KR101391616B1 - Sun light for the lens block - Google Patents

Abstract

The present invention relates to a lens block for condensing sunlight. The lens block for condensing sunlight according to one embodiment of the present invention includes fixing plat modules (10); a circular lens (20) which is inserted into the insertion hole (12) of the fixing plate module (10) to be fixed, and is made of a transparent material; a center reflective coating layer (30) which reflects the sunlight; an upper reflective coating layer (50) which is formed in the uppermost part of the circular lens (20); and a protective coating layer (40) which is deposited the outside of the upper reflective coating layer (50).

Description

[0001] The present invention relates to a lens block for a solar photovoltaic device,

The present invention relates to a lens block for a sunlight collecting device, and more particularly, to a lens block for a sunlight collecting device, and more particularly to a lens block for a sunlight collecting device comprising a spherical lens having a reflective layer for separating an incident portion and a focused portion, The heat storage medium is heated by the concentration of sunlight through the heat storage medium.

Generally, solar energy generation is clean energy which has no pollution such as air pollution, noise, heat, vibration compared to other power generation, it is almost unnecessary to maintain fuel transportation and power generation facilities, It has the advantage of long lifetime of the device and easy installation.

In order to maximize the generation capacity of the solar power generation, the solar meridian direction is vertically aligned with the position of the sun and divided into a solar tracking type, a semi-tracking type, and a fixed type solar cell facility depending on the degree of change of direction Loses.

First, the tracking array is a method for maximizing the power generation efficiency of the solar power generation system. The tracking array is used to track the position of the sun through power or device manipulation so that direct sunlight of the solar panel always enters the front of the solar panel vertically. The way to go.

Such an automatic tracking type solar cell is classified into a position information programming system based on solar meridian information and an optical sensor automatic tracking system according to the type of the tracking system.

Next, a semi - tracking array system is a system in which the inclination angle of the solar cell array is changed vertically according to season or month, and generally, the array inclination angle is changed once every four seasons.

The generation amount of the above-described semi-tracking type array is about halfway between the fixed type and the tracking type, and the power generation amount is usually increased by about 20% as compared with the fixed type.

In such a power generation system, the fixed type system is most cheap and stable structure, and is widely used where there is no restriction on the installation area in the remote area.

In addition, the tracking type system has a relatively low power generation efficiency compared to the semi-fixed type, while it has a low initial installation cost,

In addition, in view of the geographical characteristics of the land, which can not be installed on the ground, a method of supplying electricity generated from solar energy to a consumer by using a building integrated photovoltaic system (BIPV) There is a limit to the shape and shape of the building, and accordingly, development of a more efficient solar concentrating technique has been continuously demanded.

Accordingly, there is a demand for a method of reducing the unit cost of the solar cell module or reducing the use area of the solar cell with respect to the same output. As a part of the method, a light focusing device for focusing the solar light and increasing the light density is incorporated A light focusing type solar cell module has been proposed.

However, in the conventional solar cell module, since the unit electric output produced per unit area increases in accordance with the focusing ratio of the apparatus, there is a problem that the unit cost of installing the unit for the electric output of the apparatus can be reduced by assembling the plate-

Accordingly, a wide space for installing the solar cell module is required, and the apparatus must be installed only in a region where the sunshine time is abundant.

In addition, since the energy for driving the solar cell module along the meridian of the sun has to use the energy produced by the solar cell module, there has been a problem in that efficiency due to energy loss is lowered.

Therefore, the present applicant has proposed a condensing device for concentrating sunlight through a plurality of condensing lenses, such as Patent Registration No. 10-1121638 (sunlight condensing device), and heating the heat storage medium to high temperature by the concentrated sunlight There is a bar.

However, the above-described invention has a problem that a case including a plurality of condenser lenses is installed in the light collecting body, which complicates assembly and configuration.

It is an object of the present invention to provide a lens block for a solar concentrator which is simple in structure and easy to install, by collecting and concentrating sunlight incident using a spherical lens.

Another object of the present invention is to provide a method of forming a mirror coating film capable of forming a mirror coating film capable of reflecting sunlight to the inside thereof on the surface of a spherical lens, Lens block.

It is still another object of the present invention to provide a structure for connecting and assembling a standardized fixed plate provided with an array of spherical lenses so that it is easy to assemble without being limited to the installation place, And to provide a lens block for an optical device.

In order to achieve the above object,

A dual stationary plate module 10 having a standardized size and having an insertion hole 12 arrayed at regular intervals;

A spherical lens 20 inserted and fixed in the fitting hole 12 of the fixing plate module 10 and made of a transparent material;

The spherical lens 20 is disposed along the center of the spherical lens 20 and is divided into an upper incident portion 21 and a lower focused portion 22. The sunlight incident through the incident portion 21 of the spherical lens 20, A central reflective coating layer (30) for reflecting the light in the direction of the light;

An upper reflective coating layer 50 provided on the upper end of the spherical lens 20 and reflecting the sunlight reflected by the central reflective coating layer 30 back to the central portion 22 of the lower lens;

And a protective coating layer 40 deposited on the outer surfaces of the central reflective coating layer 30 and the upper reflective coating layer 50.

The spherical lens 20 is integrally formed with the central reflective coating layer 30 and the protective coating layer 40 so that the spherical lens 20 is fixed to the fitting hole 12 of the fixed plate module 10 Assembly and fixing.

The central reflective coating layer 30 and the protective coating layer 40 of the spherical lens 20 are coated at positions not exposed to the outside of the fixed plate module 10, And the central portion 22 is formed by coating only the outer side of the angle at which sunlight is concentrated by the upper reflective coating film 50 on the lower portion.

In another embodiment

A dual stationary plate module 10 having a standardized size and having an insertion hole 12 arrayed at regular intervals;

A spherical lens 20 inserted and fixed in the fitting hole 12 of the fixing plate module 10 and made of a transparent material;

The sphere lens 20 is divided into the upper incident portion 21 and the lower focused portion 22 so as to surround the spherical lens 20 so as to surround the center of the spherical lens 20, A reflection member 60 having a central reflection film 61 for reflecting sunlight incident through the incident part 21 in the uppermost direction;

An upper reflective coating layer 50 provided on the upper end of the spherical lens 20 and reflecting the sunlight reflected by the central reflective layer 61 back to the central portion 22 in the downward direction of the lens;

And a protective coating layer 40 deposited on the outside of the upper reflective coating layer 50.

The central reflecting film 61 of the reflecting member 60 is provided with an uneven projection 61a for diffusing sunlight.

The reflective member 60 is integrated with the spherical lens 20 so that the upper end of the reflective member 60 is not exposed to the outside of the fixed plate module 10 and the spherical lens 20 has the incidence portion 21 thereon And only the outer side of the angle at which sunlight is concentrated by the upper reflective coating film 50 is formed.

According to the present invention having such a structure, the spherical lens can collect and concentrate incident sunlight, so that the sunlight can heat the heat storage medium to a high temperature through the spherical lens irrespective of the meridional direction of the sun .

In addition, a plurality of standardized lens blocks in which the spherical lenses are arrayed and assembled can form a light condensing device in the form of a flat plate or an eccentric shape, so that installation and assembly are easy and solar power generation efficiency is improved, It is an easy invention.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view showing a state of engagement of a lens block according to the present invention; Fig.
2 is a perspective view of a spherical lens according to an embodiment of the present invention.
3 is a cross-sectional view showing the refraction state of sunlight through the spherical lens of FIG. 2;
4 is an exploded perspective view of a spherical lens according to another embodiment of the present invention.
FIG. 5 is a sectional view showing the refraction state of sunlight through the spherical lens of FIG. 4;
6 is a schematic view of an electric power generating system using a lens block according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

The lens block for a sunlight collecting device of the present invention includes a spherical lens having a reflecting layer for separating an incident portion and a focused portion and arranging the blocks in which the spherical lenses are arranged, .

Here, the spherical lens 20 may be made of a heat-resistant material which can withstand high temperatures and is excellent in transparency, such as a glass, a ceramics, an alloy coated with ceramics, silicon carbide, alumina, a special kind of stainless steel, It is good to use it.

1, a spherical lens 20 is assembled to a fitting hole 12 of a fixing plate module 10, and solar light incident on the spherical lens 20 is mounted on a fixing plate module 10 And then heated to a high temperature.

To this end, the present invention combines flat plate modules 10 having a double-layered plate module 10 having a fit hole 12 and having a standardized size and width, in a flat or smooth manner.

2, a spherical lens 20 having a transparent material is assembled into a fitting hole 12 of the fixed plate module 10, and the spherical lens 20 is disposed on the center reflective coating film 30 is deposited on the upper surface of the coating film to form an incidence portion 21 on the upper side of the coating film and a concentration portion 22 on the lower side.

Therefore, the sunlight is incident through the incident portion 21 of the spherical lens 20, and is reflected in the uppermost direction inside the lens.

The upper reflective coating film 50 is deposited on the uppermost part of the spherical lens 20 and the sunlight reflected on the central reflective coating film 30 is again reflected back to the concentrated area 22 in the downward direction of the lens.

The protective coating layer 40 having a high rigidity is further deposited on the outer surfaces of the central reflective coating layer 30 and the upper reflective coating layer 50 to protect the inner reflective coating layer from being scratched or damaged.

The central reflective coating layer 30 and the upper reflective coating layer 50 are vacuum deposited on the outer surface of the spherical lens 20 to provide a mirror effect that looks like a mirror when viewed from the inner surface of the lens, The metal material is selected from metal materials such as silver (ag), tungsten (w), and aluminum (al) having excellent sharpness and high reflectance.

The central reflective coating layer 30 and the upper reflective coating layer 50 may increase their coating thickness in comparison with scratches themselves. However, this increases the material cost. Therefore, after the metal coating, A protective coating 40 is further deposited on the top of the central reflective coating 30 and the top reflective coating 50 to protect the coating.

The protective film 40 of the spherical lens 20 is inserted into the fitting hole of the fixing plate module 10 in a state where the central reflective coating layer 30 and the protective coating layer 40 are integrated, 12).

At this time, the central reflective coating 30 and the protective coating 40 of the spherical lens 20 are coated to a position that is not exposed to the outside of the fixed plate module 10, and the spherical lens 20 is coated thereon, And the central portion 22 is formed by coating only the outer side of the angle at which sunlight is concentrated by the upper reflective coating film 50 on the lower portion.

The central reflective coating 30 coated on the center of the spherical lens 20 is protected from scratches by the protective coating 40 so that the coating thickness of the central reflective coating 30 can be very thinly coated The reflectance of the central reflective coating 30 can be further improved by the dark color of the protective coating 40.

When the spherical lens 20 integrally coated with the central reflective coating layer 30 and the protective coating layer 40 is assembled into the fitting hole 12 of the fixing plate module 10, The upper and lower portions of the coating film of the spherical lens 20 are fixed.

 That is, the protective coating 40 deposited on the spherical lens 20 prevents the spherical lens 20 from being scratched during assembly and fixing of the spherical lens 20 to the fitting hole 12, It is possible to prevent the sphere lens 20 from being moved or moved by fixing the lens barrel 20 up and down.

4, a reflective member 60 is separately provided so as to surround the center of the spherical lens 20 formed of a transparent material. Inside the reflective member 60, The spherical lens 20 is inserted and fixed.

The reflecting member 60 has a protective film 62 on the outer surface and a central reflecting film 61 for reflecting sunlight on the inner surface of the reflecting member 60. The spherical lens 20 is attached to the reflecting member 60, The spherical lens 20 is divided into the upper incident portion 21 and the lower focused portion 22 and the sunlight incident through the incident portion 21 is reflected in the uppermost direction.

The upper reflective coating film 50 is deposited on the uppermost part of the spherical lens 20 and the sunlight reflected on the central reflective film 61 is again reflected back to the central part 22 in the downward direction of the lens.

Further, a protective coating layer 40 having a high rigidity is further deposited on the outer surface of the upper reflective coating layer 50 to protect the reflective coating layer from being scratched or damaged.

In addition, the central reflecting film 61 of the reflecting member 60 is formed with the irregular projections 61a as a whole, so that incident sunlight can be diffusedly reflected.

The reflecting member 60 may be assembled and integrated with the spherical lens 20 so that the upper end of the spherical lens 20 is not exposed to the outside of the fixing plate module 10 during the assembly process, And an upper portion of the upper reflective coating film 50 is positioned only to the outside of the angle at which sunlight is concentrated.

The traveling path of the sunlight using the lens block thus constructed will be described with reference to FIGS. 1 to 6. FIG.

First, a plurality of standardized fixed plate modules 10 constituting a lens block are fixed to the upper surface of a ground by connecting and combining them, and it is preferable to configure such that the body is not shaken, or snow and foreign substances are not accumulated in a natural environment such as strong wind Do.

Particularly, the fixing plate module 10 of the present invention has side walls 11 formed along the periphery of the body so that when the fixing plate module 10 is assembled, the side walls 11 come into contact with each other and are firmly fixed And the fixing plate having the fitting holes 12 on the same line on the upper and lower sides is formed in a double structure so that the spherical lens 20 assembled to the fixing plate module 10 is double fixed to prevent the lens from flowing .

It is noted that the shape of the fixing plate module 10 can be formed by a module having a width of three to six angles in order to configure the flat plate or the curved shape.

Solar light is incident on the incidence portion 21 of the spherical lens 20 when sunlight shines through the spherical lens 20 mounted on the fixed plate module 10 regardless of the position of the sun.

3, the incident sunlight is reflected by the upper reflective coating layer 50 in the central reflective coating layer 30 coated along the center of the spherical lens 20, and the upper reflective coating layer 50 The light is redirected to the central portion 22 in the lower direction of the spherical lens 20.

Accordingly, the sunlight passing through the central portion 22 is refracted according to the lower shape of the spherical lens 20, and the sunlight is focused in the lower direction of the fixed plate module 10, The medium H is heated to a high temperature state.

4, incident sunlight is reflected from the central reflection film 30 coated along the center of the spherical lens 20 to the upper reflective coating film 50 And is reflected from the upper reflective coating film 50 to the central portion 22 in the lower direction of the spherical lens 20.

At this time, the irregular projections 61a formed on the central reflection coating layer 61 irregularly reflect incident sunlight. However, the irregularly reflected solar light is refracted by the other irregular projections 61a and reflected by the upper reflection coating layer 50 And is reflected from the upper reflective coating film 50 to the central portion 22 in the lower direction of the spherical lens 20, thereby increasing the amount of light.

Accordingly, the sunlight passing through the central portion 22 is refracted according to the lower shape of the spherical lens 20, and the sunlight is focused in the lower direction of the fixed plate module 10, The medium H is heated to a high temperature and the sunlight of a large capacity can be condensed compared to the size of the spherical lens 20 so that a small condenser can generate a large amount of solar energy, It can save.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It will be clear to those who have.

10 - fixed plate module 20 - spherical lens
21 - Incident part 22 - Concentrated part
30 - Central reflective coating 40 - Protective coating
50 - upper reflective coating 60 - reflective member
61 - Central reflection film 61a -
62 - Shield

Claims (6)

A dual stationary plate module 10 having a standardized size and having an insertion hole 12 arrayed at regular intervals;
A spherical lens 20 inserted and fixed in the fitting hole 12 of the fixing plate module 10 and made of a transparent material;
The spherical lens 20 is disposed along the center of the spherical lens 20 and is divided into an upper incident portion 21 and a lower focused portion 22. The sunlight incident through the incident portion 21 of the spherical lens 20, A central reflective coating layer (30) for reflecting the light in the direction of the light;
An upper reflective coating layer 50 provided on the upper end of the spherical lens 20 and reflecting the sunlight reflected by the central reflective coating layer 30 back to the central portion 22 of the lower lens;
And a protective coating layer (40) deposited on the outside of the central reflective coating layer (30) and the upper reflective coating layer (50).
The spherical lens 20 is formed by integrating the central reflective coating layer 30 and the protective coating layer 40 so that the spherical lens 20 is fixed to the fitting hole 40 of the fixed plate module 10 12. The lens block for a solar photovoltaic device according to claim 1,
The spherical lens 20 is coated on the center reflective coating layer 30 and the protective coating layer 40 of the spherical lens 20 at positions not exposed to the outside of the fixing plate module 10, And the upper reflective coating layer (50) is coated only on an outer side of an angle at which sunlight is concentrated by the incident reflective layer (21).
A dual stationary plate module 10 having a standardized size and having an insertion hole 12 arrayed at regular intervals;
A spherical lens 20 inserted and fixed in the fitting hole 12 of the fixing plate module 10 and made of a transparent material;
The sphere lens 20 is divided into the upper incident portion 21 and the lower focused portion 22 so as to surround the spherical lens 20 so as to surround the center of the spherical lens 20, A reflection member 60 having a central reflection film 61 for reflecting sunlight incident through the incident part 21 in the uppermost direction;
An upper reflective coating layer 50 provided on the upper end of the spherical lens 20 and reflecting the sunlight reflected by the central reflective layer 61 back to the central portion 22 in the downward direction of the lens;
And a protective coating layer (40) deposited on the outside of the upper reflective coating layer (50).
The lens block for a solar photovoltaic device according to claim 4, wherein a central reflecting film (61) of the reflecting member (60) is provided with an uneven protrusion (61a) for diffusing sunlight.
The spherical lens 20 is disposed on the incident portion 21 so that the upper end of the spherical lens 20 is not exposed to the outside of the fixed plate module 10, And a lower portion of the lens block is formed only to an outer side of an angle at which sunlight is concentrated by the upper reflective coating layer.

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