to the installation of a plurality of primary reflectors.

A primary reflector (200) that reflects sunlight and is formed as a part of a parabolic surface;

A secondary reflector 400 formed as a part of a spherical surface formed at a focus position of the primary reflector;

An optical fiber 700 formed at a center position of the secondary mirror;

A conical reflector 500 formed at the end of the optical fiber and receiving the bundle;

And a member for displacing and fixing the secondary mirror in a vertical direction (V1, V2), a direction (H1, H2) and a horizontal direction (S1, S2) connected to the center of the primary reflector,

The cone-shaped reflector includes a rectilinear section (500b) that receives a bundle of optical fibers and an inclined section (500a) that is an inclined plane.

The end of the optical fiber is positioned so that the end of the optical fiber is equal to the height corresponding to the surface of the primary reflector 200. In this case,

The secondary reflector is mounted on the center of the secondary reflector base 322 formed around the secondary reflector and includes a second secondary support 320 and a secondary reflector base 322 disposed in parallel with the secondary reflector base Are connected to each other by a plurality of distance adjusting bolts 355 and a distance adjusting spring 350 is formed on the outer circumference of the distance adjusting bolt 355.

The first auxiliary supporter 310 is coupled to the second auxiliary supporter 320. The first auxiliary supporter 310 is provided with an arc-shaped hole 319 having a longer side than the height of the hole, And a pivoting hole 318 is further formed under the arcuate hole. The pivoting bolt 316 is inserted into the pivoting hole so that the first auxiliary support can be rotated about the bolt 316 by a predetermined angle in the left or right direction and then the first auxiliary support can be fixed The secondary reflector support 300 is coupled to the first auxiliary support 310 and the secondary reflector 300 is coupled to the vertical support 306. The secondary reflector support 300 includes a vertical groove 306, Is formed to be larger than the interval length between the pivoting hole 318 and the arcuate hole 310 so that the position of the secondary reflector can be adjusted.

It is easy to mount main mirror (or primary mirror) and secondary mirror (or secondary mirror), and it is convenient to adjust the position of optical fiber and reflectors when installing the solar light device, The time and the working distance are reduced, and the reflector structure for transmitting the reflected light from the secondary reflector to the optical fiber effectively has a merit that a large amount of light can be used as illumination under the same condition.

1 is a perspective view of a solar light illumination apparatus
Fig. 2 is a photograph showing an actual photograph taken from the front view of Fig. 1 and a diagram for explaining the excellentness of the light collection efficiency of the primary reflector shape
3 is a side sectional view showing a schematic configuration of the present invention
4 is a view showing the positional relationship between the primary and secondary reflectors and the members for mounting the secondary reflector;
5 is an exploded perspective view of a telescopic device 600
Fig. 6 is a side view of Fig. 5
Fig. 7 is a view of the telescopic device with the reflector removed in Fig. 6,
8 is a view for explaining the coupling degree of the mounting member of the secondary reflector and the mounting method by moving the auxiliary support vertically and horizontally;
9 is an exploded view
10 is a photograph of a secondary reflector and a mounting member product

Preferred embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a perspective view of a solar light illuminating device, FIG. 2 is a photograph for explaining the light-condensing efficiency by the primary reflector shape, and FIG. 3 is a side sectional view showing a schematic configuration of the present invention Fig. 4 is a view showing the positional relationship between the primary and secondary reflectors and the members for mounting the secondary reflector. Fig. 5 is an exploded perspective view of the telescopic device 600, Fig. Fig. 7 is a view showing a state in which the reflector is removed in Fig. 6 and a view for explaining the operation of the telescopic device in Fig. 5, and Fig. 8 is a view for explaining the operation of the telescopic device in Fig. Fig. 9 is an exploded perspective view of Fig. 8, and Fig. 10 is an actual photograph of the secondary reflector and the mounting members.

Referring to FIGS. 1 and 2, the solar light illumination apparatus of the present invention is installed in an outdoor space, so that a closed housing 100 is formed and installed, a transparent front panel 120 is formed in a front part thereof, A first reflector 200 for receiving and reflecting light firstly and a second reflector 200 for receiving the light reflected from the primary reflector and transmitting the sunlight to the end of the optical fiber 700 formed at the center of the primary reflector 200 And includes a car mirror 400.

FIG. 2 is a photograph taken at the front of the front panel 120 of FIG. 1, in which three primary reflectors 200 are formed such that the outer edge portions thereof are adjacent to each other. A support base 300 is formed on the front surface of each primary reflector. The support base 300 is provided with a secondary reflector 400 corresponding thereto.

FIG. 3 is a diagram showing a positional relationship between the primary reflector 200 and the secondary reflector 400 as viewed from the side. The sunlight is reflected by a primary reflector formed in an elliptical shape, Collides with the secondary reflector 400 formed at the corresponding place, and is transmitted to the inside of the optical fiber 700 installed on the front surface of the secondary reflector. The secondary reflector has a shape corresponding to a part of a spherical surface.

The light transmitted through the optical fiber is used for illumination of the room after the total reflection process. In FIG. 3, the cone-type reflector 500 is not shown at the end of the optical fiber, but a cone-type reflector must be provided.

The cone-shaped reflector acts to effectively converge and move the light reflected from the secondary reflector 400 toward the optical fiber 700. The side surface of the cone-shaped reflector 500 is made similar to the side surface of the cone, and the tilted angle of the side surface with respect to the horizontal line is preferably formed within a range of 5 degrees to 15 degrees. However, such an angle is not necessarily limited to a certain value since it depends on the size of the first and second reflectors and the mutual linear distance.

It is preferable that the primary reflector 200 is coated with nickel and the secondary reflector is coated with aluminum, but it is not limited to these materials. As shown in the right side of FIG. 2, the primary reflecting mirrors are preferably formed in a shape of a quadrangle-like shape, that is, an octagonal shape in which corner portions 280 (FIG. 2, right side) are rounded.

2 shows a case where a primary reflector shape is formed in a circular shape when viewed from the front. In this case, it is not preferable because there is a loss in light receiving area, and the shape shown in the lower left figure in FIG. Shape.

As shown in FIG. 4, the primary reflector 200 has a curved surface corresponding to the parabolic surface as a whole, and a telescopic device 600 is formed toward the secondary reflector in the central portion, and a cone- have.

As shown in FIG. 6, the cone-shaped reflection angle 500 has a shape in which an inclined portion 500a such as a side wall shape and a pipe-shaped straight portion 500b having a predetermined diameter formed at the end of the inclined portion are combined .

In the linear portion 500b, an optical fiber is closely inserted therein. Positioning the end of the optical fiber such that the end position of the optical fiber is equal to the height corresponding to the surface portion of the primary reflector 200 efficiently converges the light transmitted from the secondary reflector.

The telescopic device 600 of FIG. 4 is formed by interconnecting the plurality of members of FIG. 5 and may be of varying length, such as a telescope.

This is a device for adjusting the distance between the cone-shaped reflector 500 and the secondary reflector 400. The telescopic device includes first to third optical fiber supports 610, 620, and 630 in the shape of a straight pipe, and is movable back and forth as shown in FIG.

A thread is formed at the end of the third optical fiber support so that it can be coupled with the support nut 650 at the rear of the primary reflector 200. Since the telescopic structure is a known structure, detailed description is omitted. While the holder 640 serves to receive and guide the outside of the second fiber optic support.

Hereinafter, the secondary reflector formed on the front surface of the primary reflector of FIG. 4 and the members for mounting the secondary reflector will be described in detail.

The apparatus for placing the secondary reflector shown in the left side of FIG. 8 can operate the secondary reflector 400 in the primary reflector direction (H1 direction) or in the opposite direction (H2 direction) (V1 and V2 directions), and the secondary mirror can also be moved in the left and right directions (S1 and S2 directions).

This operation is very useful in real-time installation of the solar light device in order to allow the light reflected from the primary reflector to be reflected back to the secondary reflector and then transmitted to the end of the optical fiber as much as possible.

Referring to Figs. 4 and 9, the members provided with the secondary reflector will be described.

The secondary reflector is formed as a part of a spherical shape, and a secondary reflector cover 410 is disposed around the secondary reflector. The secondary reflector and the secondary reflector cover are mounted at the center of the secondary reflector base 322. The second secondary support 320 and the secondary reflector base 322, which are arranged in parallel with the secondary reflector base, And a distance adjusting spring 350 is formed on the outer circumference of the distance adjusting bolt 355. [

That is, as the distance adjusting bolt 355 is fastened, the distance adjusting spring is compressed.

Fix the distance adjustment bolt at the desired position. At this time, while maintaining a gap between the second auxiliary support and the second reflector base, flow is prevented and elasticity is exerted in both directions. This operation relates to the adjustment of the distance in the H1 and H2 directions in the left figure of Fig.

Next, referring to the right picture of FIG. 8, the downward movement and the leftward / rightward movement of the secondary reflector will be described.

The lower portion of the second auxiliary support 320 is coupled to the first auxiliary support 310.

The first auxiliary support 310 has a circular arc-shaped hole 319 formed in a circular arc shape longer than a height thereof, and a pivoting hole 318 is formed in a lower portion of the arc-shaped hole.

The pivoting hole 318 and the arc-shaped hole 319 are used to move the first auxiliary support 310 in the S1 and S2 directions of the right side of FIG.

That is, the pivoting bolt 316 is inserted into the pivoting hole so that the first auxiliary support can be rotated around the bolt 316 in the left or right direction by a predetermined angle, and then the first auxiliary support can be fixed. The right side view of FIG. 10 is a photograph of the state in which the first assistant is slightly inclined and fixed. This fixing is very useful in a situation in which the secondary mirror 400 is adjusted in the left and right directions S1 and S2.

At this time, the secondary reflector support 300 is provided with a vertical groove 306 formed in a vertically elongated shape, and the secondary reflector support 300 is coupled with the first auxiliary support 310.

The rectilinear groove 306 should be larger than the distance between the pivoting hole 318 and the arcuate hole 310. In this case, the lower portion of the rectilinear groove 306 is partially exposed Has been recognized.

In order to adjust the installation height of the secondary reflector, it is possible to move the height of the first auxiliary support 310 in the V1 and V2 directions and then fix the rotation fixing bolt and the pivoting bolts 315 and 316 with the nuts 373 and 372, respectively . (The dotted line in the right picture of FIG. 8 is an enlarged view of the left picture)

Since the relative positions of the first and second reflectors and the optical fiber are very important for the light collecting efficiency of the sunlight, these devices are very useful when the first solar light illuminating device is installed. In addition, since the solar light illuminating device is installed outdoors, There is a problem in maintenance that the relative positions of the first and second reflectors must be corrected after the first installation, which is a structure that can be used effectively in this case.

100: housing 110: side cover
120: front panel 200: primary reflector 280: corner portion
300: Secondary reflector support
306: vertical groove 310: first auxiliary support
315: rotation fixing bolt 316: pivoting bolt
318: Pivoting hole 319: Circular hole
320: Second auxiliary support 322: Secondary reflector base
350: Distance adjusting spring 355: Distance adjusting bolt
400: Secondary reflector 410: Secondary reflector cover
500: cone type reflector 600: telescopic device
610: first optical fiber support
620: second fiber optic support
630: third fiber optic support
640: holder 650: support nut 700: optical fiber

Claims (4)

A primary reflector (200) that reflects sunlight and is formed as a part of a parabolic surface;
A secondary reflector 400 formed as a part of a spherical surface formed at a focus position of the primary reflector;
An optical fiber 700 formed at a center position of the secondary mirror;
A conical reflector 500 formed at the end of the optical fiber and receiving the bundle;
And a member for displacing and fixing the secondary mirror in a vertical direction (V1, V2), a direction (H1, H2) and a horizontal direction (S1, S2) connected to the center of the primary reflector,
The cone-shaped reflector includes a rectilinear section (500b) that receives a bundle of optical fibers and an inclined section (500a) that is an inclined plane,

In the linear portion 500b, an optical fiber is closely inserted therein
The end position of the optical fiber is positioned so that the end of the optical fiber is equal to the height corresponding to the surface portion of the primary reflector 200,

The secondary reflector is mounted at the center of the secondary reflector base 322 formed around the secondary reflector,
The second auxiliary support 320 and the secondary reflector base 322 disposed in parallel with the secondary reflector base are mutually connected by the plurality of distance adjustment bolts 355,
And a distance adjustment spring 350 is formed on the outer periphery of the first spring 355,
Solar light equipment.

The method according to claim 1,
A first auxiliary support 310 is coupled directly under the second auxiliary support 320,
The first auxiliary support 310 is formed with an arc-shaped hole 319, which is a groove formed in the shape of an arc longer than the height of the hole,
A pivoting hole 318 is further formed in the lower part of the arcuate hole,
The pivoting bolt 316 is inserted into the pivoting hole so that the first auxiliary support can be rotated about the bolt 316 by a predetermined angle in the left or right direction and then the first auxiliary support can be fixed ,
The secondary reflector support 300 is provided with a vertical groove 306 which is elongated in the vertical direction. The secondary reflector support 300 is coupled to the first auxiliary support 310,
The rectilinear groove 306 is formed to be larger than the distance between the pivoting hole 318 and the arcuate hole 310
Solar light equipment.

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