Device for the Utilization of Solar Energy

Abstract

The invention relates to a device for the utilization of solar energy which contains a row of absorbing members (2) arranged in a rigid lamella (1), each of the absorbing members containing an optical lens (21) and an absorbing means (20) coupled to it in an optical axis. The absorbing members (2) are oscillatingly mounted in a support bar (11) of the rigid lamella (1) which is fixedly mounted in a longitudinal frame (10). The absorbing members (2) are jointly deflectable in relation to the rigid lamella (1) by means of a movable guide bar (3) located below the support bar (11) of the rigid lamella (1) and are coupled with the absorbing means (20).

Claims

1. A device for the utilization of solar energy which contains a row of absorbing members (2) arranged in a rigid lamella (1), each of which contains an optical lens (21), to which is coupled an absorbing means (20), characterized in that the absorbing members (2) are mounted oscillatingly in a support bar (11) of the rigid lamella (1) mounted in a longitudinal frame (10), the absorbing members (2) being jointly deflectable in relation to the rigid lamella (1) by means of a movable guide bar (3), situated below the support bar (11) of the rigid lamella (1) and coupled to the absorbing means (20).

2-14. (canceled)

Description

DESCRIPTION OF DRAWINGS

[0014] An example of embodiment of an improved device for the utilization of solar energy is schematically represented in the drawing, where

[0015] FIG. 1 is a lateral view of a row of photovoltaic elements with optical means in a basic position;

[0016] FIG. 2 shows a plan view to supplement FIG. 1;

[0017] FIG. 3 is a view of a lamella in the direction P1 of its longitudinal axis;

[0018] FIG. 4 is a lateral view of a row of photovoltaic elements with optical means in an inclined position,

[0019] FIG. 5 is a plan view of the element for the utilization of solar energy to heat a liquid medium;

[0020] FIG. 6 is a lateral view in the direction P2 of a detail of the mounting of a heat exchanger tube from FIG. 5;

[0021] FIG. 7 there is a lateral view of the arrangement of the drive of a guide bar; and

[0022] FIG. 8 there is a plan view for FIG. 7.

SPECIFIC DESCRIPTION

[0023] A device for the utilization of solar energy is in an example of embodiment according to the invention designed in the form of elongated lamellas which can be used separately, or they can be arranged modularly in continuous large assemblies which have a shape of planar surfaces or, according to the possibilities of the space where they are to be installed, a shape of curved surfaces.

[0024] FIGS. 1, 2 show the length section of the elongated lamella 1 in the basic configuration. For better understanding, only its substantial components are shown, the other segments are apparent from the view in the direction along the length of the lamella 1 in FIG. 3.

[0025] A firm part of the lamella is a support bar 11, which is fixedly mounted in an unillustrated longitudinal frame 10 of the device. The support bar 11 is at both longitudinal ends provided with an edge 111, in which are hung in a mutual spacing RN individual absorbing members 2. An absorbing member 2 contains an optical lens 21, which is in the example of embodiment fixed, for example, with glue into the annulus 22. The annulus 22 is mounted oscillatingly by two rotating pins 221 in the support bar 11.

[0026] To the annulus 22 is mounted by four rigid draw bars 23 a bed 24, in which is fixedly mounted an absorbing element of concentrated solar radiation. In the case of a photovoltaic solar means this element is a photovoltaic cell 25. In the lower portion of the lamella 1 is arranged in its longitudinal direction a movable guide bar 3, whose longitudinal edges form hems 31, in which in mutual distances RV identical with distances RN are oscillatingly mounted beds 24 of photovoltaic cells 25 with the aid of of lateral rotating pins 241.

[0027] The photovoltaic cells 25 of one lamella are mutually electrically interconnected by conductors 4.

[0028] The guide bar 3 is with both ends connected to oscillating links 5. Only the oscillating link 5 at the end of the bar 3 on the right-hand side is illustrated, which is at the same time a rigid component of the drive mechanism 6 (FIGS. 7, 8).

[0029] In the illustrated example of embodiment, the support bar 11 of the lamella 1 is made with a U-type profile, analogically to the guide bar 3.

[0030] In an unillustrated embodiment, the lamella may be designed as a substantially planar elongated plate allowing the swinging mounting of the lenses 21. In this case, the lenses 21 are disposed in the elliptical openings in this planar plate, which do not block the lens in its inclined position with the sun rays falling in an oblique direction. If the lens 21 is made of plastic, it does not have to be inserted in the annulus 22. The draw bars 23 carrying the bed 24 for mounting the photovoltaic cell 5 and the lateral rotating pins 221 are cast directly in the material of the plastic lens.

[0031] FIGS. 5 and 6 show a modification of the device—a solar collector heat exchanger, which is used, for example, for heating water or air or another liquid.

[0032] The bed 24 for mounting the photovoltaic cell 25 from FIGS. 1 to 4 is replaced by a hinge 7 of the heat exchanger tube 71, which is, for example, a metal tube or hose made of a suitable heat conducting material. The hinge 7 carried by the draw bars 23 has a shape of the letter “H” in the plan view in FIG. 5, whereby it is oscillatingly mounted in the guide bar 3 by lateral rotating pins 72 analogically to the bed 24 for mounting the photovoltaic cell 25 by the lateral rotating pins 241. In the crossbar of the hinge 7 is mounted a flexible partially opened sleeve 73 for simple fixation of the longitudinal straight heat exchanger tube 71.

[0033] The principal difference between the arrangement of the photovoltaic solar collector and a heat exchanger solar collector is the distance of the lens and the absorbing means itself, i.e. the photovoltaic cell 25 or the heat exchanger tube 71. While the heat exchanger tube 71 is preferably located at the focal point of the optical lens 21, where the device has the greatest efficiency, the photovoltaic cell 25 is situated outside of the focal point of the optical lens 21, in an exemplary embodiment in front of the focal point of the optical lens 21. This is necessary due to the material of the photovoltaic cell 25 itself, which is not able to withstand overheating by the high temperature of the radiation concentrated at the focal point. Moreover, in the position in front of the focal point of the optical lens 21 greater absorption of sun rays is utilized. In addition, the device enables easy replacement of one photovoltaic absorbing means 20 with a heat exchanger tube 71, whereby it is possible to use in one absorbing means 20 simultaneously a photovoltaic cell 25 as well as a heat exchanger tube 71.

[0034] The above-mentioned device according to the invention can be further used at least partially for the conversion of solar energy into light energy. In an unillustrated embodiment, the end of a fiber optic waveguide is in this case located at the focal point of the lens or in the vicinity of the focal point of the lens 21 of at least some absorbing members 2. The fiber optic waveguide can be, for example, provided with an inner reflective layer blocking lateral irradiation of light and it can be used for lighting, for example, dark spaces, in which the light from the fiber optical waveguide is irradiated to facilitate the orientation of moving persons. The fiber optical waveguide with lateral light radiation, at least in a part of its length not provided with an inner reflective layer, can be also used for orientation in corridors and hallways or, for example, for glowing advertising signs and the like.

[0035] The movement of the moving guide bar 3 is carried out by at least one drive mechanism 6 according to FIG. 7. Both rigid ends 32 of the guide bar 3 are in a longitudinal direction substantially oscillatingly mounted relative to the longitudinal frame 10. The end of the guide bar 3 is connected to the drive mechanism 6 by means of a slider 61, which has a shape of the letter “H” in the plan view (FIG. 8). The slider 61 is by means of its four lifting lugs 62 slidingly mounted on a pair of guide oscillating links 5, whereby the connecting pin 63 of the slider 61 is connected to the driving means 64 of the drive mechanism 6. In an example of embodiment, the drive means 64 contains a belt gear with a drive pulley 641 mounted on a shaft of an unillustrated bidirectional rotary motor, with two guide pulleys 642 and an endless belt 643, which is oscillatingly connected to the connecting pin 63 of the slider 61. In an unillustrated embodiment, the driving means contains cable gear or chain gear instead of belt gear, optionally it can be formed by worm gear.

[0036] An unillustrated other end of the movable guide bar 3 (not shown) is mounted without the driving means 64 analogically to the end driven by means of the oscillating links 5 and the slider 61. In an alternative unillustrated embodiment, the non-driven end of the movable guide bar 3 is suspended in relation to the longitudinal frame 10 by means of a pendulum in such a manner that it moves along a curve corresponding to the curvature of the oscillating links 5 similarly to the piston rod of a double-crank four-joint mechanism (parallelogram). It is apparent that in the case of a great length of the movable guide bar 3 synchronous drive mechanisms 6 may be at both its ends.

[0037] Individual elongated lamellas 1 are in the basic arrangement located next to each other, thus constituting substantially a planar surface. This planar surface may be rigid in an unillustrated common frame, whereby, the absorbing members 2 are arranged movable towards it in the above-described manner by means of rotating pins 221, the absorbing members 2 swinging about axes perpendicular to the longitudinal axis of the support bar 11. Individual lamellas 1 may be arranged as blinds, which in relation to the common frame oscillate about longitudinal axes of the lamellas 1 in the same mutual direction according to a method known from the background art, such as from document CZ 302600 B6.

[0038] The operation of the drive mechanism 6 is initiated by an unillustrated per se known sun-tracking device, whose information give signals for turning the drive motor of the driving means 64. The driving means 64 shifts the slider 61 by means of an endless belt 643 in one or the other direction on the oscillating links 5, whereby the guide bar 3 shifts in a direction parallel to the rigid support bar 11 by the distance X, whereby it changes its distance Y from the support bar 11. Thus, around the pins a respective row of absorbing means of one lamella 1 is inclined so that the direction of their optical axes will get to the current direction of the incident rays. If it is a heat exchanger solar collector, also the heat exchanger tube 71 moves with the guide bar 3, the ends of heat exchanger tube 71 being in the case of using the tube connected to the entire exchanger circuit by a flexible hose.

[0039] In an unillustrated embodiment, the bed 24 of the photovoltaic cell 25 and the hinge 7 of the heat exchanger tube 71 have a common universal shape, which allows to connect to it either the photovoltaic cell 25, or the heat exchanger tube 71. This versatility enables the user to relatively easily convert a photovoltaic system into a heat exchange system, e.g., depending on the season or in inaccessible areas, for instance even in space. An advantageous mutual position of the lens 21 and the photovoltaic cell 25 or the heat exchanger tube 71 can be implemented by an inserted sleeve 73 for securing the heat exchanger tube 71 or by setting the length of the draw bars 23, which can be mounted in the annulus 22 of the lens 21, or in the plastic lens, or in the bed 24 of the photovoltaic cell 25 by using high frictional forces, which cannot be overcome without intentionally applying external force.

[0040] The advantage of the device according to the invention is concentration of solar energy into the absorbing means 20, which may be either a photovoltaic cell 25 or a heat exchanger tube 71, or simultaneously both these types of absorbing means. The device enables continuous adjustment of the position of the absorbing means 20 according to the current position of the sun in the sky. In addition, the device contains relatively simple and inexpensive components, which makes it easy to replace them separately after being damaged, in contrast to, for example, large-scale panels. Also, the costs of the recycling of the device and its parts are considerably lower.

LIST OF REFERENCES

[0041] 1 lamella
10 frame of the device (longitudinal)
11 support bar (of the lamella)
2 absorbing member
20 absorbing means
21 lens (of the absorbing element)
22 annulus (of the lens)
221 pivot (of the annulus)
23 draw bar (joint of the annulus and the bed of the photovoltaic cell or the tube hinge)
24 bed of the photovoltaic cell
241 lateral pins (beds of the photovoltaic cell)
25 photovoltaic cell
3 guide bar (movable)
31 edge of the guide bar
32 end of the guide bar
4 conductors (electric)
5 oscillating link (guide oscillating link for the guide bar)
6 drive mechanism (of the guide bar)
61 slider
62 lifting lug (of the slider)
63 connecting pin (of the slider)
64 drive means
641 drive pulley (of the driving means)
642 guide pulley (of the driving means)
644 endless belt (of the driving means)
7 hinge (of the heat exchanger tube)
71 heat exchanger tube
72 lateral rotating pin (of the hinge of the heat exchanger tube)
73 sleeve (of the heat exchanger tube)
RN mutual distance (of the absorbing members 2 in the support bar)
RV mutual distance (of the absorbing means 20 in the guide bar)
X distance (spacing between adjacent absorbing elements)
Y distance of the guide bar from the support bar of the guide bar from the support bar (when changing the position of the absorbing elements)