DE10062102A1 - Beam deflector has grid of elongated, mutually parallel mirror strips perpendicular to direction of beam to be deflected, pivotably arranged and forming channels between them - Google Patents

Abstract

The beam deflector has a grid consisting of a number of elongated, mutually parallel mirror strips (1,2) perpendicular to the direction of the beams (4,6) to be deflected, pivotably arranged and forming channels between them. The mirror strips are mirrored on both sides. Two mirror grids can be arranged with parallel strips.

Description

The invention relates to devices that block the rays, for example that of the sun, regardless of the angle of incidence in a given direction through stationary facilities for energy conversion or interior lighting can be used.

To achieve the object, the invention provides mirror gratings that lower stripes are formed right to the incident rays, the Strips are hung pivotably about their longitudinal axis and preferably me can be pivoted so that the rays in a given direction be reflected. Two can be used to extend the entry angle interval Layers of mirror strips are provided that are independent of one another Experience pivoting. The invention also relates to mirror strips with changeable chem distance of the mirror strips from each other as well as pivoting devices and typical applications of mirror gratings.

The inventive concept is set out in claim 1.

The invention will be explained with reference to figures,

Fig. 1 shows a single-layer mirror grating.

FIG. 2a to 2g show a two-layer mirror grating.

Fig. 3a and 3b show a mechanical pivoting device.

Fig. 4 shows the suspension of a mirror strip.

Fig. 5a and 5b show a photovoltaic generator.

Fig. 6 shows an electromagnetic swivel device.

Fig. 7a shows a light guiding device for room lighting.

FIGS. 7b and 7c show the radiation path.

Fig. 8 shows an electrostatic pivoting device.

Fig. 9 shows an unbalanced photovoltaic power plant module.

Fig. 10 shows a subsequently installable sunlight steering device for room lighting.

Fig. 11 shows a mechanical pivoting device with diversified extending mirror strips.

Fig. 12 shows a module of a photovoltaic power station, without lenses.

FIG. 13a shows the combination of secondary concentrators with folding mirrors.

Fig. 13b shows the beam path.

Fig. 14 shows solar generators for floor space-saving installation.

Fig. 15 shows a pivoting mechanism.

Fig. 16 shows the connection of two superimposed levels.

FIG. 17 shows the arrangement according to FIG. 16 in a lateral section.

Fig. 18 shows two pairs of a mirror grating with variable spacing of the mirror gel from one another.

Fig. 19 shows a reflection grating with variable mirror spacing.

Fig. 20 shows the beam path of a roof solar power plants.

In Fig. 1, the symmetry half of a mirror grating is shown, in which the joints 3 of the mirror strips 1 , 2 moored on north-south planes, so that the morning sun rays 6 as well as the late afternoon three times on the mirror strip 2 are reflected and then directed vertically Exit rays 7 from the mirror grille. In the morning or afternoon, the desired only one-time reflection of the sun's rays 4 occurs , which emerge according to ray 5 . As soon as the mirror strips 1 run approximately parallel to the radiation, the solar radiation passes directly through. The curve 8 intersects the mirror strips in each case directly below the respective width of the mirror strip which reflects the sun rays 4 , 6 only once. Beyond this, the width of the mirror strips leads to the fact that, as the ray 9 shows, rays are lost at certain angles of incidence. This distrust is portable for light control devices for room lighting, but not for solar electricity generation.

Fig. 2 shows the beam path at two superposed levels gratings 20 and 21. Since the afternoon ray image is mirror-symmetrical to the illustration shown, only the positions passed until noon are shown. The assignment of a second mirror grating 21 enables a beam guidance in which no beams are lost.

The illustration 2 a shows that the mirror strips 10 reflect all rays 22 between 25 ° and 45 ° to the perpendicular exit beam 23 . The mirror strips of the grid 21 are placed vertically.

B In Preparation 2 the beam path of the subsequent Auftreffwinkelinterval les between 47.5 ° and 67.5 ° is shown. The emerging rays 24 of the upper mirror grating 20 , which fall within this angle of incidence, are narrowed by the mirror strips 26 of the lower mirror grating 21 to a sufficiently narrow angular interval of ± 5 ° for concentrators.

Representation 2 c shows that an unimpeded passage through the upper mirror grating 20 occurs at the third angle of incidence between 70 ° and 90 °. The angular deviation from the vertical is reduced by the mirrors 26 in the lower mirror grille 21 .

Since every reflection leads to energy losses, the invention aims for mirror gratings in which the incident rays are reflected only once. For an impact angle interval of 25 ° to 55 °, a mirror grille is sufficient, as shown in FIGS. 2d and 2e for small angles and in FIG. 2g for angles between 80 ° and 90 °. If the entire interval between 25 ° and 90 ° is to be deflected, two mirror gratings are arranged one below the other, but in contrast to the beam path shown in FIG. 2b, the mirror strips of the upper or lower grating are set in parallel with the rays passing through become.

Fig. 2e shows deflections, in which the emerging from a mirror grid beams between 2 ° and 11.04 ° deviate from the vertical. The distance between the mirror strips is 54.6% of the strip width in FIGS. 2d and 2e and only 18.5% of the strip width in FIGS. 2f and 2g.

In the illustrations, only two mirror strips 26 , which are associated with a pair of mirror strips 27 and 28 (of the upper mirror grating), are shown. From the width of these mirror strips 27 and 28 , the division ratio between the division of the upper (primary) mirror grating 20 and the division of the lower (se secondary) mirror grating 21 can be seen. An advantageous assignment is for the mirror grating 20 a strip width spacing ratio of 1.833 and for the bottom 21 is one having the ratio of 5.4 before. Another assignment provides a stripe width-to-space ratio of 2.1 for the upper mirror grating and 4.72 for the lower.

Another, not shown, third tertiary mirror grating is another, in in practice, however, it is seldom necessary to narrow the exit angle interval.  

In FIGS. 3a and 3b is a mechanical pivoting device of the mirror strips 39, shown in the mirror gratings 30 and 31 40. Between the levers 34 and 35 pivotable about the axis 32 and 33 are made of thin material, for. B. sheet metal existing trusses 36 and 37 , the receiving areas 38 for the mirror strips 40 , the longitudinal extensions of which are perpendicular to the travers sen. The mirror strips 39 , 40 consist of polished aluminum sheet or silver-plated metal or plastic film strips. These strips are protected from corrosion by a thin layer of acrylic. Plastic films can be reinforced along the edges with high tensile flat wires.

Fig. 4 shows the storage of a mirror strip 40 , which contains a slotted bearing pin 41 , via which the forces of the spring 42 are transmitted to the mirror strips, who are necessary for tensioning the mirror strip relative to the stationary walls 43 . Also visible in section are the cross members 36 and 37 , which are distributed over the longitudinal extent of the strips 40 and hold them in the respective angular position.

Fig. 5a shows in vertical section and Fig. 5b in section along section line VI-VI a solar electricity module. The housing 53 is covered by a cover plate 54 facing the sun, which possibly absorbs harmful UV rays. The longitudinal axis 56 is oriented in the east-west direction. On the two housings seendwandungen 57 stub axles 58 are arranged, which are mounted in stands 59 . From time to time, the normal 60 is tracked by the sun migration plane, which becomes steeper until the summer solstice, so that all sun rays run approximately parallel to planes which are formed by the east-west direction and the normal 60 a. Behind the cover plate 54 are two mirror grids 60 and 61 with mirror strips 39 and 40 which run perpendicular to the east-west axis and which are held parallel to one another between cross members 36 and 37 . Behind the mirror gratings 60 and 61 is a linear lens 63 , the steps of which, like on some enlarged prisms 64 , 65 , 66 . , , recognizable, the sun rays running on vertical planes 67 break upon entry, then totally reflect and break again upon exit. This makes z. B. a right angle deflection, as shown on the beam 68 , possible, which leads to a compact concentrator. In the focal region 70 , the rays are directed towards the photocell 71 , which is carried by a cooling water pipe 72 .

The pivoting of the mirror strips 39 and 40 takes place as a function of the sun elevation 4 , 6 according to FIG. 1 by adjusting devices, the pivoting of which is predetermined for the respective sun height via a program or which is dependent on the radiation intensity achieved by the angular position of the mirror strips the optimal value is set.

Fig. 6 shows two adjacent mirror strips 75 and 76 , which are magnetized similarly to tapes. The mirror strips are parallel to the stripe extension duri fende wires 77 A to 77 E assigned, which lie on arcs 78 , the radius of which is slightly larger than half the width of the mirror strips 75 and 76th Depending on the current direction with which the wires are flowed through, the neighboring edges of the mirror strips experience a repulsion or attraction. If, for example, the two mirror strips are to be swiveled clockwise into the positions 75 x and 76 x, the wires 77 A and 77 B are flowed through vertically into the plane of the image, while the wires 77 E and 77 F in opposite opposite flow of electricity. The wires 77 C and 77 D are then flowed through in the same way as before 77 A and 77 B and produce a repulsive field until the mirror strips have reached the positions 75 y and 76 y. If the current direction is then reversed in 77 E and 77 F, the mirror strips are pivoted into a position according to 75 z. All intermediate values in the angular positions of the mirror strips 75 and 76 can be set via the current intensity.

Fig. 7a shows a sunlight guide device for guiding the sun's rays into the interior of buildings. The frame 83, which is elongated in the east-west direction, is mounted on the roof 85 of a building. The cover plate 84 advantageously runs perpendicular to the sun orbit plane 80 of the equinox midday. The mirror strips 81 and 82 lying in the neutral position in the vertical planes are pivoted as a function of the respective height of the sun so that all exit rays run approximately on vertical planes perpendicular to the cover plate 84 .

By a third mirror grating 86 , the mirror strips of which are perpendicular to the mirror strips 81 and 82 , the rays emerging from the mirror grating with the Spiegelstrei fen 82 rays in predetermined directions z. B. 87 or 88 for uniform room lighting. The mirror grating 86 also has the task of compensating for the seasonal declination of ± 23 °. The swiveling of this mirror grille does not need to take place continuously; swiveling in monthly intervals is usually sufficient.

Fig. 7b shows a limit position of the mirror strips 81 , in which the sun rays 89 perpendicular to the mirror strips 81 u and thus are fully reflected re. In this position, the mirror strips 81 do not emit sun rays in the room to be illuminated, so that no undesired heating takes place due to penetrating sun rays.

Fig. 7c shows a position of the mirror strip 81 v, in which a small part of the sun rays penetrate into the room according to arrow 88 v, while the greater part of the solar energy is reflected to the outside. In addition to uniform illumination, the sunlight guiding device also permits the regulation of the light intensity and the radiant heat entering the room.

Fig. 8 shows mirror strips 30 s, 31 s, which are suspended on joint-forming foils 33 s, are electrostatically charged, the even-numbered mirror strips 30 s having the opposite polarity as the odd-numbered 31 s. The positively charged wires 32 s attract the even-numbered mirror strips 30 s and repel the odd-numbered 31 s, so that they pivot in the direction of the arrow 35 s.

Fig. 9 shows a vertical section through a solar electricity module. The cover disk 94 forms the aperture in the housing 92 , the longitudinal axis of which extends in the east-west direction. From time to time, the normal 80 follows the sun migration level. Behind the cover plate 94 are two mirror grids 90 and 91 , which can be pivoted by actuators 97 and 98 . In the prisms of the linear lens 93 , the approximately vertical planes following mirrored sun rays 95 are deflected by internal reflection by up to 90 °, so that the bundle of rays 96 hits the photo line 99 without further deflection devices, which is mounted on a cooling water tube 100 . In contrast to the construction according to FIG. 5, the heat-emitting photocell 99 is always in the lowest range. This tube forms a swivel joint together with a holding element 101 . The photo tents 99 lie below the linear lens 93 and eccentrically to it. From time to time, the module is guided by a telescopic tube 102 to the solar path plane. If, on the other hand, a third mirror grating, which runs at right angles to the mirror strips of the mirror grids 90 and 91 , is provided, as described in FIG. 7a, this takes over the tracking. In place of the cooling water pipe 100 , the lower region, as shown in FIG. 4, can also be immersed in a water layer.

Fig. 10 shows a sunlight guide device, the same elements, cover plate, two mirror grids 81 D and 82 D, the mirror strips of which run in the neutral position on vertical planes and a perpendicularly extending mirror grille 86 D, as described in FIG. 7 Includes device. The difference is that the rays exiting from the mirror grille 86 D 88 D are directed vertically downward through an internally mirrored tube 83 D, which forms the connection between the roof 85 D and a radiator 103 that covers the room 108th forms the end of the tube 83 D.

Fig. 11 shows the kinematics of the collective angular pivoting and the superimposed spreading of the mirror strips 40 H. The two levers 34 H and 35 H, one of which is biased by the tension spring 44 H, take between them two traverses 36 H and 37 H made of elastic material to which the mirror strips 40 H are attached as shown in FIG. 3. The levers 34 H and 35 H are connected to one another via a wire 39 H. If the distance between one end of the two levers z. B. shortened by a nut 31 H, the spread angle between adjacent mirror strips 40 H and 41 H increases. On the other hand, the levers 34 H and 35 H are guided parallel to one another and pivots ver about the axis 32 H, so all mirror strips experience 40 H and 41 H pivot by the same angular amount.

Fig. 12 shows schematically a vertical section through two modules of an aligned in east-west direction of the solar power plant with a device according to Fig. 11. Underneath the cover plate 94 H extends the 90 H when changing the height of the sun to pivoting mirror grating from which the sun's rays exit as that they lie approximately in vertical planes moored parallel to the mirror strips. Beneath the mirror grille 90 H is the mirror grille 86 H, whose mirror stripes 91 H moor at right angles to the mirror strips of the upper mirror grille 90 H. The mirror strips 91 H are fanned out in such a way that the rays reflected by the mirror grating 90 H become bundles of rays 64 H, in the focal line region of which photocells 71 H lie. To increase the concentration, each photocell 71 H forms a unit with a secondary concentrator 70 H made of transparent material, the walls of which run parabolically. The heat loss from the photo cells is dissipated via a 72 H pipe through which water flows. The inclination of the mirror grating forms an angle 80 H with a horizontal line 60 H with an angle which is determined by the respective geographical latitude and, if appropriate, the time of year. In addition to the concentration, the 91 H mirror strips can also compensate for the declination of ± 23.4 °. A more precise concentration can be achieved by a second mirror layer, the mirror strips of which run parallel to the mirror strips 91 H. The walls are completely separated from the outside air by walls 66 H and end walls. Pressure equalization takes place via a fine-pored air filter, which at the same time dries sucked-in air, so that the water content of the indoor air remains so low that no droplet condensation occurs on the 94 H cover plate. The volume can also be changed using a harmonica compensator. This power plant is characterized by the extreme use of the floor space, since the aperture and the floor area almost coincide.

Fig. 13 shows a perspective view of secondary concentrators 70 H, to which mirrors 58 H are hinged ver. The mirror arrangement with the beam path is shown schematically in FIG. 13a. The rays 51 H of the bundle of rays are reflected by the mirror 58 H such that the rays 58 I enter the secondary concentrators 70 H approximately perpendicularly.

Fig. 14 shows the assignment of adjacent solar power generators. The south-facing wall 149 of the triangle is shorter than the north-facing wall 156 angled in the upper region. Arranged below the two mirror grids 154 is a linear lens 160 consisting of two areas, the slightly deflecting area 143 on the south side of which is designed as a Fresnel lens, while the area 144 on the north side consists of pointed prisms, in which the incoming rays give a total reflection experience what makes a stronger redirection possible. The housing configuration allows an extremely extensive use of the floor space. The spacing of the generators from one another is almost zero with a small geographic latitude in midsummer. At the maximum swivel for the winter solstice day, the neighboring generator experiences a certain shade. In the lower area, the photocells 140 are connected to the outer wall with good thermal conductivity. The solar generators are immersed in a layer of water 150 which is closed off from the outside air by a thin-walled plastic film 151 . On the north-facing wall 156 a gear 156 and an electric motor 157 is arranged at the upper end. The heat loss leads to slight heating of the water layer 150 . The outside air can pass through the channels 159 between the adjacent, elongated generators to the plastic film 151 and in particular remove the stored heat from the water during the night. The same generator can also be operated without pivoting if a mirror grating with mirror stripes running in east-west direction is arranged between the cover plate and the two mirror grids 154 , which reflects the sun's rays at sun heights that are 90 ° minus the geographic angle Deviate width, reflected in a normal direction to the cover plate. The normal on the disc should then form an angle of 90 ° minus the latitude with the horizontal.

Fig. 15 shows an enlarged view of a mirror strips 158, 159 about the central axis H 160 H is pivoted over a slotted stub shaft. Outside the inter mediate wall 155 H is a toothed segment 161 , which is pressed by a coil spring 162 in the direction of arrow 163 . In sleeves 164 , a gear worm 165 H is mounted, the helical region 166 H of which engages in the toothing of the segment 161 . This gear worm is driven by an electric motor and takes care of the angle adjustment of the mirror strips 158 as a function of the height of the sun according to a predetermined program.

Fig. 16 shows an arrangement of the superimposed mirror grille, which are connected to each other via egg ne joint 165 . The upper mirror strips 166 tra gene at the axial ends clamping pieces 167 , the stub axles protrude into holes in the wall 168 . Below the hinge seam 165 , which is formed, for example, from two reflective adhesive foils 169 , which are glued to a sheet metal strip 176 , there are again clamping pieces 170 only at the axial ends. These have a bore 171 through which a very thin steel cable 172 passes. Between two adjacent mirror strips is a aufgefä delt tube 173 arranged on the steel cable, which is squeezed together at a suitable point 174 , whereby an indissoluble frictional connection with the steel cable 172 is formed. If the steel cables 172 and 175 are moved to the right or to the left by an equal amount, only the upper region of the mirror strip 166 is pivoted. If, on the other hand, only the lower area is pulled out of the rest position by the steel cable 175, the lower area of the mirror strip 166 is pivoted. Suitable pulling movements on the steel cables 172 and 175 make it possible to achieve any desired inclined days of the two mirror strip areas.

In Fig. 17 the wall is shown pivoted about the vertical axis by 90 ° 168th It can be seen how the clamping pieces 167 are mounted, furthermore the clamping pieces 170 with the holes for the steel cables 172 and 175 are visible. The hinge seam 165 acts like a hinge.

Fig. 18 shows that with increasing elevation of the sun, the division of the mirror strips becomes narrower. The elevation of 25 ° is assigned a distance of 180 a. The distance 180 b for the elevation beam 180 c is considerably shorter. Arrangements are therefore provided in which the distance 180 a between the Spiegelstrei fen is variable.

Fig. 19 shows a technical solution. The respective adjacent mirror strips 181 are connected to one another by two leaf springs 182 and 183 connected to one another. The first of the mirror strips 181 of a first group 185 is connected to a lever 186 which is rotatable about the pivot axis 187 . A second group 188 is connected to the lever 189 . The mirror strips of this group have projections 190 which protrude into the helix 191 , whereby these mirrors strip 192 are pushed together to the smallest possible distance. If the helix is rotated through 360 °, the next mirror strip 192 a is released. Zugteich shortens the distance between all mirror strips 181 . If the distance 181 a is to be extended, a tongue 193 , which is axially displaceable via the push rod 193 a, is pivoted between the projections 190 and then moved in the direction of the arrow 194 a. By rotating the helix 191 , the mirror strip 192 a, which is moved, is fixed. Each mirror strip has a pivot bearing 194 at the ends. These pivot bearings 194 slide in a U-profile 195 .

Fig. 20 shows schematically the structure of a linear lens system with an upper linear lens 200 and a lower linear lens two hundred and first The lens 200 breaks the sun ray 202 of the low-lying sun into the steeper ray 203 . This is reflected by the mirror strip 204 to the beam 205 . This beam 205 is then refracted into the exit beam 206 by the prisms of the linear lens 201 . After refraction in the prism 207 , the sunbeam 208 entering the upper linear lens does not require a change of direction through the mirror strip 209 , which therefore runs parallel to the beam 210 . The vertical sun ray 211 is after breakage to the ray 212 , which is reflected by the mirror strip 213 compared to the reflection of the ray 203 in the opposite direction as the ray 214 . All the emerging rays 206 emerge parallel to one another, whether the entry direction comprises an angular interval of 65 °. The mirrored rays 203 , 210 and 212 have an angular interval of only 47 °. The lower linear lens 201 can be designed as a Fresnel lens on its underside.

Claims (41)

1. beam steering device with mirrors, characterized by a grid, which consists of a plurality of elongated, parallel mirror strips, which are perpendicular to the direction of the beams to be deflected, which are pivotable and form channels between them. 2. Beam steering device according to claim 1, characterized in that the mirror gel strips ( 10 , 28 ) are formed on both sides mirror. 3. Beam steering device according to claim 1, characterized in that two mirror grids ( 60 , 61 ), the mirror strips moored parallel to each other, in Rich direction, the beams to be deflected by reflection are arranged one below the other. 4. beam steering device according to claim 3 with two mirror gratings ( 20 , 21 , 60 , 61 , 81 , 82 , 90 , 91 ), characterized in that the division of the first mirror grating ( 20 , 60 , 81 , 90 ) is different from the division of the second mirror grating ( 21 , 61 , 82 , 91 ). 5. beam steering device with a mirror grating according to claim 1, characterized in that adjacent mirror strips are held by elastic connecting elements ( 36 H, 37 H) at a preselectable distance from each other. 6. beam steering device with a mirror grating according to claim 5, characterized in that the elastic connecting elements ( 36 H, 37 H) of adjacent mirror strips are made of rubber-elastic strands. 7. beam steering device with a mirror grating according to claim 5, characterized in that the elastic connecting elements ( 36 H, 37 H) of adjacent mirror gel strips consist of coil springs. 8. beam steering device with a mirror grating according to claim 5, characterized in that the distances between the mirror strips are determined by a rope ( 172 , 175 ) which is connected to the first mirror strip and that the rope ( 172 , 175 ) the mirror strip ( 158 ) runs at right angles to the axis ( 160 H). 9. beam steering device with a mirror grating according to claim 5, characterized in that the elastic connecting elements ( 36 H, 37 H) adjacent mirror strips ( 181 ) made of leaf springs ( 182 , 183 ). 10. beam steering device with a mirror grating according to claim 5, characterized in that at a small distance ( 181 a) of the mirror strips ( 181 ) from each other a large number of mirror strips ( 181 ) is exposed to the rays, and at a large distance ( 181 a) the mirror strips ( 181 ) from each other a smaller number of mirror strips is exposed to the rays. 11. beam steering device with a mirror grating according to claim 10, characterized in that a first plurality of mirror strips ( 192 ) is kept operationally in stock, while a second plurality ( 181 ) is exposed to the rays. 12. Radiation steering device with a mirror grating according to claim 1, characterized in that a linear lens ( 200 ) is arranged in front of the mirror grating ( 181 , 204 , 209 , 213 ) in the direction of the radiation source. 13. beam steering device with a mirror grating according to claim 1, characterized in that a linear lens ( 63 , 93 , 201 , 143 , 144 ) is arranged behind the mirror grating ( 60 , 90 , 154 , 204 , 209 , 213 ). 14. Beam steering device with a mirror grating according to claim 13, characterized in that linear lenses ( 200 , 201 ) are arranged in front of and behind the mirror grating ( 204 , 209 , 213 ). 15. A beam steering device according to claim 3 for using solar energy, characterized in that the aperture extends in the east-west direction, and in that the beams ( 22 ) have two mirror strips ( 1 , 2 , 27 , 28 ) formed mirror grids ( 20 , 21 , 60 , 61 , 90 , 91 , 154 ) and then through a concentrating device ( 63 , 86 , 93 , 160 ) onto a radiation converter ( 71 , 71 H, 99 , 140 ) can be concentrated. 16. Radiation steering device according to claim 1, characterized in that the mirror gel strips ( 181 ) are pivotable ver about an axis running parallel to the mirror strips. 17. beam steering device with concentrating optics according to claim 15, characterized in that a further mirror grating ( 86 , 86 D, 86 H) with perpendicular to the mirror strips of the first mirror grating ( 60 , 61 , 90 , 90 H, 91 ) extending The streak of mirrors is penetrated by the rays. 18. Beam steering device according to claim 17, characterized in that the mirror strips of a mirror grating ( 86 , 86 D, 86 H), the mirror strips of which run in the east-west direction, are adjustable so that the emerging rays form a bundle of rays ( 64 H) form, in the focal area of which there is a radiation converter ( 71 H). 19. Beam steering device with concentrating optics according to claim 18, characterized in that below the mirror grating ( 90 H) another mirror grating ( 86 H), the mirror strips of which are aligned at right angles to the vertical plane in which the sun rays lie. 20. Beam steering device with concentrating optics according to claim 1, characterized in that the mirror strips ( 30 s, 31 s) are electrically conductive, and that between adjacent mirror strips ( 30 s, 31 s) an electrical conductor ( 32 s) is tense, and that a high voltage between mirror strips ( 30 s, 31 s) can be applied. 21. Beam steering device according to claim 1, characterized in that each mirror strip ( 40 ) between pivot bearings ( 41 , 159 H) is suspended and pivotable about its longitudinal axis. 22. Radiation steering device according to claim 1, characterized in that the mirror strips ( 75 , 76 ) contain permanent magnetic substance and that over arcs ( 78 ) whose radii are greater than half the width of the mirror strips ( 75 , 76 ) distributed electrically conductive wires ( 77 a to 77 f) are stretched, which run parallel to the mirror strips. 23. Radiation steering device with concentrating optics according to claim 16, characterized in that a radiation converter ( 99 , 140 ) lies in the pivot bearing region of the housing ( 92 ) pivotable about the east-west axis. 24. Beam steering device with concentrating optics according to claim 15, characterized in that the concentrator consists of a linear lens ( 63 , 93 , 160 ), in whose prism-forming stages ( 64 , 65 , 66 ) a total reflection of the penetrating rays ( 67 , 95 ) takes place. 25. Beam steering device according to claim 15, characterized by the following features:

• a) a housing ( 53 , 92 ) which is covered in the direction of the sun by a disk ( 54 , 94 ) and which can be pivoted about a geometric axis ( 58 , 100 ) running in the east-west direction,
• b) the housing ( 53 , 92 , 149 ) is tracked operationally so that the normal ( 60 a) on the disc ( 54 , 94 , 94 H) lies in the plane of the sun,
• c) a first mirror grating ( 20 , 60 , 90 ) with mirror strips ( 39 , 40 ), the longitudinal axes of which run perpendicular to the geometric axis of the housing ( 53 , 92 , 149 , 156 ), lies behind the cover plate ( 54 , 94 , 94 H) and runs essentially parallel to it,
• d) a second mirror grating ( 21 , 61 , 91 ) with mirror strips ( 28 ), which run parallel to the mirror strips ( 27 , 28 , 40 ) of the first mirror grating ( 20 , 60 , 90 ), lies behind the first mirror grating when viewed in the direction of radiation .
• e) the pivoting angle of the mirror strips of the two mirror grids ( 20 , 21 , 60 , 61 , 90 , 91 ) which can be pivoted within a predetermined angular interval are selected as a function of the respective height of the sun so that the rays ( 22 ) as a function of their angle of incidence on the cover plate ( 54 , 94 , 94 H) within a predetermined angular interval to the normal ( 60 a, 80 ) on the cover plate ( 54 , 94 , 94 H), within an angular interval emerge from the second mirror grille ( 21 , 61 , 91 ) .
• f) on the side of the mirror grids ( 20 , 21 , 60 , 61 , 90 , 91 ) facing away from the sun, a concentrating device ( 63 , 93 , 160 ) is arranged, the aperture dimension of which approximates that of the cover plate ( 54 , 94 , 94 H) coincides
• g) in the focal area of the concentrating device ( 63 , 93 , 160 ) there is a radiation converter ( 71 , 99 , 140 ).

26. Radiation steering device according to claim 15 for the production of solar energy, characterized in that below the mirror grille ( 90 , 154 ) closes a room whose vertical section running from south to north contains a triangle, the south-facing wall ( 149 ) is smaller than the north-facing wall ( 156 ) and that the photocell ( 90 , 140 ) is located in the tip region of the triangle. 27. Beam steering device according to claim 26, characterized in that the con centering device ( 160 ) is a linear lens with a first region ( 143 ) which forms a Fresnel lens and consists of a more deflecting second region ( 144 ), in the prisms of which Total reflection takes place. 28. Beam steering device according to claim 1, characterized by rods ( 36 , 37 ) extending at right angles to the mirror strips, which extend above and below the mirror strips ( 39 , 40 ) and accommodate them between them at defined points ( 38 ) and by opposing longitudinal movement cause the mirror grids to pivot. 29. Beam steering device according to claim 28, characterized in that the inter mediate mirror strip holding rods ( 36 , 37 ) consist of elastic material or springs, and that the mirror strips ( 40 H, 41 H) by pivoting the levers in opposite directions ( 34 H, 35 H) enclose angles deviating from the parallel assignment, so that the mirror strips fan out. 30. beam steering device with concentrating optics according to claim 28, characterized in that the ends of the rods ( 36 , 37 , 36 H, 37 H) are articulated with pivot levers ( 34 , 35 , 34 H, 35 H) are connected, which in turn can be pivoted about axes ( 32 , 32 H, 33 ). 31. Beam steering device according to claim 1, characterized in that the pivotably arranged mirror strips ( 1 , 26 , 27 , 28 , 39 , 40 , 40 H, 41 H, 154 ) are suspended in the longitudinal direction under tension. 32. beam steering device according to claim 15, characterized in that the mirror strips ( 158 ) carry stub axles ( 159 H), via which the pivoting movement of toothed segments ( 161 ) engage in which screws ( 165 H) on the associated mirror strips ( 158 ) is transferred. 33. beam steering device according to claim 25, characterized in that the foot area with the photocell ( 140 ) is immersed in a water layer ( 150 ). 34. beam steering device according to claim 15 or 33, characterized in that the water layer ( 150 ) is protected by a film ( 151 ) against evaporation. 35. beam steering device according to claim 1, characterized in that a connection to the beam steering device ( 81 D, 82 D, 86 D) ( 83 D) connecting the connection between the beam steering device ( 81 D, 82 D, 86 D) and a diffusing lamp ( 103 ) that serves to illuminate the room. 36. Beam steering device according to claim 1, characterized in that the mirror strips of the upper and lower mirror layers are formed from two sections which are connected to one another by an articulated seam ( 165 ), the upper end of the mirror strips via clamping pieces ( 167 ) is pivotally mounted in the axial walls ( 168 ). 37. beam steering device according to claim 36, characterized in that the lower right region of the mirror strips ( 166 ) of the mirror grating at the axial ends has clamping pieces ( 170 ) which are held by molded parts ( 173 ) at a distance from the neighboring mirror strip. 38. beam steering device according to claim 37, characterized in that the clamping pieces ( 170 ) have a bore ( 171 ) through which a rope ( 172 ) is drawn, on which the molded parts ( 173 ) are fixed immovably. 39. beam steering device according to claim 11, characterized in that the second plurality of mirror strips ( 192 ) is held together by helix ( 191 ). 40. beam steering device according to claim 39, characterized in that the Zun gene ( 193 ) of push rods ( 193 a) move mirror strips from the spread group ( 185 , 188 ) in the pushed together group ( 192 ). 41. beam steering device according to claim 39, characterized in that the Tei the mirror strips can be changed operationally.