NL2005311C2 - SOLAR PANEL COMPOSITION. - Google Patents

Abstract

Solar panel assembly for collecting sunlight, comprising an underframe, a first solar panel holder and a solar panel, wherein the first solar panel holder comprises a basis having a circumference onto which a drive engages for rotation of the first solar panel holder with respect to the underframe about a vertical rotation axis, wherein with respect to the first solar panel holder the solar panel is rotatable about a horizontal rotation axis, wherein the vertical rotation axis is perpendicular to the horizontal rotation axis and intersects the horizontal rotation axis in an intersection, wherein the solar panel assembly is provided with a second solar panel holder which, when viewed parallel to the vertical rotation axis, is situated fully within the circumference of the basis of the first solar panel holder, wherein the second solar panel holder is rotatable with respect to the underframe about a parallactic rotation axis, wherein the parallactic rotation axis intersects the intersection of the horizontal rotation axis and the vertical rotation axis.

Description

NLP187391A

Solar panel assembly

BACKGROUND OF THE INVENTION

The invention relates to a solar panel assembly.

A solar panel assembly for receiving sunlight is known, comprising a solar panel and a holder which carries the solar panel at an angle with respect to the horizontal surface. From the earth's perspective, the sun moves in a complex non-linear motion across the sky. The position of the solar panel in the known solar panel assembly is inaccurate relative to the movement of the sun, as a result of which the yield due to the incident sunlight on the solar panel is less optimal.

It is an object of the invention to provide a solar panel assembly with an improved incidence of light relative to the sun.

SUMMARY OF THE INVENTION

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The invention provides from a first aspect a solar panel assembly for collecting sunlight, comprising a base to be placed on a substrate, a first solar panel holder supported by the chassis and a solar panel supported by the first solar panel holder, wherein in the condition arranged on the substrate first solar panel holder is rotatable relative to the chassis about a vertical axis of rotation, wherein the solar panel is rotatable relative to the first solar panel holder about a horizontal axis of rotation, wherein the vertical axis of rotation is perpendicular to the horizontal axis of rotation and intersects the horizontal axis of rotation, wherein the solar panel assembly is provided with a second solar panel holder 10 which is rotatably coupled to the solar panel on a first side and which is rotatably coupled to the second side of the second solar panel holder and to the vertical axis of rotation rotatably to the second side chassis, wa the second solar panel holder is rotatable relative to the frame about a parallactic axis of rotation, wherein the parallactic axis of rotation intersects the intersection of the horizontal axis of rotation and the vertical axis of rotation.

The assembly of the first solar panel holder and the second solar panel holder provides a movement mechanism 20 which is arranged to keep the solar panel pivotally oriented optimally towards the sun about the horizontal axis of rotation. In this way the incidence of light on the solar panel can be optimized in order to achieve an optimum efficiency.

In one embodiment, the second solar panel holder is coupled to the solar panel on the first side with a first rotation bearing, the first rotation bearing having a field rotation axis extending through the intersection. The second solar panel holder can rotate in the first rotation bearing about the field rotation axis, in order to rotate the solar panel within the freedom of movement thereof about the horizontal rotation axis.

In one embodiment, the second solar panel holder is coupled to the chassis on the second side with a second rotation bearing, the rotation axis of the second rotation bearing coinciding with the parallactic rotation axis. The second solar panel holder can rotate in the second rotation bearing about the parallactic, in order to rotate the solar panel within the freedom of movement thereof about the horizontal axis of rotation.

In one embodiment the second solar panel holder comprises a control arm, the control arm comprising a first segment which is coupled to the second rotation bearing and which is located on the parallactic axis of rotation, a second segment connecting the first segment and the second segment which deflects from the first segment of the parallactic axis of rotation and a third segment coupled to the first rotation bearing 10 bridges the distance between the deflection of the second segment and the intersection in the solar panel. Due to the curved shape of the control arm composed of the first, second and third segment, the control arm on the first side and the second side can be coupled to the first rotation bearing and the second rotation bearing, respectively, in line with the axis of rotation thereof.

In an embodiment the third segment of the control arm is provided with a connecting element which is adapted to fix the third segment at a position along the longitudinal direction of the second segment. The solar panel can be fixed at an angle with respect to the parallactic axis of rotation with the aid of the connecting element, in order to compensate for the variation in the movement of the sun through the sky observed from planet earth during the seasons.

In one embodiment, the solar panel assembly comprises a step-by-step drive for stepwise adjusting the position of the field rotation axis with respect to the parallactic axis during the course of the seasons. With the aid of the step-by-step drive, the solar panel can be automatically fixed daily at a daily changing angle with respect to the parallactic axis of rotation, in order to automatically adjust the variation in the orbit of the sun through the sky observed from planet earth during the seasons. to compensate.

In one embodiment the chassis is provided with a drive which engages the first solar panel holder for rotation of the first solar panel holder relative to the chassis about the vertical axis of rotation. The solar panel holder can be driven from the chassis by the drive placed on the chassis 5 outside the first solar panel holder.

In one embodiment, the drive is provided with a drive pinion and a drive belt connected to the drive pinion, the first solar panel holder being provided with a circular cylindrical base, the drive engaging a first solar panel holder around a portion of the circumference of the circular cylindrical base. The base of the solar panel holder has a circular cylindrical outer circumference that can be driven by the drive in a favorable transfer ratio.

In one embodiment, the solar panel assembly is provided with a control unit, which measures the rotation speed of the second solar panel holder about the parallactic axis of rotation and compares it with a fixed or linear angular speed, the control unit being adapted to adjust the drive on the basis of the comparison. in order to make the rotation of the second solar panel holder about the parallactic axis of rotation linear. Through this measurement and control feedback, the drive can be controlled non-linearly in order to achieve a linear rotation of the second solar panel holder about the parallactic axis.

In one embodiment the drive is provided with the control unit adapted for linear rotation of the second solar panel holder in a twenty-four hour cycle about the parallactic axis of rotation. As a result, the rotation speed of the second solar panel holder about the parallactic axis is synchronous with the rotation speed of the earth.

In one embodiment, the parallactic axis of rotation is parallel to the polar line or polar axis of planet Earth. The parallelism of the parallactic axis of rotation with respect to the polar axis of planet Earth can compensate for the skew of the undercarriage on the curved surface of the earth with respect to the polar axis.

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In one embodiment the first solar panel holder is provided with two vertically upright supports between which the solar panel is arranged, the upright supports being provided with bearings for rotation of the solar panel about the horizontal axis of rotation. This allows the solar panel to be suspended symmetrically within the outer circumference of the base of the first solar panel holder.

In one embodiment, the solar panel comprises a flat plate, the plate being provided with photovoltaic cells on one side. The photovoltaic cells can absorb the sun's rays falling on the plate and convert their solar energy into electricity.

In one embodiment, the solar panel comprises a lens or mirror that converges sun rays that fall substantially parallel to the lens or mirror, the solar panel being provided with a focal point of the lens or mirror located at a distance from the lens or mirror. solar power inverter. The lens or mirror can bend the sun's rays falling onto the lens mirror so that they converge at a focal point located at the location of the solar collector. The solar energy converting device, for example a solar collector, can convert the solar energy of the bundled sun rays into electricity.

The invention provides a series of solar panel assemblies for collecting sunlight from a second aspect, wherein each solar panel assembly comprises a chassis to be placed on a substrate, a first solar panel holder carried by the chassis and a solar panel supported by the first solar panel holder, The first solar panel holder is rotatable relative to the chassis about a vertical axis of rotation, wherein the solar panel is rotatable relative to the first solar panel holder about a horizontal axis of rotation, the vertical axis of rotation being perpendicular to the horizontal axis of rotation and the horizontal axis of rotation. cuts into a point of intersection, wherein the solar panel assembly is provided with a second solar panel holder which is rotatably coupled to the solar panel on a first 6 side and which rotates on a second side the first side of the second solar panel holder and remote from the vertical axis of rotation. is vertically coupled to the chassis, wherein the second solar panel holder is rotatable relative to the chassis about a parallactic axis of rotation, wherein the parallactic axis of rotation intersects the intersection of the horizontal axis of rotation and the vertical axis of rotation, the series being provided with a drive which engages the solar panel holders 10 of the successive solar panel assemblies, for simultaneous rotation of all first solar panel holders of the series relative to the chassis about the vertical rotation axes. The linear or constant rotations of the second solar panel holder about the parallactic axis of rotation provide effective non-linear rotations of the solar panels about both the vertical axis of rotation and its horizontal axis of rotation.

In an embodiment the drive is provided with drive pinion and a drive belt connected to the drive pinion, wherein first solar panel holders are provided with a circular cylindrical base, the drive belt on each of the circular cylindrical base engaging at least a part of the circumference on the first solar panel holders. The solar panel holders can easily be driven from the frame by the drive placed on the frame.

In one embodiment, the circular cylindrical bases are located in the same horizontal plane and, in use, the drive drives the circular cylindrical bases in that horizontal plane. The drive can in this simple manner rotate a series of solar panels simultaneously and synchronized with non-linear rotation movements about the vertical rotation axes and the horizontal rotation axes.

The invention provides from a third aspect a method for collecting sunlight with a solar panel assembly, wherein the solar panel assembly comprises a chassis to be placed on a substrate, a first solar panel holder carried by the chassis 7 and a solar panel supported by the first solar panel holder, wherein in the condition arranged on the substrate, the first solar panel holder is rotatable relative to the chassis about a vertical axis of rotation, wherein the solar panel is rotatable relative to the first solar panel holder about a horizontal axis of rotation, the vertical axis of rotation being perpendicular to the horizontal axis of rotation and the horizontal axis of rotation intersects at an intersection, wherein the solar panel assembly 10 is provided with a second solar panel holder which is rotatably coupled to the solar panel on a first side and which is remote from the first side of the second solar panel holder on a second side and from the vertical rotation the shaft is rotatably coupled to the chassis, wherein the second solar panel holder is rotatable relative to the chassis about a parallactic axis of rotation, wherein the parallactic axis of rotation intersects the intersection of the horizontal axis of rotation and the vertical axis of rotation, wherein the solar panel assembly is provided with a drive Engages the first solar panel holder for rotation of the first solar panel holder relative to the chassis about the vertical axis of rotation, the method comprising rotating the first solar panel holder about the vertical axis by means of the drive, and due to the rotation of 25 moving the first solar panel holder from the solar panel, rotating the second solar panel holder about the parallactic axis due to the movement of the solar panel, measuring the rotational speed of the second solar panel holder about the parallactic axis, comparing the rotation speed of the second solar panel h older about the parallactic axis with a constant or fixed angular velocity, adjusting the drive on the basis of the comparison so that the rotation speed imposed by the first solar panel holder via the solar panel on the second solar panel holder is linear around the parallactic axis, due to cause the rotation of the second solar panel holder to rotate about the parallactic axis of rotation of the solar panel about the horizontal axis of rotation. The rotation position of the solar panel about the horizontal axis of rotation and the rotation position of the first solar panel holder about the vertical axis of rotation can in this way be accurately controlled non-linearly in order to correspond to the movement of the sun through the sky observed from planet Earth.

In one embodiment, a complete rotation of the second solar panel holder about the parallactic axis takes twenty-four hours. As a result, the rotation speed of the second solar panel holder about the parallactic axis is the same as the rotation speed of the earth.

In one embodiment, the solar panel is oriented at least half a rotation about the vertical axis of rotation with the main surface facing the sun. During the half rotation about the vertical axis of rotation, the solar panel can collect solar energy and convert it into electricity.

In one embodiment, the solar panel is for at least half a rotation about the vertical axis of rotation with the main plane perpendicular to the sun. During the half rotation about the vertical axis of rotation, the solar panel can collect solar energy perpendicularly and convert it optimally into electricity.

In one embodiment the solar panel is in a starting position focused on the sunrise and in an end position focused on the sunset, wherein the drive is arranged to move the solar panel between the starting position and the ending position in a synchronized tracking movement with the sun. The solar panel can follow from the sunrise in the east to the sunset in the west around the vertical axis of rotation in order to collect solar energy and optimally convert it into electricity.

The aspects and measures described in this description and claims of the application and / or shown in the drawings of this application can, where possible, also be applied separately from each other. Those individual aspects and other aspects may be the subject of split-off patent applications directed to them.

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This applies in particular to the measures and aspects that are described per se in the subclaims.

5 BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be elucidated on the basis of a number of exemplary embodiments shown in the attached schematic drawings. Shown are: figure 1 a side view of a solar panel assembly according to the invention, figure 2 a side view of the planet earth with the solar panel assembly according to figure 1, figure 3A-F schematic representations of the operation of the solar panel assembly according to figure 1 at following the sun from planet earth, figure 4 shows an alternative embodiment of a solar panel assembly according to the invention, figure 5 shows a further alternative embodiment of a solar panel assembly according to the invention.

DETAILED DESCRIPTION OF THE DRAWINGS

Figure 1 shows a solar panel assembly 1 according to the invention for following the sun from the planet earth. The solar panel assembly 1 comprises a horizontal frame 2, a first solar panel holder 3 placed on the frame 2 and a solar panel 4 carried by the first solar panel holder 3.

The chassis 2 is provided with a first rotation bearing 21 which couples the first solar panel holder 3 to the chassis 2 and a drive means 22 which is coupled to the first solar panel holder 3 by means of a drive belt 23. The first rotation bearing 21 has a vertical axis of rotation V relative to the horizontal chassis 2, which axis passes through the symmetrical center of the first solar panel holder 10. The vertical axis of rotation V is substantially perpendicular to the interface of the curved surface of the planet Earth at the location where the solar panel assembly 1 is arranged.

As shown in figure 1 and figure 3A, the first solar panel holder 3 comprises a circular cylindrical base 32 which is placed on the first rotation bearing 21. The circular cylindrical base 32 is externally provided with a ridge structure 37 on which the drive belt 23 engages. Because the circular cylindrical base 32 has a considerably larger diameter than the drive pinion 22, a favorable transmission ratio can be achieved. Alternatively, the solar panel assembly 1 may comprise a chain or gear drive. The first solar panel holder 3 is provided with a first support 33 and a second support 34, which extend vertically upwards from the base 32 on opposite sides thereof. The first support 33 and the second support 34 are provided at their free end with a second rotation bearing 2 and a third rotation bearing 36, respectively, which have a common, horizontal axis of rotation X.

As shown in Fig. 3B, the solar panel 4 in this example comprises a rectangular plate 41 with a straight main surface and a number of photovoltaic cells 42 mounted on the upwardly directed main surface of the solar energy plate 41 and converting it into electricity. The solar panel 4 is supported in the center of the short sides by the second rotation bearing 35 and the third rotation bearing 36. The horizontal rotation axis X of the second rotation bearing 35 and the third rotation bearing 36 extends through the plate 41, and falls together with the longitudinal axis of the plate 41. The longitudinal axis of the plate 41 divides the plate 41 into two equal parts.

As shown in Figure 3A, the solar panel 4 in the center of the plate 41 is provided with a fourth rotation bearing 45 with a field rotation axis S which is perpendicular to the main surface of the plate 41. The field rotation axis S intersects the vertical rotation axis V of the first rotation bearing 21 and the horizontal rotation axis X of the second rotation bearing 35 and the third rotation bearing 36 at the intersection point B. The intersection point B is located in the symmetrical center of the plate 41, at the 5 longitudinal center line thereof. In an alternative embodiment, the plate 41 may be offset perpendicular to the field rotation axis S and spaced apart from the horizontal axis of rotation X, for example when the plate 41 is mounted on a spacer (not shown) which at the horizontal axis of rotation X the second rotation bearing 35 and the third rotation bearing 36 are connected. The plate 41 in that case rotates at a distance from the horizontal axis of rotation X about the horizontal axis of rotation X.

The solar panel assembly 1 comprises a second solar panel holder 5 which couples the chassis 2 to the solar panel 4. The second solar panel holder 5 is provided with a fifth rotation bearing 51 which is fixedly connected to the base 2 in an upright position of the base 2. The fifth rotation bearing 51 has a parallactic axis of rotation P which is at an oblique angle with respect to the base 2. As in Fig. 1, the second solar panel holder 5 comprises a form-retaining, curved control arm 52. The control arm 52 is provided with a first straight segment 53 which is inserted with the free end thereof in the fifth rotation bearing 51. The first straight segment 53 is located on the parallactic axis of rotation P for rotation about the parallactic axis of rotation P about its axis. The first straight segment 53 merges into a second straight segment 54 via a curvature. The second straight segment 54 deflects from the parallel rotation axis P and, viewed from the first straight segment 53, faces away from the main surface of the plate 41 . As a result of this deflection, the solar panel 4 can run free from the control arm 52 in steep positions relative to the chassis 2. The second straight segment 54 passes through a curvature 35 into a third straight segment 55 that the distance between the deflection of the second straight segment 54 and the intersection point B. The third straight segment 55 is inserted with its free end 12 into the fourth rotation bearing 45 of the solar panel 4. The third straight segment 55 is located on the field rotation axis S for rotation about the field rotation axis S about its axis. The rigid control arm 52 is limited to 5 rotational movements about the parallactic axis of rotation P and the field axis of rotation S.

The parallactic axis of rotation P intersects the vertical axis of rotation V, the horizontal axis of rotation X and the field axis of rotation S at the intersection point B. By meeting the rotation axes P, X, V and S at the point of intersection B and by the symmetrical location of the point of intersection B within the first solar panel holder 3, forces between and / or in parts as a result of the rotational movements are counteracted.

The second solar panel holder 5 is provided with an angle sensor 56, for example a potentiometer, for recording the rotation angle or rotation position of the control arm 52 about the parallactic axis of rotation P, a timer 57 and a control unit 58 for controlling the drive pinion 22 .

Figure 2 shows diagrammatically that the earth surface 9, which is generally perceived as being substantially horizontal, is tilted by the curvature of the earth surface 9 relative to the plane stretched by the equator E, unless the North or South Pole. The placement of the solar panel assembly 1 on the curved earth surface 9 at a distance from the North or South

South Pole, therefore, causes the vertical axis of rotation V to be at a different angle to the polar line or polar axis Q of planet Earth. Because of this deviating angle of the vertical axis of rotation V relative to the polar axis Q and because the planet earth rotates about the polar axis Q, following the sun from a location other than the North or South pole is subject to a complex combination of rotations. The ratio of the solar panel assembly 1 in Fig. 2 in relation to the size of the earth is, for the sake of clarity, strongly represented.

As shown in Figure 1, the parallactic rotation axis P of the fifth rotation bearing 51 is at an oblique angle with respect to the horizontal chassis 2. The parallactic rotation axis P of the fifth rotation bearing 51 must be parallel to the pole axis Q of the planet earth. perpendicular to the plane stretched by the 5 equator E of the earth.

The solar panel assembly 1, as shown in Fig. 3A, is adapted to accurately follow the sun from a certain location on the earth's surface, such that the main surface of the plate 41 remains directed perpendicular to the sun. The rotation of the rigid control arm 52 about the parallactic axis of rotation P is measured and compared with a regular signal of the time clock 57. The difference of the rotational speed of the rigid control arm 52 with respect to the regular signal of the time clock 57 becomes is processed in the control unit 58 into a control signal for the drive pinion 22, such that the control arm 52 rotates opposite to the direction of rotation of the planet earth about the polar axis about the parallactic axis of rotation P with a constant or linear angular velocity proportional to time. As a result of the rotation of the control arm 52, the solar panel 4 coupled to the control arm 52 rotates about the parallactic rotation axis P within the rotational freedoms imposed by the first rotation bearing 21, the second rotation bearing 35 and the third rotation bearing 36 about the vertical rotation axis V and the horizontal rotation axis X. The rotation of the solar panel 4 about horizontal rotation axis X imposed by the control arm 52 and the rotation of the first solar panel holder 3 driven by the drive belt 23 about the vertical rotation axis V result in a slavish rotation of the solar panel 4 about the horizontal rotation axis X and the vertical rotation axis V.

Figures 3A-F show a series of three solar panel assemblies 1 arranged in a straight line according to Figure 1. The solar panel assemblies 1 can form part of a longer series of solar panel assemblies 1, for example on a roof of a building. Because the bases 32 of the successive solar panel assemblies 1 lie in the same horizontal plane, the solar panel assemblies 1 within the array in the same horizontal plane can be jointly driven by the drive belt 23 of one drive pinion 22. The drive belt 23 is lengthwise for this purpose 5 adapted to form a loop around the entire series of solar panel assemblies 1. The drive belt 23 therefore engages at least a portion of the circumference of each base 32 of successive solar panel assemblies 1. The solar panel holders 3 of the solar panel assemblies 1 are in the same 10 starting position and are driven simultaneously, so that they move synchronously. In principle, only one of the solar panel assemblies 1 from the series must be provided with an angle sensor 56. The other solar panel assemblies 1 then slave slavishly on the basis of the movement of the one solar panel assembly 1.

Figures 3A-F show six consecutive snapshots of the rotations of the solar panels 4 about the horizontal rotation axis X and the vertical rotation axis V. Because all solar panel assemblies 1 from the series move synchronously from the same starting position, the rotational movements within only one have been chosen below of the solar panel assemblies 1.

Figure 3A shows the solar panel assembly 1 in the starting situation, for example at sunrise in the east. 25 For the sake of clarity, a schematic compass is shown with the four main winds north N, east O, south Z and west W. Due to the large distance between the sun and the earth, the sun's rays hit the surface of the earth parallel to each other. The direction of the sun's rays relative to the solar panel assembly 1 is indicated by arrow C.

The solar panel 4 is rotated about a horizontal axis of rotation X at a steep, almost vertical angle of inclination with respect to the horizontal frame 2. The side of the plate 41 provided with photovoltaic cells 42 is oriented substantially eastwards, the side of the plate 41 with the photovoltaic cells 42 is directed substantially perpendicular to the direction of the sun's rays C in order to achieve an optimum absorption of solar energy by the photovoltaic cells 42.

Figure 3B shows the situation in which the drive pinion 22 has rotated the drive belt 23. The drive belt 23 has rotated the first solar panel holder 3 for a few hours about the vertical axis of rotation V from the east 0 in the direction of the southeast SE. The rotational movement of the first solar panel holder 3 about the vertical rotation axis V is transmitted via the second rotation bearing 35 and the third rotation bearing 36 to the solar panel 4. The solar panel 4 has rotated about the horizontal rotation axis X within the rotation freedom imposed by the control arm 52. It is now a few hours after sunrise and the sun has risen higher in the sky 15 observed from planet Earth. The angle of inclination of the plate 41 has decreased, so that the side of the plate 41 with the photovoltaic cells 42 has remained substantially perpendicular to the continuously changing direction of the sun's rays C.

In the elapsed time between the snapshots in Figures 3A and 3B, the angle sensor 56 has measured the rotation speed of the control arm 52 about the parallactic axis of rotation P. A complete rotation of the planet earth about the polar axis takes place in twenty-four hours, whereby the rotation about the parallactic axis of rotation P, which is after all parallel to the polar axis, can be brought into linear relation with the elapsed time. If the rotation of the control arm 52 about the parallactic axis of rotation P is too fast relative to the pulses of the timer 57, the drive pinion 22 is delayed by the control unit 58. If the rotation about the parallactic axis of rotation P is too slow with respect to the pulses of the timer 57, the drive pinion 22 is accelerated or less decelerated by the control unit 58. The rotations of the solar panel 4 about the vertical axis of rotation V and the horizontal axis of rotation X are therefore non-linear and dependent on the constant or linear rotation of the control arm 52 about the parallactic axis of rotation P and are correspondingly determined by the 16 measuring and control units 56, 58 based on the pulses of the timer 57.

Figures 3C-F show snapshots of the continued rotation of the first solar panel holder 3 from the southeast SE toward the west W due to the driven rotation about the vertical axis of rotation V and the rotation of the solar panel 4 within the rotational freedoms imposed by the control arm 52 about this horizontal axis of rotation X. During this continued rotation, the side of the plate 41 with the photovoltaic cells 42 remains directed substantially perpendicular to the continuously changing direction of the sun's rays C.

In figure 3C, the solar panel 4 is positioned substantially towards the southeast SE, wherein the angle of inclination of the plate 41 relative to the horizontal frame 2 is further reduced.

In figure 3D, the solar panel 4 is oriented substantially towards the south Z, wherein the angle of inclination of the plate 41 relative to the horizontal undercarriage 2 is further reduced. The sun is now at the highest point in the sky observed from 20 on Earth, for example around noon, or has just passed there.

In figure 3E, the solar panel 4 is oriented substantially towards the southwest SW, with the angle of inclination of the plate 41 relative to the horizontal frame 2 increasing.

In Fig. 3F, the solar panel 4 faces substantially west W, the angle of inclination of the plate 41 relative to the horizontal undercarriage 2 further increasing to an almost vertical position. The sun is at the bottom of the sky observed from planet Earth.

Between the situations shown in Figures 3A and 3F, the solar panel assembly 1 has rotated at least half a turn or one hundred and eighty degrees around the vertical axis of rotation V. To return from the position as shown in Figure 3F to the starting position as shown in Figure 3A, the first solar panel holder 3 can be further rotated by the drive belt 23 about the vertical axis of rotation V over the north N up to the east 0. Wiring between the solar panel 4 and the chassis 2 can in that case be provided with electrical sliding contacts. Alternatively, the drive 5 direction of the drive pinion 22 can be reversed, with the drive belt 23 rotating the first solar panel holder 3 a half turn the other way or one hundred and eighty degrees back from the west W over the south Z to the east O Wiring between the solar panel 4 and the undercarriage 2 can in that case be provided more simply, because there is only a limited rotation through one hundred and eighty degrees of the first solar panel holder 3 about the vertical axis of rotation V.

In this example, the solar panel assembly 1 is arranged in the northern hemisphere of planet Earth, where the sun rises in the sky observed from the northern hemisphere in the east O, rotates over the south Z and sets in the west W. On the southern In the hemisphere, the sun rises in the east 0, rotates over the north N and goes below it in the west W. In that case the solar panel assembly 1 according to figure 1 can be driven oppositely by the drive pinion 22, of which it is important the solar panel assembly 1 can be arranged such that the side of the plate 41 with the photovoltaic cells 42 rotates from the east O 25 over the north N to the west W instead of over the south Z.

In this example, the solar panel assembly 1 is arranged at a certain latitude from the North Pole of planet Earth. Depending on the position of the solar panel assembly 1 along the latitude, the angle of the parallactic axis of rotation P relative to the horizontal frame 2 changes. In that case, it is possible to opt for another fifth rotation bearing 51 with a different angle of inclination of the parallactic axis of rotation P or an alternative, not shown, adjustable fifth rotation bearing.

Figure 4 shows an alternative embodiment of the solar panel assembly 101 with seasonal adjustment.

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The solar panel assembly 101 comprises an alternative control arm 152 which is provided with a first hinge 160 in the transition from the second segment 154 to the third segment 155 and which is provided in the transition from the first segment 153 to the second segment 154 of a second hinge 163. The first hinge 160 provides a rotation of the field rotation axis S about the intersection point B in the direction of the arrow K for fixing the solar panel via the third segment 155 at different angles of inclination with respect to the parallactic rotation axis P 4 on the second segment 154 of the control arm 152. The second hinge 163 receives the rotation of the second segment 154 as a result of the displacement of the third segment 155 along the second segment 154. The control arm 152 is provided with a hollow sleeve 161 which is slid over the second segment 154 and a wing bolt 162 extending through a recess in the hollow sleeve 161 and engaging a screw thread on the inside thereof. The hinge 160 can be fixed by tightening the wing bolt 162 in the longitudinal direction of the second segment 154 on the second segment 154 in order to fix the field rotation axis S and the parallactic rotation axis P at an angle with respect to each other. This adjustability can be used to compensate for the slightly varying orbit of the sun through the sky observed from the earth 25 during the seasons, so that the side of the plate 41 provided with photovoltaic cells 42 always remains perpendicular to the direction of the sun's rays C.

In an alternative, not shown, embodiment of the solar panel assembly 101 with seasonal adjustment, control arm 152 is provided with an automatic seasonal adjustment of the solar panel with a cycle of three hundred sixty-five days. This seasonal adjustment can be realized, for example, by transferring the rotation steps of a stepwise drive via a worm wheel to a gear wheel which is rotatably mounted on the second segment 154. A complete rotation of the gear takes 19 three hundred and sixty-five steps of a day. The third segment 155 is eccentrically mounted on the gear so that the position of the third segment 155 relative to the second segment 154 shifts back and forth in the longitudinal direction of the second segment 154 during the rotation of the gear in 5 years.

Figure 5 shows a further alternative embodiment of the solar panel assembly 201. The solar panel assembly 201 comprises a lens 241, for example a Fresnel type lens, which instead of the solar panel 4, as shown in Figures 1-4, is placed in the solar panel holder. The lens 241 captures the substantially parallel sun rays from direction C and converges them in the focal point F. The focal point F in this example lies on the field rotation axis S, but can also be located laterally with respect to the field rotation axis S due to adjustment of the lens characteristics. to be. The solar panel assembly 201 is provided with a solar energy inverter, for example a sterling motor or a solar collector 242 which is placed at a distance under the lens 241, for example on the transition from the second segment 154 to the third segment 155. The solar collector 242 is located in the focal point F of the lens 241, so as to capture and convert the sun's rays converging at the focal point F into electrical energy.

The above description is included to illustrate the operation of preferred embodiments of the invention, and not to limit the scope of the invention. Starting from the above explanation, many variations will be evident to those skilled in the art that fall within the spirit and scope of the present invention.

Claims (24)

A solar panel assembly for collecting sunlight, comprising a base to be placed on a substrate, a first solar panel holder supported by the chassis and a solar panel supported by the first solar panel holder, wherein in the condition arranged on the substrate the first solar panel holder is rotatable relative to the chassis about a vertical axis of rotation, wherein the solar panel is rotatable relative to the first solar panel holder about a horizontal axis of rotation, wherein the vertical axis of rotation is perpendicular to the horizontal axis of rotation and intersects the horizontal axis of rotation, wherein the The solar panel assembly is provided with a second solar panel holder which is rotatably coupled to the solar panel on a first side and which is rotatably coupled to the chassis on a second side at a distance from the first side of the second solar panel holder and at a distance from the vertical axis of rotation. second solar panel holder compared of the chassis is rotatable about a parallactic axis of rotation, wherein the parallactic axis of rotation intersects the intersection of the horizontal axis of rotation and the vertical axis of rotation. 2. Solar panel assembly according to claim 1, wherein the second solar panel holder is coupled to the solar panel with a first rotation bearing on the first side, the first rotation bearing having a field rotation axis extending through the intersection. 3. Solar panel assembly as claimed in claim 1 or 2, wherein the second solar panel holder is coupled to the chassis with a second rotation bearing on the second side, the rotation axis of the second rotation bearing coinciding with the parallactic rotation axis. 4. Solar panel assembly as claimed in any of the foregoing claims, wherein the second solar panel holder comprises a control arm, the control arm being successively provided with a first segment coupled to the second rotation bearing which is located on the parallactic rotation axis, a second segment which from the first segment of the parallactic axis of rotation deflects and a third segment coupled to the first rotation bearing that bridges the distance between the deflection of the second segment and the intersection in the solar panel. 5. Solar panel assembly as claimed in claim 4, wherein the third segment of the control arm is provided with a connecting element which is adapted to fix the third segment at a position along the longitudinal direction of the second segment. 6. Solar panel assembly as claimed in any of the foregoing claims, comprising a step-by-step drive for stepwise adjustment of the position of the field rotation axis relative to the parallactic axis during the course of the seasons. 7. Solar panel assembly as claimed in any of the foregoing claims, wherein the chassis is provided with a drive which engages the first solar panel holder for rotation of the first solar panel holder relative to the frame about the vertical axis of rotation. 8. Solar panel assembly as claimed in claim 7, wherein the drive is provided with a drive pinion and a drive belt connected to the drive pinion, the first solar panel holder being provided with a circular cylindrical base, the drive engaging around a portion of the circumference of the circular cylindrical base 30 on the first solar panel holder. 9. Solar panel assembly according to claim 7 or 8, wherein the solar panel assembly is provided with a control unit, which measures the rotation speed of the second solar panel holder about the parallactic axis of rotation and compares it with a fixed or linear angular speed, the control unit being arranged around the adjust drive based on the equation to make the rotation of the second solar panel holder about the parallactic axis of rotation linear. 10. Solar panel assembly as claimed in any of the claims 7-9, wherein the drive is provided with the control unit adapted for linear rotation of the second solar panel holder in a twenty-four hour cycle about the parallactic axis of rotation. 11. Solar panel assembly as claimed in any of the foregoing claims, wherein the parallactic axis of rotation is parallel to the polar line or polar axis of the planet earth. 12. Solar panel assembly as claimed in any of the foregoing claims, wherein the first solar panel holder is provided with two vertically upright supports between which the solar panel is arranged, wherein the upright supports are provided with bearings for rotation of the solar panel about the horizontal axis of rotation. 13. Solar panel assembly as claimed in any of the foregoing claims, wherein the solar panel comprises a flat plate, the plate being provided on one side with photovoltaic cells. 14. Solar panel assembly as claimed in any of the foregoing claims, wherein the solar panel comprises a lens or mirror that converges sun rays that fall substantially parallel to the lens or mirror, wherein the solar panel 25 is provided with a lens or mirror placed at a distance from the lens or mirror. focal point of the lens or mirror located solar energy conversion device. 15. A series of solar panel assemblies for collecting sunlight, wherein each solar panel assembly comprises a chassis to be placed on a substrate, a first solar panel holder carried by the chassis and a solar panel supported by the first solar panel holder, the first solar panel holder being arranged on the substrate is rotatable relative to the chassis about a vertical axis of rotation, wherein the solar panel is rotatable relative to the first solar panel holder about a horizontal axis of rotation, wherein the vertical axis of rotation is perpendicular to the horizontal axis of rotation and intersects the horizontal axis of rotation at an intersection, the solar panel assembly being provided with a second solar panel holder which is rotatably coupled to the solar panel on a first side and which is rotatably coupled to the chassis on a second side at a distance from the first side of the second solar panel holder and at a distance from the vertical axis of rotation, where the second solar panel holder is rotatable relative to the frame about a parallactic rotation axis, wherein the parallactic rotation axis intersects the intersection of the horizontal rotation axis and the vertical rotation axis, the series being provided with a drive which engages the solar panel holders of the successive solar panel assemblies for simultaneous rotation of all first solar panel holders of the series relative to the chassis about the vertical axes of rotation. 16. Series of solar panel assemblies according to claim 15, wherein the drive is provided with drive pinion and a drive belt connected to the drive pinion, wherein first solar panel holders are provided with a circular cylindrical base, the drive belt on each of the circular cylindrical base at least on a portion of the circumference engages the first solar panel holders. 17. Series of solar panel assemblies according to claim 16, wherein the circular cylindrical bases are located in the same horizontal plane and the drive in use drives the circular cylindrical bases in that horizontal plane. 18. Method for capturing sunlight with a solar panel assembly, wherein the solar panel assembly comprises a chassis to be placed on a substrate, a first solar panel holder carried by the chassis and a solar panel supported by the first solar panel holder, the solar panel disposed on the substrate condition the first solar panel holder is rotatable relative to the chassis about a vertical axis of rotation, wherein the solar panel is rotatable relative to the first solar panel holder about a horizontal axis of rotation, wherein the vertical axis of rotation is perpendicular to the horizontal axis of rotation and intersects the horizontal axis of rotation in a point of intersection, wherein the solar panel assembly is provided with a second solar panel holder which is rotatably coupled to the solar panel on a first side and which is rotatably mounted on a second side by distance the first side of the second solar panel holder and by distance from the vertical axis of rotation is coupled to the chassis, wherein the second solar panel holder is rotatable relative to the chassis 10 about a parallactic rotation axis, the parallactic rotation axis intersecting the intersection of the horizontal rotation axis and the vertical rotation axis, wherein the solar panel assembly is provided with a drive which engages the first solar panel holder for rotation of the first solar panel holder relative to the chassis about the vertical axis of rotation, the method comprising rotating the first solar panel holder about the vertical axis with the aid of the drive, causing the solar panel to move as a result of the rotation of the first solar panel holder rotating the second solar panel holder about the parallactic axis due to the movement of the solar panel, measuring the rotation speed of the second solar panel holder about the parallactic axis, comparing the rotation speed of the second solar panel holder about the parallactic axis with a constant or fixed angular speed, adjusting the drive on the basis of the comparison so that the rotation speed imposed by the first solar panel holder via the solar panel on the second solar panel holder runs linearly about the parallactic axis, as a result of the rotation of the second solar panel holder around the rotate parallactic axis of rotation of the solar panel about the horizontal axis of rotation. 19. Method as claimed in claim 18, wherein a complete rotation of the second solar panel holder about the parallactic axis lasts twenty-four hours. A method according to claim 18 or 19, wherein the solar panel is directed at the sun for at least half a rotation about the vertical axis of rotation with the main plane. 21. Method as claimed in any of the claims 18-20, wherein the solar panel is directed perpendicular to the sun for at least half a rotation about the vertical axis of rotation with the main surface. 22. Method as claimed in any of the claims 18-21, wherein the solar panel is directed to the sunrise in an initial position and is directed to the sunset in an end position, wherein the drive is arranged to move the solar panel 10 between the initial position and the final position in a synchronized tracking movement with the sun. 23. Solar panel assembly provided with one or more of the characterizing measures described in the attached description and / or shown in the attached drawings. 24. Method provided with one or more of the characterizing measures described in the attached description and / or shown in the attached drawings. -o-o-o-o-o-o-o-o-RM / FG