CZ16891U1 - System of photovoltaic cells on panels with positioning feature - Google Patents

Abstract

The present invention concerns to a set of photovoltaic cells on panels with an adjustable position, where the set comprises at least one movable supporting construction where panels equipped by photovoltaic cells are carried on, a foundation for carrying this movable supporting construction with photovoltaic cells, and a positioning driving device. The foundation (1) is consisting of two stands (11,12), having a different height, where each of them having on its top a supporting place (111,121), adjusted for a rocking coupling with a movable supporting construction (2), this movable supporting construction (2) being created as in longitudinal direction laying main longitudinal beam (21), to which supporting cross beams (23) are fixed in regular relative distances, corresponding the dimensions of the photovoltaic panels (22) with photovoltaic cells, where those supporting cross beams (23) are adjusted for carrying of said photovoltaic panels (22) with photovoltaic cells, and further, the ends of the main longitudinal beam (21) are adjusted for pivoting in bearing places (111,121) of the stands (11,12) of the foundation (1), where in the meantime, the positioning driving device is created as a linear electric drive (3) or hydraulic drive, coupled by a driving mechanical coupling (31) to a movable supporting construction (2) and connected by governing linkage (41) to a governing device (4).

Description

Technical field

The invention relates to photovoltaic cells, a system of such cells in the form of a panel or panels mounted on a rack or racks, where the rotation of the panels at an optimum angle in relation to the direction of the incident solar rays is simultaneously solved.

BACKGROUND OF THE INVENTION

Currently, both photovoltaic cells and their assemblies in the form of panels are known. It is also known to rotate such panels so that the sun's rays fall as perpendicular to the panel surface as possible. Considering the relatively larger weight of the panels, when constructing a system of a type not only an auxiliary source for low power or low power electronic devices. for recharging relatively small sources, but of the type that supplies power consumers or even has to supply power to the grid, in such cases, in the latter situation, the supporting structure must be designed so that on the one hand such a structure is relatively light, The rotation did not require strong and energy-intensive and demanding propulsion, but at the same time such a construction could not only safely bear the relatively high weight of each such photovoltaic cell panel, but also to withstand static and dynamic forces from wind. Current conventional structures are formed as frames mounted rotatably on a stable wide pedestal, where a drive is also attached to each such structure, usually regulated by a plurality of directed photocells. Such constructions, in order to meet the above-mentioned strength requirements, are relatively complicated and demanding in terms of material, and the individual pivoting drives are also relatively expensive. Particularly challenging are the structures to be solved, both in terms of panel and pedestal construction, as well as in terms of angle adjustment, rotation in the direction of both the daily and annual relative movement of the sun relative to the earth. In this case, the price of equipment is usually already so high that the energy from the photovoltaic source thus created is well above the highly subsidized feed-in tariffs for electricity from renewable sources.

The essence of the technical solution

Said disadvantages are solved to a large extent by a set of photovoltaic cells on the pivot panels according to the present invention, wherein the assembly comprises at least one movable support structure with fixed photovoltaic cell panels, a base for supporting such a movable support structure with photovoltaic panels and a pivot device. and wherein the base is formed as a pair of racks of different heights, each rack having at its apex a storage location adapted to rotatably support the movable support structure, the movable support structure being formed in the form of a longitudinally directed support beam, to which they are fixed at intervals corresponding to the width of the photovoltaic cell panels, support beams adapted to receive photovoltaic cell panels, and wherein the ends of the base beam are adapted to be rotatably mounted to storage locations on racks base while simultaneously pivoting device is designed as a linear electric or hydraulic motor, mechanical drive link connected to a movable supporting structure and connected to the actuating linkage with the control device. Preferably, in a pair of stands of different heights, the higher stand is formed as a planar triangular structure with two peaks at the ground and a third peak at a height, while the lower stand is formed as a pyramid with a triangular base. In particular, it is advantageous if the triangular structure of the higher rack is formed as two longer hollow profiles, at the bottom with a spacing embedded in the ground and connected at the top by a crossbar, to which the upper yoke is fixed. Similarly, it is advantageous if the lower stand is formed as a welded tripod, embedded in the ground, from the shorter hollow sections, at the top with an interconnection of the shorter hollow sections with a sloping platform to which the lower yoke is attached. Solid support structures. It is furthermore advantageous if, in the movable support structure, the base beam is formed as a hollow profile, each end axially extending by a shaft of smaller diameter on which the bearing is always mounted, and at the same time crossbars are attached to the base beam, fastened in its center by means of a clamping bracket, always tightened around the base beam. A connection other than a yoke can be used at these locations, but using an yoke connection is the optimal solution for preparing parts in production for on-site assembly quickly and easily. Still further, it is advantageous if the linear electric drive or the hydraulic motor is mounted with one end on the lower part of the lower stand or on the grip concreted into a common base with the lower stand and the other end on the drive arm connected to the base beam of the movable support structure. It is particularly advantageous if the control device of the linear electric drive or the hydraulic motor is designed as a timer with an interval switch. It is particularly advantageous if the timer has set steps of 10 to 60 minutes and the switching intervals are set to a duration of 1 to 60 seconds. Finally, it is an essential advantage if the assembly comprises at least two movable load-bearing structures, stacked side-by-side and stacked on a pair of stands of different heights, where each base beam is provided with a two-arm connecting crossbeam. interconnected at the ends of two-arm or two-arm connecting crossbars of adjacent or adjacent movable load-bearing structures. In such a case, prevention of possible oscillation of the system can be achieved such that from the scope of support crossbeams, support panels, support of linear electric drive or hydromotor drive crossbeam and support of two-arm connecting crossbeam on the base beam, wherein such a cushioning resilient bearing is preferably designed, for example, to clamp the base beam with a yoke over the elastomer insert. With respect to a particularly advantageous shape combination of hollow profiles over the entire structure, it is advantageous if the hollow profiles on the stands are tubes and the hollow profiles of the base beam and the cross beams are square hollow profiles.

In this way, a photovoltaic array system is achieved in which the structure is very strong and stable, both against stresses in adjusting the angle of the panels and against the effects of wind, rain or snow, and at the same time the structure itself is light, simple and relatively inexpensive. its transport and assembly will also be very simple, and even with a larger number of constructions, the whole system can be positioned either by several separate drives, or only a single, and therefore relatively inexpensive, drive can be used to position the entire system.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is further described and explained in more detail with reference to the accompanying drawings, in which: FIG. 1 shows one movable structure on a stand in a side view; Fig. 3 shows the same structure as Fig. 1, but this time in front view, and Fig. 4 shows schematically, in front view, the whole assembly of two movable structures interconnected and stored on their stands.

Examples of technical solution

The structure of the exemplary embodiment, in accordance with the present invention, is formed such that the array of photovoltaic cells on the pivotable panels comprises two movable support structures 2 with fixed photovoltaic cell panels 22, bases for supporting both such movable support structures 2 s. photovoltaic panels 22 and pivot mechanism. The base 1 is each formed as a pair of stands 11, 12 of different heights, each stand 11, 12 having at its apex a receptacle 111, 121 adapted to rotatably support the movable support structure 21, the movable support structure 21 being each formed in the form of The longitudinally directed base beam 21, to which the support beams 23 adapted to receive the photovoltaic panels 22 are fixed at regular intervals. The ends of the base beam 21 are then each adapted to be rotatably mounted in the receiving positions 111, 121 on the stands 11, 12 of each base L The pivoting device is here formed as a linear electric drive 3, connected by a drive mechanical coupling 31 with a movable supporting structure 2 and connected by a control coupling 41 to a control device 4. In each pair of stands 11, 12 of different heights triangular construction with two peaks near the ground and the third peak at a height, while the lower stand is formed as a pyramid with a triangular base. The planar triangular structure of the upper rack 12 is formed here in particular with longer hollow profiles 1201 formed as two tubes, spaced at the bottom with concrete embedded in the ground and connected at the top by a crossbar 1202 to which an upper bracket 1203 is mounted adapted to receive the upper end of the base beam 21. of the movable supporting structure 2. The lower stand 11 is here always made of shorter hollow sections 1101, here in particular of tubes, a welded tripod embedded in the ground, at the top with an interconnection of these tubes by an inclined platform 1102 to which the lower yoke 1103 In the movable support structure 2, the base beam 21 is formed here as a tube, axially extending at each end by a shaft of smaller diameter, on which the bearing is always mounted, and at the same time are fixed to the base beam 21. nosné příčn 23 in the form of flat rectangular hollow profiles. The fastening of the crossbeams 23 to the base beam 21 is here carried out in such a way that each crossbeam 23 is fixed in its center by means of a clamping bracket 231, always clamped around the base beam 21. The linear electric actuator 3 is supported by one end on the bracket welded to the lower. and the other end is mounted on a drive arm connected to the base beam 21 of the movable support structure 2. As a drive arm there is used a part of the support crossbar 23 of the movable support structure 2. The control device 4 of the linear electric drive 3 is then designed as a timer with an interval switch, so that the timer is set to increments of 30 minutes and the intervals of 25 tensions are set to 20 seconds. The photovoltaic system comprises two movable support structures 2, stacked side by side and stacked on a pair of stands 11, 12 of different heights, where each base beam 21 is at its upper end provided with a two-arm connecting crossbeam 211 at the ends of which ropes 212 connected to the ends of the two-arm connecting crossbeam 211 of the adjacent movable support structure 2 are further provided. the mounting of the drive cross member of the linear electric drive 3 as well as the mounting of the double-arm connecting cross member 211 on the base beam 21 is realized as a resilient bearing with damping, where such a resilient bearing with damping is here a clamping yoke 231 over an elastomer insert.

The function of the device is as follows. On the assembled and electrically connected equipment, electric current is generated under sunlight. The movable support structure 2 is adequately directed to the sun, with the angle between the base beam 21 and the ground surface being 30 degrees here, which for optimal alternatives with a constant base inclination appears optimal at latitudes of about 50 degrees latitude. Laterally, the movable support structure 2, pivoted on the stands 11, 12, is rotated behind the sun throughout the day, with a rotation of 20 seconds, in total of 16 steps, in half an hour, each time. After the last forward step, a reverse step is engaged in the overall cycle by which the movable structure is rotated backward to the initial position for the morning direction of exposure.

Economic usability

The device according to the present invention is usable as a system carrying primarily individual photovoltaic cell panels commercially supplied by themselves, and the use of a structure of the same type would also be relevant for supporting solar panels for heating water or air.

-3EN 16891 Ul

PROTECTION REQUIREMENTS

Claims (12)

PROTECTION REQUIREMENTS A system of photovoltaic cells on pivot panels comprising at least one movable support structure with fixed photovoltaic cell panels, a base for supporting a movable support structure with panels and a pivot device, characterized in that the base (1) 5 is formed as a pair of stands (11, 12) of different heights, each stand (11, 12) having at its apex a storage location (111, 121) adapted to rotatably support the movable support structure (11). 2), wherein the movable support structure (2) is formed in the form of a longitudinally directed base beam (21), to which they are fixed at intervals arranged equal to the width of the supported photovoltaic panels (22), support beams (23) adapted to receive photovoltaic and wherein the ends of the base beam (21) are adapted to be rotatably mounted to receiving locations (111, 121) on the stands (11, 12) of the base (1), wherein the pivoting device is configured as a linear electric drive (3). ) or a hydraulic motor, which is connected by a mechanical drive coupling (31) to a movable supporting structure (2) and at the same time connected by a control coupling (41) to a control device (4). A set of photovoltaic cells on a rotatable panel according to claim 1, characterized in that in a pair of stands (11, 12) of different heights, the higher stand (12) is formed as a planar triangular structure with two vertices near the ground and a third apex at while the lower stand (11) is formed as a pyramid with a triangular base. A set of photovoltaic cells on a rotatable panel according to claims 1 and 2, characterized in that the flat triangular structure of the higher stand (12) is formed as two longer hollow profiles (1201), at the bottom with a spacing embedded in the ground. and top joined by a partition (1202) to which is attached an upper yoke (1203) adapted to receive the upper end of the base beam (21) of the movable support structure (2). A set of photovoltaic cells on pivot panels according to claims 1 to 3, characterized in that the lower stand (11) is formed as a welded tripod, embedded in the ground, from the shorter hollow sections (1101), at the top with a connection of the shorter hollow sections a bottom bracket (1103) adapted to receive the lower end of the base beam (21) of the movable support structure (2). A set of photovoltaic cells on rotatable panels according to claims 1 to 4, characterized in that in the movable support structure (2), the base beam (21) is formed as a hollow profile, each axially extending by a shaft of smaller diameter, on which the bearing crossbars (23) are fastened to the base beam (21) in such a way that each cross beam (23) is fixed in its center by means of a clamping bracket (231), which is always tightened around the base beam (21) . 35 A set of photovoltaic cells on a rotatable panel according to claims 1 to 5, characterized in that the linear electric drive (3) or the hydraulic motor is mounted at one end on the lower part of the lower stand (11) or on a bracket concreted into a common base with the lower stand (11), and the other end is mounted on a drive arm connected to the base beam (21) of the movable support structure (2). 40 A set of photovoltaic cells on a rotatable panel according to claims 1 to 6, characterized in that the control device (4) of the linear electric drive (3) or of the hydraulic motor is designed as a timer with an interval switch. -4EN 16891 Ul The photovoltaic cell array on a rotatable panel according to claims 1 to 7, characterized in that the timer has been set in steps of 10 to 60 minutes and the interval switch has switching intervals of 1 to 60 seconds. A system of photovoltaic cells on a rotatable panel according to claims 1 to 8, characterized in that the system comprises at least two movable supporting structures (21), stacked side by side and stacked on a pair of stands (11, 12). of different heights, wherein at the same time each base beam (21) is provided with a double-arm connecting beam (211), at the ends of which the tie rods or ropes (212) are attached, connected to the ends of the two-arm or two-arm connecting beams (211) structures (21). A set of photovoltaic cells on a rotatable panel according to claims 1 to 9, characterized in that from the range of support beams (23) supporting the photovoltaic panels (22), the support beam of the linear electric drive (3) and the two-arm connecting beam ( 211) on the base beam (21), the at least one bearing is designed as 15 flexible mounting with damping. A system of photovoltaic cells on a rotatable panel according to claim 10, characterized in that the resilient mounting with damping is formed as a clamping of the base beam (21) by the respective clamping yoke over the elastomer insert. A system of photovoltaic cells on a rotatable panel according to claims 1 to 11, characterized in that the hollow sections (1101, 1201) on the stands (11, 12) are tubes and hollow sections of the base beam (21) and the support cross members (23). ) are square hollow profiles.