KR101162723B1 - Soalr heat collecting system using flat refractive lens - Google Patents

Abstract

PURPOSE: A solar heat collection apparatus using flat refractive lenses is provided to effectively obtain solar heat by concentrating focus points of the lens on a heat collector using a mirror. CONSTITUTION: A solar heat collection apparatus using flat refractive lenses comprises an image frame, a plurality of mirrors(300), and a heat collector(400). The image frame supports a plurality of the flat refractive lenses. The plurality of mirrors is installed at the lower side of a center vertical line(61) of the flat refractive lenses. The plurality of mirrors adjusts the angle of incident sunlight(62) passing through the flat refractive lenses before focus points are formed. The heat collector concentrates the focus points of the flat refractive lenses. The heat collector is installed in the lower center area of the flat refractive lenses.

Description

Solar heat collector using flat refractive lens {SOALR HEAT COLLECTING SYSTEM

The present invention is a technology of fastening a solar tracker to a tracker to track the sun and collecting the light at a high temperature, and incidence of each lens using a plate refractive lens (fresnel lens), a collector (collector), and a mirror (reflector). It is a technique of the principle of focusing each focus on the central four-sided collector of four lenses by breaking the sunlight that is incident midway before the light becomes the focal point.
One unit combined with the technique of the above principle is a basic technical product.
If a large number of the technical products (1 unit) is concluded, more efficient efficiency can be obtained, and the obtained strong heat is stored in the heat storage tank. CO ₂ , which produces hot water and heating electricity, greatly increases energy efficiency without generating any leading edge. New concept Improved Eco-friendly renewable energy.

It has been used as a flat plate collector, a vacuum tube collector, a fixed collector type collector, etc. which obtain general solar heat, and is fastened to components such as an absorber plate, a transmitter, a reflector, and a collector.
However, the constituents composed of these are less efficient in collecting heat compared to the area, and do not meet the recovery of the installation cost and the installation cost is not easy to respond very poorly.

It is an object of the present invention to solve the weak heat of the solar system of the past is not generalized because it is weak to be applicable to heating, hot water and the like, and specifically, to form a flat refractive lens to be more efficient and practical It is to provide a solar heat collecting device using a planar refraction lens that can focus on the heat collector using a rear mirror to obtain strong heat and use high heat energy.
Another object of the present invention is to provide a solar heat collecting apparatus using a flat refraction lens which does not generate carbon dioxide at all.
In addition, by incorporating the technology of my patent application 10-2011-0106XXX with excellent heat in use and excellent convenience to develop to meet the energy of humanity and carbon dioxide (CO ₂ ) is not generated at all.

In the present invention, in order to solve the problems of the past, as a single flat refractive lens had a heat that can melt the glass (sky copulation experiment results) by combining four lenses, one focus four times further improved It is able to boil water with unlimited technology and obtain unlimited capacity, which is a combination of solar tracker, flat refractive lens, mirror (reflector), and quadrangular heat collector, and it can solve the problems of the past. have.
The object is provided in the image frame for supporting a plurality of flat plate refractive lenses, respectively provided below the center vertical line of the plurality of flat plate refractive lenses to reflect the sunlight passing through the plurality of flat plate refractive lenses, respectively, to allow angle adjustment. A plurality of mirrors; And a heat collecting body provided in the lower center area of the entire of the plurality of flat refraction lenses to concentrate the sunlight reflected from the plurality of mirrors, wherein the heat collecting body includes a heat medium inlet and a heat medium into which the heat medium is introduced; The heat medium is discharged and has a black coated pipe shape, and the sunlight concentrated through the heat collecting body via the plurality of plate refraction lenses and the plurality of mirrors causes the heat medium flowing along the inside of the heat collecting body. It is achieved by a solar heat collecting apparatus using a flat plate refractive lens to heat.
The flat refractive lens and the mirror are each provided in four, the collector is formed in a quadrangular pipe shape, the surface of the collector is carbon coated, the focus of each of the sunlight reflected through the four mirrors The collectors may be arranged such that the respective surfaces face the four mirrors 300 so as to be concentrated on corresponding ones of four surfaces of the four-pipe collector.
A tracker is formed by connecting an upper frame and a lower plate frame on which the plurality of flat refraction lenses are installed, and an ade supporting a plurality of flat refraction lenses is fastened to the upper frame, and a solar tracker is fastened to the tracker. By concentrating the focus of the flat plate refractive lens on the heat collector, the heat medium passing through the heat collector may be boiled and stored in the heat storage tank.

The present invention is a large flat refractive lens, the focus is clear and the heat of focus is strong.
The fastening of the material is light in weight and effective in the production process compared to the efficiency.
The mirror is used to focus the lenses on the central quadrilateral collector to obtain high heat by focusing the lenses to achieve a great effect.
The collection of focus of the flat refractive lenses is highly effective.
In addition, by tracking the sun by fastening the solar tracker with a combination of components such as aluminum, plate refractive lens, collector, mirror, the efficiency is much more excellent.
The present invention has the effect that CO ₂ does not occur all the way.
Combination made of the above technology is fastened in the embodiment, the more the efficiency and capacity in proportion to increase the effect of the invention.
The high temperature of the final heat storage has the effect that can be used hot for about 5 days to the maximum warming measures.

1 is a perspective view showing a solar heat collecting device using a plate refractive lens according to an embodiment of the present invention.
2 is a plan view illustrating a solar heat collecting device using a plate refractive lens according to an embodiment of the present invention.
3 is a perspective view showing a heat collector of the solar heat collecting apparatus using the flat refraction lens according to the embodiment of the present invention.
4 is a view showing a path from the solar heat collecting apparatus using a plate refractive lens according to an embodiment of the present invention is transmitted to the heat collector after the reflection of the sunlight passing through one plate refractive lens to the mirror.

Hereinafter, with reference to the accompanying drawings will be described a preferred configuration and operation of the present invention for achieving the above object.
1 is to focus the light through the flat refractive lens at a suitable distance about halfway before focusing the reflection angle of the mirror to focus the collector to focus the focus of the flat refractive lens to the heat collector It is a figure explaining the thing. Specifically, FIG. 1 shows the bending of sunlight (sunlight) passing through the lens of the flat refractive lens a and the flat refractive lens d at a perspective angle. The flat refractive lens c and the flat refractive lens b follow the same explanation.
In detail, the description is to focus the focus of each flat-lens refraction lens to focus the strong heat of the focus on the heat-collecting body by using the flat-lens refraction lens fastened to the image tracker and the reflection of the heat collector and the mirror (angle can be adjusted). The angle of this figure is not prescribed | regulated as an angle for description. As shown in FIG. 4, the most ideal angle is ideally bent at a right angle of 90 ° about the middle of the center vertical angle of incidence.
In addition, in FIG. 1, both angles of bending of sunlight should be the same, and the angles of 60 ° on both sides of the drawing are for explaining that both angles are the same since the heat collector in the center of the four flat refractive lenses is viewed as a perspective angle. As shown, the actual angle of inclination is the angle of incidence of the angle of incidence of the flat refraction lens to 90 °, and the angle of both sides with the mirror is 45 °, which is the ideal angle. The angle of 90 ° is the most preferred angle, not the prescribed angle.
FIG. 2 is a plan view of fastening four flat refraction lenses with a tracker and affixing the letters a, b, c, and d for the following description.
The collector 400 is also changed up and down according to the angle, and the size and focal length of the flat refraction lens 200 are formed as needed. Any of the flat refraction lenses 200 can be used, and the phrase lens is a flat refraction lens. It is an abbreviated phrase and the collector can be used to change the size and shape as needed.
3 is a view showing the heat collecting body 400, and in detail, the low temperature heat medium inlet 401 in fastening the earth (black) coated metal quadrangular pipe heat collecting body 400 having heat medium inlets and outlets 401 and 402. And a high temperature heat medium outlet 402 is provided. Here, the heat medium may include water.
The collector 400 has four earthy colors and is configured to contact each surface facing the focal points of the flat refractive lens 200.
The collector 400 has an object of further increasing efficiency by concentrating strong heat to the collector 400 having the lens focus of the four lenses 200 a, b, c, and d.
FIG. 4 is a diagram for explaining in detail one of four flat refractive lenses of FIG. 2. 4 is a planar refraction lens (fresnel lens) having a refraction and focus on the flat plate as shown in the above figure. 4 is a view for explaining the relationship between the plate refractive lens, the mirror, the heat collector of the four-pipe shape.
The present invention is provided with a flat refractive lens (200, Fresnel lens) and the angle adjustable mirror 300, the flat plate refractive on the earth-coated four-square metal pipe collector 400 having the inlet, outlet (401,402) The lens 200 is a breakthrough technology for obtaining solar energy of a new concept green energy that collects solar heat of focus.
The present invention has been developed to be more efficient and practical beyond the scope of products as mentioned in the prior art. The solar tracker is fastened to the tracker to focus the focus of the flat refractive lens 200 on the central collector 400 using the mirror 300. Specifically, four flat plate refractive lenses 200 are configured in the upper frame 100 as shown in FIG. 2, and a black plate collector 400 having a black coating is disposed between the bottom of the center and the bottom plate of the four flat plate refractive lenses. (79) Fasten the mirror 300 (reflector) centering on the incident angle optical axis of sunlight passing through the central portion and passed through each of the flat refraction lenses 200. The incident light 63 passing through each of the planar refraction lenses 200 was broken to focus the incident light 63 facing each surface of the heat collector 400 having black coating on each side, thereby greatly improving the efficiency of generated heat. The efficiency is maximized by collecting 4 times the scattered heat.

Again, FIG. 1 is an image tracker fastening four flat refractive lenses 200 to apply the technique of the present invention, and fastening the quadrangular heat collecting body 400 coated black under the center of four flat refractive lenses 200. In addition, the mirror 300 having the support is fastened to the lower plate 79 of the center refraction lens 200 to adjust the focus 64 of each plate refraction lens 200 by using the mirror 300. . The sunlight (sunlight) passing through the planar refraction lens 200 is adjusted to the mirror 300 at an intermediate point before reaching the focal point 64, and then focuses on an appropriate surface of the heat collector 400 facing each other. Focus. a the focus of the flat refractive lens on the 404 surface of the heat collecting body 400, the b of the flat refractive lens on the opposite back surface of the surface 406 of the heat collecting body 400, c the focus of the flat refractive lens is the heat collecting body 400 On the 406 plane, the focal point of the d flat refraction lens reaches the 405 plane of the heat collecting body 400 and maximizes the efficiency by angularly adjusting each focal point to the plane facing the lens.
In the above implementation, the four-coated black coated collector 400 can further increase the efficiency and maximize the efficiency by tracking the solar tracker whenever there is sunlight.
In the present embodiment, Fig. 1 is a representative view illustrating only the c flat refraction lens and the d flat refraction lens as a front view having a slight perspective angle.
In addition, the distance of 63G and 60M are the same depending on the angle, but the distance varies according to the angle.
Accordingly, the collector may also be changed up and down.
Alternatively, the size and focal length of the flat refraction lens are formed as needed, and anything made of flat refraction lenses can be used as a shared product.

FIG. 2 illustrates a frame 100 configured to apply the technique of the present invention and includes an intermediate ade 103 in a frame capable of mounting four flat refractive lenses 200, including the center between the frames 100. ) And fasten the flat refraction lens 200 to each of them to help explain by attaching alphabetical symbols of a, b, c, and d. The numbers on the solid lines of the arrows are numbers for explanation.

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By collecting multiple foci of wide flat refraction lenses into the heat collector 400, it is possible to obtain a very strong heat energy. It is an essential product anywhere in the world as well as in Korea. The production process is simple and the production cost is low. We look forward to green energy innovation.
In the use of the above technology, water and the like are introduced into the low temperature inlet 401 of the heat collector 400 having the inlets and outlets 401 and 402 as the component combinations of FIGS. 1, 2, 3, and 4, The water boils through the binder path and the water boiled through the plurality of heat collectors is stored in the heat storage tank through the outlet.
When using high temperature water in the tank by combining the technology of my patent application 10-2011-01061XX in the use of the use of the above technology, the water is filled when boiled, and when it is harmless, the cold water does not enter all the time and always maintains high temperature It's a system project.
In the present invention, four flat plate refractive lenses 200 with focus are composed of fastening trackers and four inlet angles are formed by processing a four-pipe below the center where four lenses 200 are fastened. A black coated quadrangular metal collector (collector) 400 is fastened according to the position.
The mirror (reflector) (300) having a support (304) on the lower plate provided on the lower center vertical line (optical axis) of the flat plate refractive lens (200) by fastening the mirror (300) as the number of flat plate refractive lenses (200) After adjusting the angle, the focus of each of the flat refraction lenses 200 is focused so as to be directed toward the surface corresponding to the heat collector 400, thereby obtaining a high temperature.
The core configuration described above is one of which the solar tracker with azimuth elevation angle is fastened and the focus of each of the four flat refraction lenses 200 is concentrated on the heat collecting body 400 together with the tracker when the sun is present. In principle, the technical characteristics of the finished product.
The collector 400 has an inlet and outlet through a quadrilateral pipe, and each of the four sides is coated in black to sufficiently absorb the strong heat of the focal point of the flat refraction lens 200 and to focus the four flat refraction lenses. Focusing on 400), the water or heat medium flowing through the inside of the heat collector is boiled and stored in the heat storage tank, where water is hot water and heat medium is used as heating.
In principle, the technology that can combine hot water and heating with hot water alone.
As shown in FIG. 2, four flat plate refractive lenses 200 are fastened to the tracker 99 and the focus is composed of a frame and a tracker.
Angle the focus of the fastening lens on the bottom of the tracker inner lower plate 79, the mirror 300 having the support 304 on the bottom of the lower plate 79 centered on the central incident light optical axis of each plate refractive lens 200. By adjusting and concentrating on the collector 400, the efficiency can be maximized.
1, 2, and 3, one product of the technology disclosed in the present invention is significantly more efficient, and the greater the number of fastening products with a larger tracker, the greater the proportional capacity and efficiency is.
In the above embodiment, there is one type using only hot water, one type of hot water heating, one type of hot water electricity, and a product using up to hot water heating electricity.
The technology is a principle of boiling water, heat medium and the like passing through the heat collector and sending it to the heat storage tank to produce hot water heating electricity and the like.
The present invention is not limited only to the embodiments described in the present invention, and various modifications can be made without departing from the scope and spirit of the invention.
[Example]
The present invention intends to be carried out in practice to prepare all the subsidiary materials to complete the actual product and submit a photograph to the priority screening.
Negotiations have been made to conclude that the products will be able to use electricity for homes (except air conditioning), and all of these will be resolved, aiming to innovate renewable green energy.
The production products are four kinds of products, one type using only hot water, heating and hot water, heating hot water electricity, hot water and electricity, a project to produce four kinds of products.
Although the present invention has been described with reference to the accompanying drawings and the preferred embodiments described above, the present invention is not limited thereto but is limited by the following claims. Accordingly, those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the spirit of the following claims.

59; Sunlight
60K; The centerline to the focal point through which the sunlight passes through the flat refraction lens, but the distance until it is reflected and mirrored by the mirror
60M; The sum of the distances of 60K and 60M should be the focal point and the distance of 63G and 60M should be the same
61; Incident light through optical refraction lens (optical axis)
62; Fresh dashed line through incident refraction lens (incident light)
63; Explanation of light of incident light (61; and 62;) passing through a planar refraction lens
63G; Distance from center line to mirror to focus on collector
64; Focus of Plate Refractive Lens
65; Angled
79; Bottom plate
99; Tracker
100; Award tracker frame
101; Bottom frame
102; Side cover fastened for insulation of upper and lower space
103; Arde between frames for fastening flat refractive lenses
104; Flat Refractive Lens Edge
106; Indication that the collector is in the middle of the bottom plate
108; Refraction Pattern (Virtual Display)
200; Flat Refractive Lens
300; Mirror or metal reflector
301; Virtual line on the mirror surface to explain the angle of bending of the mirror
302; Mirror frame
303; Balls mounted on the mirror to adjust left, right, up and down angles.
304; Mirror support
305; Mirror fixing plate
400; Square carbon collector or black coated metal collector
401; Low temperature water, medium oil, etc.
402; Outlet of hot water, medium oil etc.
404; Flat refractive lens a facing the flat refractive lens a
405; The surface facing the flat refractive lens d while the flat refractive lens d is in focus.
406; The surface facing the flat refractive lens c while the flat refractive lens c is in focus.

Claims (5)

Image frame 100 for supporting a plurality of flat refractive lens 200,
A plurality of mirrors 300 respectively provided below the center vertical line of the plurality of plate refractive lenses 200 to adjust angles of sun incident light passing through the plurality of plate refractive lenses 200 in the middle before focus is formed; ); And
It includes one collector 400 provided in the lower central area of the whole of the plurality of plate refractive lenses 200, so that the focus of each of the plate refractive lenses bent from the plurality of mirrors 300, respectively,
The collector 400 has a heat medium inlet through which the heat medium is introduced and a heat medium outlet through which the heat medium is discharged, and has a black coated pipe shape.
Solar heat concentrated in the heat collector 400 after bending through the plurality of plate refractive lenses 200 and the mirrors 300 heats the heat medium flowing along the heat collector 400.
The flat refractive lens and the mirror are each provided in four, and the heat collector is formed in a quadrangular pipe shape,
Each side of the heat collecting body 400 is such that the focus of each of the sunlight reflected through the four mirrors 300 is concentrated on the corresponding side of the four sides of the quadrangular pipe-shaped heat collecting body 400. It is arranged to face the four mirrors 300,
By concentrating the focal points of the plurality of plate refractive lenses 200 on the heat collecting body 400, the heat medium passing through the inside of the heat collecting body 400 is boiled and stored in the heat storage tank.
The tracker 99 is formed by connecting the upper frame 100 and the lower frame 101 on which the four flat refractive lenses 200 are installed, and the four flat refractive lenses 200 are supported by the upper frame 100. Ade 103 is fastened, the solar tracker is fastened to the tracker 99, between the upper frame 100 and the lower frame 101 is a flat plate refractive lens is fastened to the side cover 102 for warming Used solar collector.
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