DE3840895A1 - Solar system - Google Patents

Abstract

The invention relates to a solar system having planar absorbers and/or solar cells in a collector field, on whose edges at least partially one or more planar mirror surfaces are arranged at an angle to the absorbers or solar cells, the solar radiation incident on the mirror surfaces falling at least partially on the absorber and/or solar cells and the mirror surfaces and the absorber surfaces or solar cells being fixed rigidly on the roof of a building or on carrier elements, while the mirror surfaces are fastened on a plane running inclined to the absorber plane and extending to the north and/or to the south, and the mirror surfaces expanding sideways over the absorber surfaces in a shadow-free manner with respect to the absorbers, the mirror surfaces and their associated carrier elements on one of the planes extending to the north or to the south being divided into at least two planar mirror surfaces whose inclinations increase with respect to the horizontal with greater separation from the absorbers, according to Patent P 3600881 and Patent (Patent Application P 3719099). In such a solar system, in order to extend the possibilities for adjustment, it is proposed that the rigid support (35), which serves for the common mounting of the mirrors (1, 17) and the collectors or modules (2, 2a) [lacuna] with a hinge (33) on a rigid building (45) in a pivotable manner and arranged adjustably by means of a support (14)... Original abstract incomplete. <IMAGE>

Description

The invention relates to a solar system according to the preamble of Claim 1.

Such a solar system has already been very practical lasts because the mirror surfaces can be enlarged considerably, so that correspondingly high temperatures behave with little effort can be achieved quickly. As another special one It proves advantageous that the absorbers and the mirrors on one common support together by hand, for example, about every 14 Days can be adjusted once. This can be an optimization can be achieved without a biaxial or even uniaxial Sun tracking is required.

The object of the present invention is to make this possible expansion options and additional options to show how such a system on a pitched roof with ge ring inclination can be attached.

To solve this problem, the characteristic features of the An Proposition 1 provided. This makes the system easy for example attached to a balcony and can also be adjusted there.

In a further embodiment of the invention, the features of the Proverbs 2 cheap, because this adjustment also Ver can find application if there is almost no additional floor space is needed.  

Due to the features of claim 3, the possibility arises only to adjust the mirrors alone on a facade, if the collectors or modules should remain stationary.

Due to the features of claim 4, a new possibility of Arrangement specified on a roof with a slight slope.

Further advantages, aims and details of the invention emerge from the following description of some exemplary embodiments referring to the drawing. In this shows

Fig. 1 is a side view of the first embodiment;

FIG. 2 shows a side view of the embodiment according to FIG. 1, in a different position;

3 is a side view of a further embodiment having a location-independent frame.

Figure 4 is a partially sectioned side view of a facade arrangement.

Fig. 5 is a schematic side view in a further embodiment;

Fig. 6 is a schematic side view of a further embodiment and

Fig. 7 is a schematic side view of an additional embodiment.

Fig. 1 shows a balcony 45 in side view, the common support 35 is arranged with the mirrors 17 and the absorbers or modules 2 at the top by means of the hinge 33rd In the lower region of the support 35 , the support 14 engages by means of the joint 34 . This support 14 is locked here by means of a bolt 42 which is firmly attached to the balcony 45 below. This bolt is seated in a hole in the support 14 . Further holes 43, 44, 46 and 47 are arranged further to the right for adjusting the support 14 .

Fig. 1 shows a relatively steep setting, as is required in winter.

Fig. 2 shows another setting with the same arrangement. Here the bolt 42 is seated in the hole 44 of the support 14 . As a result, the common support 35 is pivoted far to the left and upward, so that it now has only a very small angle of inclination with respect to the horizontal. This is required to optimally absorb the diffuse radiation in our latitudes. In countries near the equator, this position may be the best for lunch or otherwise.

The design of the common for the mirror 1, 17 and the absorber 2, 2 a 35 prop is known from the main patent and therefore need not be explained. Is well known that the mirrors 1, 17 laterally beyond, ie perpendicular to the drawn here level on the absorber 2, 2 a.

The mentioned adjustment in the different holes can be done by hand. Of course, two supports 14 will usually be provided, namely one at the end of the balcony. Intermediate supports are of course also possible with very wide balconies.

The arrangement on a balcony is generally cheap because the Attachment more accessible here for the purpose of the adjustment mentioned is than, for example, on a high roof.

Fig. 3 shows the same adjustment in a known frame. The hinge 33 sits here on the vertical supports 10 or in the vicinity thereof. In the lowest area, different bores 50, 51 and 52 are arranged vertically one above the other at a distance in order to be able to adjust the end of the support 14 here.

The adjustment can also be made in any other way. For example, a gear can be provided by which the end of the support 14 is changed up or down, for example by a self-locking worm gear. The joint 34 engages the support 35 here again, similarly to FIGS. 1 and 2.

In addition, mirrors 17 l can now be placed on the supports 14 in order to additionally direct sunlight onto the arrangement below on the support 35 in this way. As a result, the angle of the mirror 17 l is also advantageously changed with a change in the setting of the support 14 . The visible from above stood b between two common supports 35 must be chosen so large that mutual shading does not occur in our latitudes.

The supports 11 serve only to support the vertical supports 10 in the present exemplary embodiment. Of course, there is also the possibility of arranging the support 11 to the south, on which the common supports 35 can then be adjusted, similarly to the upper region.

Fig. 4 shows a partially sectioned side view through the facade of a building. Below the wall 61 is shown in section, on the left an angle iron 62 with the holes lying one above the other holes 50, 51, 52 is attached, which serve the adjustment in this case. In the hole 50 , the support 14 a is fastened, which again engages at the top with the joint 34 on the holder for the two mirrors 17 f , 17 g , which can be pivoted about the hinge 33 . By setting in different holes, only the mirror arrangement is adjusted here on its own.

Instead of the absorbers, a radiation-permeable insulation 64 is arranged here, behind which there is a black-colored radiator 63 according to the prior art, which is also suitable for heating the room. This is already known and therefore need not be explained in detail.

Instead of this arrangement you can either use collectors again or have facade modules, which in this case are fixed to the lower right wall can be arranged.

Above you can see the window 65 and above the support 14 b accordingly the support 14 a .

These adjustable mirrors according to FIG. 4 show the advantage that they can also be retrofitted if, for. B. facade collectors or facade modules are already available in a known manner.

Fig. 5 shows a gable roof 59 with a relatively low inclination of z. B. only 15 °. Left is south and north is right, as indicated by the large letters. It can be seen that a thermosystem with the collector 2 and the storage container 58 is not arranged as usual on the south roof, but on the north roof. For this purpose, beams 53, 54, 55, 56, 57 are fastened to the roof approximately parallel to the roof 60 by means of the known roof hooks.

In the upper area not far from the roof ridge 60 , two beams 53, 54 are even arranged one above the other, so that the distance between the mirror 17 f and the roof becomes slightly larger with a slight inclination. In contrast, the lower mirror 17 g lies approximately parallel to the roof on the same, being held together by the beam 56 together with the end of the collector or absorber 2 . Below you can see an approximately vertical support 10 , which is held by the beam 57 . In general, two supports 10 are of course available. Above you can see a slightly shortened mirror 1 b , which is supported on the storage container 58 of a known type. The Thermosyfon plants of this type are generally known and therefore do not need to be described in detail.

The advantage of the arrangement according to FIG. 5 is that the mirrors 17 can be arranged approximately parallel to the roof without great wind loads. Another advantage is that an additional roof area, namely the north roof, is used at all. In countries near the equator, the roof pitch can also be considerably larger.

Fig. 6 shows an embodiment with a storage container 37 , which is provided according to the invention not only in the south with a transparen th thermal insulation material 38 , but also above with a thermal insulation material 39 .

In the areas of these transparent thermal insulation materials 38, 39 , the container 37 is designed as an absorber, so that an additional absorber surface is not required. As you can see is to the left, south, the container 37 obliquely at an angle of z. B. 45 ° formed while it is formed perpendicular to the north right.

On the north edge of the container you can see the mirror 17 at an angle γ 5 of z. B. 80 °, which mirror is also divided here. It also protrudes east and west far beyond the absorber 39 . As a result, especially the low solar radiation is additionally directed onto the absorber surface behind the transparent thermal insulation material 39 , whereby the container 37 naturally produces at least twice as much heat overall. Even the very low solar radiation just before sunrise and sunset is still reflected by the mirror 17 m . In addition, there is also the possibility of providing the east and west sides of the container with additional transparent thermal insulation materials, which are arranged behind a glass pane or a transparent plastic film.

In this way there is the possibility, especially in Winter the very low solar radiation early in the morning and late to be implemented in the evening. This is not shown in the figure provides, it is easily understandable to the expert.

If all of these measures are carried out, the container 37 is only provided with the exception of the north wall and the bottom with transparent thermal insulation material, behind which the container wall itself is designed as an absorber. The 17 m mirror directs its radiation partly onto these side surfaces in the east and west, particularly in the morning and evening in winter.

In the Fig. 6, there is only a schematic representation. In a practical embodiment, the corners of the container 37 are very rounded. It can also be a substantially oval container in this side view, which can be manufactured somewhat more easily than the one shown. All that matters is that the container has an inclined surface 38 facing south and an approximately horizontal surface 39 pointing upward.

The two mirrors are divided as before.

Fig. 7 shows another embodiment that is particularly suitable for countries near the equator. As is known, the sun rises exactly in the east and sets in the west at the equator, it rises and falls exactly vertically. Therefore, an adjustment for the different seasons, as previously described, is not necessary.

The straight common support 35 here lies horizontally on the floor or flat roof. The collectors or solar cell modules 2, 2 a are arranged with a width b and a distance a from one another. Here, the distance a can be much larger because there is no danger of shading from the mirrors at any rate at the equator. By very large distances a must of course be accepted that the diffuse radiation of the upper mirrors 1 a , 17 f is only slightly reflected. However, this results in higher levels of direct radiation because the levels are much larger.

From left to right you can first see a support 18 which supports the two mutually offset mirrors 17 g , 17 f . Down there on the right, the solar cell module 2 is visible, to which the two mirrors 1 b , 1 a connect on the right, which are held by the common support 36 a , which also holds the right-hand mirror. Further to the right you can see the module 2 a , to which the mirrors are connected, which are held by the support 36 b .

Of course, the common support 35 can also be adjustable as described above or by the main patent. As is known, the closer you are to the equator, the smaller the angle of inclination to be set. In addition, the closer you are to the equator, the less necessary is the adjustment.

The invention is not based on the illustrated embodiments limits. Rather, the specialist has the option of modified To provide embodiments within the scope of the claims.

Claims (7)

1.Solar system with flat absorbers and / or solar cells in a collector field, at the edges of which at least partially one or more flat mirror surfaces are arranged at an angle to the absorbers and / or solar cells, the solar radiation impinging on the mirror surfaces at least partially on the absorbers and / or solar cells falls and the mirror surfaces and the absorber surfaces and / or solar cells are rigidly arranged on the roof of a building or on supporting elements, while the mirror surfaces are fastened in a plane extending to the north and / or south and inclined to the absorber plane and the mirror surfaces extend laterally beyond the absorber surfaces with respect to the absorbers without shading, the mirror surfaces with associated supporting elements on one of the planes extending north or south being divided into at least two flat mirror surfaces, the inclinations of which are at a greater distance v increase on the absorbers with respect to the horizontal, according to patent P 36 00 881 and patent (patent application P 37 91 099), characterized in that the rigid support ( 35 ), which is used to hold the mirrors ( 1, 17 ) and the collectors or Modules ( 2, 2 a) is used, with a hinge ( 33 ) on a rigid building ( 45 ) pivotally and is arranged adjustable by a support ( 14 ). 2. Solar system according to claim 1, characterized in that the common support ( 35 ) on vertical masts ( 10 ) at a distance (b) are arranged one above the other and that the supports ( 14 ) for this purpose are provided with mirrors ( 17 l) . 3. Solar system according to claim 1, characterized in that the collector gates, modules or the like ( 63, 64 ) on a building facade ( 61 ) are arranged in a fixed position and the mirror ( 17 f , 17 g) by the supports ( 14 a ) held and individually adjustable on the facade. 4. Solar system with flat absorbers and / or solar cells in a collector field, which is arranged together with mirrors on the sloping roof of a building, characterized in that the collectors or solar cell modules ( 2 ) and the mirrors ( 17 f , 17 g) with a low roof pitch are arranged on the north roof, the mirror ( 17 g) z. T. on the north roof, parallel to the same, are arranged. 5. Solar system according to claim 4, characterized in that the collector gates and the mirrors are fixed by beams ( 53, 54, 55, 56, 57 ) on the north roof, which are attached to the roof first by means of roof hooks parallel to the roof ( 60 ) are. 6. Solar system, in which the collector field is arranged in a storage container with transparent thermal insulation material, characterized in that several absorber surfaces with insulating material ( 38, 39 ) are arranged, one of which ( 39 ) is approximately horizontal, the one about vertical mirror ( 17 m) is assigned. 7.Solar system with essentially flat absorbers and / or solar cells in a collector field, which is not attached to the roof of a building or on supporting elements, the mirror surfaces extending laterally beyond the absorber surfaces with respect to the absorbers, and the mirror surfaces in at least two mirror surfaces are divided, the inclinations of which increase with a greater distance from the absorbers or solar cells with respect to the horizontal, characterized in that one-piece supporting elements ( 36 a , 36 b) for the mirrors ( 1, 17 ) on the common support ( 35 ) are arranged.