BE1022365B1 - CONFIRMATION FRAME, SOLAR PANEL CONFIRMATION SYSTEM. - Google Patents

Abstract

Mounting frame, mounting system for solar panels Mounting frame for mounting a row of solar panels on an underlying structure, comprising two mounting feet arranged on one bottom for mounting on the underlying structure, and provided at the top with an arm that can be pivotally mounted with the foot with a connecting rod between the two arms, wherein the solar panels are adjustably mountable in a row on the connecting rod, the arm being an L-shaped arm including an included angle between two legs of the L-shaped arm that is greater than 90 °.

Description

Mounting frame, mounting system for solar panels

The invention relates to a mounting device for mounting solar panels on an underlying structure.

Such fastening devices are known. Solar panels can be placed on flat or pitched roofs and / or can be placed on plots of land that are fallow or not, for example on a flat piece of land or on a sloping piece of land. There are many options for installing solar panels.

Solar panels that are placed on a flat underlying structure, such as for example a flat roof or a flat piece of land, can be placed at an angle at a fixed angle to slightly direct the solar panels towards a position of the sun. Alternatively, it is also possible to provide the solar panels with a tracking system whereby the angle of inclination of the solar panels can be variable, depending on the position of the sun. Such a tracking system, also called a "solar tracker", can include a complex mechanical structure. The known tracking systems are usually expensive, complex, difficult to install and can be relatively heavy. Many of the known tracking systems can also be so complex that with a large angle adjustment of the solar panels, for example, the mechanical structure will cast shadow on solar panels and / or that solar panels, for example, will cast shadow on neighboring solar panels. This can reduce the efficiency of such tracking systems. The known tracking systems are also usually only cost-effective if a large number of solar panels are provided, so that they remain out of reach of private individuals who wish to provide solar panels on, for example, a flat roof.

There is a need for a tracking system that can be cost-effective for a relatively small number of solar panels. In particular, there is a need for a tracking system that is relatively simple and / or user-friendly.

To this end, the invention provides a mounting frame according to claim 1.

By providing a mounting frame for a row of solar panels, it is possible to set up a tracking system for only a limited number of solar panels. There are usually three to six solar panels in a row, depending on the dimensions of an individual solar panel.

A mounting frame according to claim 1 has a relatively simple construction. Substantially at least two mounting feet, each foot being provided with a pivotable arm, a connecting rod and drive mechanisms, are sufficient for building up the mounting frame. Due to the relatively simple components and the relatively simple construction, the system can also become accessible and / or cost-effective for a private individual who wants to install only a small number of solar panels. Due to the relatively simple construction, the system can also be arranged by a do-it-yourselfer.

By providing an L-shaped arm with an enclosed angle between the two legs greater than 90 °, the connecting rod on which the solar panels are mounted being connected to the L-shaped arm, a relatively large angle adjustment in a direction of rotation can be achieved, without the mechanical structure of the mounting frame and / or the neighboring solar panels going to cast shadow on the solar panels. Hereby the profitability of a tracking system comprising a mounting frame according to the invention can be increased.

By providing a two-axis adjustability of the solar panels, in a first direction of rotation and in a second direction of rotation, the position of the sun can be monitored in an optimum manner.

The adjustability of the solar panels in a first direction of rotation can be achieved by pivoting the L-shaped arm, whereby the connecting rod is moved and therefore the solar panels mounted on the connecting rod change their angular position. The pivoting of the L-shaped arm can be achieved by a first drive mechanism, which can for instance be designed as a hydraulic cylinder and / or an electric motor and / or any other actuator. By swiveling the L-shaped arm, all the solar panels on the connecting rod are simultaneously changed in position.

The solar panels are advantageously suspended in such a way that they can rotate around their center of gravity. This is advantageous since the force that may then be required to adjust the panels can remain limited. Advantageously, the connecting rod on which the solar panels are mounted can thus also be suspended around its center of gravity, so that the force to adjust the connecting rod can also remain limited.

The adjustability of the solar panels in a second direction of rotation can be achieved by, for example, mutually coupling the solar panels in the second direction of rotation, by subsequently adjusting a solar panel in the second direction of rotation, the other solar panels coupled thereto are also adjusted. In such a simple manner, for example, the solar panels of the row of solar panels mounted on the connecting rod can be adjusted in the second direction of rotation by a single drive mechanism. Alternatively, a drive mechanism can be provided for each individual solar panel for adjusting the solar panels in the second direction of rotation. In order to prevent shadow ejection in that case, the individual drive mechanisms for the second direction of rotation are preferably synchronized.

The second drive mechanism can also be designed as a hydraulic cylinder and / or an electric motor and / or a random actuator. The first and / or the second drive mechanism are preferably designed such that a relatively small angle adjustment of the solar panels and / or a relatively slow angle adjustment is possible.

A first direction of rotation may, for example, be a direction of rotation around the connecting rod, or around an axis parallel thereto, a second direction of rotation may, for example, be a direction transverse to the connecting rod.

In a simple manner, several mounting frames can be connected to each other to form a mounting system whereby multiple rows of solar panels can be provided in order to provide a flat underlying structure with solar panels. By connecting different mounting frames to each other, actuators can perhaps be used more efficiently, because, for example, a single actuator can adjust several rows of solar panels.

Further advantageous embodiments are shown in the subclaims.

The invention will be further elucidated on the basis of an exemplary embodiment of an adjusting instrument for a right-hand mirror unit seen in the direction of travel shown in the drawing. In the drawing:

FIG. 1 is a schematic perspective view of a fastening system according to the invention;

FIG. la is a schematic perspective view of a mounting system comprising a plurality of coupled mounting frames in the longitudinal and in the width direction;

FIG. 2 is a schematic perspective view of the mounting system;

FIG. 3 is a schematic perspective view of a mounting frame according to the invention;

FIG. 4a is a schematic perspective view of the arm in a first position; and

FIG. 4b is a schematic perspective view of the arm in a second position;

FIG. 5 is a schematic perspective view of an underside of a solar panel with a mounting bracket of a mounting frame;

FIG. 5a is a schematic perspective view of a support 15 of FIG. 5;

FIG. 6 is a schematic perspective view of mutually coupled mounting brackets; and

FIG. 7 is a schematic perspective view of the first drive mechanism in an extreme position.

In the figures, identical or corresponding parts are designated with the same reference numerals. It is noted that the figures are only shown by way of exemplary embodiment and should in no way be regarded as limiting.

FIG. 1 shows a mounting system 1 comprising a mounting frame 2 for mounting solar panels 3 on an underlying structure 4. The underlying structure 4 is only shown diagrammatically, but can be a flat roof, or can be a piece of land. The underlying structure is usually a more or less flat structure, but the underlying structure could also be an inclined surface, such as a sloping roof, or a slope of, for example, a hill. Many variants of an underlying structure are possible. The underlying structure is preferably suitable for carrying and / or mounting the mounting frame and / or the mounting system.

The mounting frame 2 comprises at least two mounting feet 5. On a bottom side 5a the mounting foot 5 is oriented for mounting on the underlying structure 4. The bottom side 5a of the mounting foot 5 can for instance be provided with a transverse profile to provide sufficient support and stability. Additionally or alternatively, the underside 5a of the mounting foot 5 can be loosely placed on the underlying structure 4 and, for example, weighted with concrete plates, or other material, to achieve fixation of the mounting foot 5 on the underlying structure.

On a top side 5b, the mounting foot is provided with an arm 6. The arm 6 is pivotally attached to the mounting foot 5 around a pivot axis Z. In this exemplary embodiment, the mounting frame 2 is provided with two mounting feet 5. In this exemplary embodiment, the mounting foot 5 is U- shaped, but may also have other shapes, for example L-shaped or I-shaped or J-shaped, etc. In this exemplary embodiment, the underside 5a of the mounting foot 5 is designed as a first leg of the U and the upper side 5b is designed as a second leg of the U. Numerous forms are possible. For example, the underside 5a of the mounting foot can be designed in a cross shape, or the mounting foot can be provided with one or two oblique legs that bear on the underlying structure, or the mounting foot can be in the form of a block or as two parallel ribs, etc.

A mounting rod 7 is arranged between the arms 6. The mounting rod 7 is connected at one end to a first arm 6 and is connected at another end to a second arm 6. The connecting rod 6 may be a solid or a hollow rod which may be attached to the arms 6 in a known manner. For example by means of screws, pop rivets, welding, glues, bolt / nut connection, etc.

The solar panels 3 are attachable to the connecting rod 7 by means of a support 15. In this exemplary embodiment, the supports 15 comprise fixing brackets 8 and support structures 11. The fixing bracket 8 is adapted for fixing to the connecting rod 7, and the supporting structures 11 are adapted to be pivotably connectable with the mounting brackets 8 and for supporting the solar panels 3. In other exemplary embodiments, the support 15 can be manufactured in one piece. Many variants are possible.

In this exemplary embodiment, four solar panels 3 are mounted on the connecting rod 7 between the two arms 6. In other exemplary embodiments, different numbers of solar panels can be mounted on the connecting rod. For example, three or six solar panels can be mounted. In this way the mounting frame 2 can support a row of solar panels 3.

The arm 6 is pivotally connected to the upper side 5b of the mounting foot 5. The arm 6 can be mounted on an inner side of the foot 5, i.e. the arm 6 can be located on the side of the solar panels with respect to the foot 5. Alternatively, the arm 6 can be located on an outside of the base 5, i.e. on the side of the base 5 which points away from the solar panels 3. Depending on compactness, desired angle adjustment, etc., the configuration with the arm 6 on the inside or for the configuration with the arm 6 on the outside.

The arm 6 is L-shaped, comprising a first leg 6a and a second leg 6b. The enclosed angle α between the two legs is greater than 90 °, is preferably more than 100 ° and more preferably about 120 °. The enclosed angle α is determined as the enclosed angle between the longitudinal axis A of the first leg 6a and between the longitudinal axis B of the second leg 6b. The connecting rod 7 is advantageously attached to the first leg 6a and a first drive mechanism 9 is coupled to the second leg 6b. The first drive mechanism 9 can pivot the arm 6 around the pivot axis Z, as a result of which the connecting rod 7 is also adjusted around the pivot axis Z, whereby an adjustment angle of the solar panels 3 can be adjusted in a first direction of rotation R1 around the pivot axis Z.

In FIG. 4a and FIG. 4b, two positions of the arm 6 can be seen. In FIG. 4a, a first position can be seen, wherein the arm 6 is adjusted away from the foot 5. In FIG. 4b a second position can be seen, wherein the arm 6 is adjusted towards the foot 5. It is noted that the positions shown do not have to correspond to the extreme positions of the arm 6. By designing the arm 6 L-shaped and attaching the connecting rod 7 to the first leg 6a of the arm 6, a relatively large Angular adjustment of the solar panels around the pivot axis Z is achieved. For example, an angle adjustment from about -70 ° to about + 30 ° can be achieved. A relatively large angle adjustment can also be achieved, whereby shadow formation of the construction on the solar panels can be prevented. By providing an L-shaped pivotable arm, shadowing on the solar panels can also be prevented with large angle adjustments in the first direction of rotation R1.

The first drive mechanism 9 can for instance be a hydraulic cylinder or a pneumatic cylinder or an electric motor or a magnetic motor etc. Many variants of a drive mechanism 9 are possible. For example, it is quite possible to use a brushless electric motor that can adjust the arm 6 at a lower voltage, for example at 12V. This allows the service life of the motor to be extended, while the power consumption can also be reduced.

Optionally, both arms 6 can be driven by a first drive mechanism 9, which then preferably operate simultaneously and / or synchronously. Alternatively, it may be possible to drive an arm 6 at one end of the first end of the mounting rod 7, wherein the arm 6 at the other end of the mounting rod 7 is not driven and therefore follows the adjustment of the driven arm 6.

In FIG. 1 and FIG. 2, it can be seen that mounting frames 2 can be coupled together to form a mounting system 1. In the embodiments shown, mounting frames 2 are coupled behind each other so that two rows of solar panels 3 can be formed. Alternatively and / or additionally, it is possible to also connect various mounting frames to each other in the longitudinal direction so as to form, for example, a long row of solar panels and / or to form a plane of solar panels. This is shown, for example, in FIG. la. Many variants are possible. In the exemplary embodiments shown, the mounting frames 2 are coupled to each other by means of a coupling rod 10. The coupling rod 10 also ensures that the mounting feet 5 do not move relative to each other when the arm 6 is adjusted by the drive mechanism 9. However, also other coupling mechanisms are possible, for example, the undersides 5a of the feet 5 can be connected to each other.

When a fastening system 1 is provided, a plurality of arms 6 can be driven by a single first drive mechanism 9 so as to simultaneously adjust several rows of solar panels in the first direction of rotation. To this end, for example, a plurality of arms 6 can be coupled to each other by means of a longitudinal profile 14, as in FIG. 1. If the drive mechanism 9, for example an actuator, moves the arm 6, the other arms 6 adjust simultaneously because they are coupled to each other via the longitudinal profile 14.

In another embodiment, the plurality of arms 6 can each be driven by a first drive mechanism 9, the different first drive mechanisms 9 preferably operating simultaneously and / or synchronously. In an exemplary embodiment, the arms 6 of subsequent fastening frames 2 cannot be coupled to each other via the longitudinal profile 14, whereby the arms 6 can be adjusted independently of each other and / or the arms 6 each have an independent drive mechanism. This is shown, for example, in FIG. 2, which shows a position of about -70 degrees for a first row and a position of about +30 degrees for a second row. In practice, the arms 6 are usually coupled to each other by means of the longitudinal profiles 14, as seen in FIG. 1. The solar panels 3 therefore adjust simultaneously, so that the solar panels 3 have the same adjustment angle on different rows, at least in a direction R1.

In FIG. 3 and in FIG. 5 shows that the mounting brackets 8 are on the one hand connected to the connecting rod 7 and on the other hand are connected to a support structure 11 which can be attached to a rear side of a solar panel 3. The supporting structure 11 is pivotally mounted on the mounting bracket 8. The supporting structure 11 is here embodied as an I-shaped structure, but can also be another structure, for example a rectangular structure. The mounting bracket 8 can be designed in various ways, a plate-shaped bracket is shown here, but many variants are possible, for example a beam-shaped bracket or a profile-shaped bracket. In this exemplary embodiment, the plate-shaped bracket 8 is provided on both sides with arms 8a, 8b with which the fixing bracket 8 can be attached to the connecting rod 7. For example, a continuous bolt can be used to secure the arms 8a, 8b through the - usually hollow - connecting rod 7. Alternatively, the mounting bracket 8 can also be welded to a top side of the mounting rod 7 and / or screwed and / or bolted and / or otherwise secured. The mounting bracket 8 can be attached to the connecting rod 7 by, for example, a bolt connection or a welding connection or a screw connection or a pin / shaft connection or another connection.

Also in FIG. 3, as well as in FIG. 5, to see that support structures 11 of the solar panels 3 are mutually coupled via a coupling rod 12. One of the support structures 11, the extended support structure 11a, can be coupled to a second drive mechanism 13. The support structures 11 are pivotally connected to the mounting bracket 8 and thus with the connecting rod 7. By adjusting the elongated support structure 11a and because the support structures 11 are mutually coupled, noble support structures 11 are adjusted in a second direction of rotation R2, whereby an adjustment angle of the solar panels 3 in the second direction of rotation R2 can be adjusted . The second direction of rotation R2 is transverse to the first direction of rotation R1. Typically an angle adjustment of about -45 ° to about + 45 ° is achieved in the second direction of rotation R2.

In an exemplary embodiment, the support structure 11 can be provided with two arms 11e, 11f on either side of the mounting bracket 8, as well as on either side of the connecting rod 7. The arms 11f, 11e are then attachable to the connecting rod 12. The connecting rod 12 can be designed as two rods 12a, 12b approximately parallel running between which the drive mechanism 13 can be situated. This is shown, for example, in Fig. 5 or Figs. 6. In one embodiment, the support structure 11 is rotatably supported on the mounting bracket 8, as can be seen, for example, in FIG. 5, and in detail in FIG. 5a. In this exemplary embodiment, a tube 8c is attached to an upper side of the mounting bracket 8, for example by means of welding or bolts or screws or a pin / hole connection, etc. The arms 11e, 11f of the supporting structure 11 are pivotally arranged around the tube 8c . The support structure 11 furthermore comprises a box in which support arms 11h, 11l can be fixed on either side, which arms can then be attached to a bottom side of a solar panel 3. By adjusting the second driving mechanism 13, the arms 11e, 11f adjust, so that the box is pivoted around the tube 8c. As a result of the attachment of the carrying arms 11h, 11b to the box on the one hand and to a solar panel 3 on the other hand, the solar panel 3 also swings.

Of course, other embodiments are also possible for the supporting structure 11 and / or for the connecting rod 12. For example, the supporting structure 11 and / or the connecting rod 12 can comprise a single arm or connecting rod. For example, the support structure 11 may go along one side along the connecting rod 7 to be secured with the connecting rod 12. Many variants are possible. It will be clear to those skilled in the art that the scope of protection is not limited to the configuration shown.

In FIG. 7 is an extreme position for adjusting the arm 6 in a direction R1. In this extreme position of the drive mechanism 9, the panels 3 on the row of connecting rod 7 are pivoted about 30 degrees. The panels 3 are in an approximately zero degree position in the direction of rotation R2 when the coupling rod 12 is approximately in a lowest position. In the shown configuration of the drive mechanisms 9, 13, the various parts of the fastening system 1 do not touch each other, whereby a wide angle adjustment is possible both in direction R1 and in direction R2. The same applies to a different extreme position of the drive mechanism 9, in which the panels 3 are pivoted about 70 degrees the other way.

FIG. 6 shows that the extended support structure 11a is connected to the drive mechanism 13. It can also be seen that the support structures 11 are mutually connected to the coupling rod 12, so that an adjustment of the extended support structure 11a by means of the second drive mechanism 13 also leads to a simultaneous adjustment of the other solar panels 3.

The solar panels 3 are advantageously suspended in their center of gravity in each case, so that the solar panels 3 can rotate approximately around their center of gravity. As a result, only a small force is sufficient to adjust the solar panels, so that the drive mechanism, as well as the construction, can be made relatively light. The construction of the support structure 11 is preferably such that the mounting of the solar panel 3 on the support structure is unambiguous and that after mounting the solar panel 3 is more or less suspended in the center of gravity. For example, the support structure may comprise profiles whose length and / or width corresponds to the length and / or width of the solar panel so that mounting of the solar panel on the support structure leads to a suspension of the solar panel relative to the support structure approximately in the center of gravity of the solar panel. solar panel. Many variants are possible. Many solar panels are equipped with a mounting structure at the rear of the solar panel. By designing the support structure compatible with the fixing structure of the solar panel, a suspension can be achieved practically in the center of gravity of the solar panel.

Advantageously, the connecting rod 7, to which the fixing brackets 8 are attached with the solar panels 3, is suspended approximately in the center of gravity, so that only a small force is required for adjusting the connecting rod 7. When both the solar panels 3 themselves are suspended approximately in their center of gravity and the connecting rod 7 with the solar panels is also suspended approximately in the center of gravity, adjustment of the solar panels in direction R1 or in direction R2 can take place with a relatively small force. If the solar panels and / or the connecting rod were not suspended in the center of gravity, if the solar panels were adjusted, the center of gravity of the connecting rod with solar panels would change. This is disadvantageous, since the forces for adjusting can then become relatively large.

Because the solar panels 3 and / or the connecting rod 7 with solar panels 3 are suspended approximately in the center of gravity, the construction can be made relatively light. For example, it is possible to work with aluminum profiles and / or with hollow tubular profiles.

Due to the relatively low weight of the mounting system 1, in particular the mounting and installation thereof can be carried out advantageously.

In this exemplary embodiment, a single second drive mechanism 13 is provided per row of solar panels, since the solar panels are mutually coupled via the mounting bracket and are thus adjustable together in the second direction of rotation R2. Alternatively and / or additionally, a drive mechanism can be provided per solar panel that can individually adjust a solar panel in the first and / or the second direction of rotation. Alternatively and / or additionally, several rows of solar panels can be mutually coupled and driven by a single second drive mechanism. Many variants for this are possible.

Depending on the embodiment of the second drive mechanism, the supports 15 can be pivotably attachable to the connecting rod 7 and / or the supports 15 can be fixedly connected to the connecting rod 7. The supports 15 can for instance be fixedly attached to the connecting rod 7 by means of welding or shoot through nails, or through another connection method. For example, in an alternative embodiment, the support structure 11 may be pivotal with respect to the mounting bracket 8, wherein the second drive mechanism can then adjust the support structure 11 to adjust the solar panels in the second direction of rotation.

As with the first drive mechanism, many embodiments are possible for the second drive mechanism. For example a hydraulic cylinder, or a pneumatic cylinder, or an electric motor, or a magnetic motor or an induction motor, etc.

By providing two drive mechanisms that can be placed independently of each other, a simple fastening system can be achieved. The fixing system can thus be kept relatively inexpensive, so that it can also be interesting to install for small surfaces of solar panels. By providing a tracking system, the efficiency of the solar panels can be increased, for example the efficiency can increase by approximately 5% to approximately 40%. The improvement in efficiency, however, depends on the local situation.

The fastening system 1 according to the invention can be particularly advantageous when relatively many fastening frames 2 can be mutually coupled to each other, such as for instance for relatively large surfaces, for example an industrial roof or a large piece of supporting terrain. When a relatively large number of mounting frames 2 can be coupled to each other, a plurality of arms 6 or a plurality of connecting rods 7 can be coupled to a single first drive mechanism and / or to a single second drive mechanism. This is possible since the solar panels 3 and / or the connecting rods 7 are suspended approximately in the center of gravity, i.e. approximately in equilibrium. Such an increase in scale can therefore yield a relative cost saving.

In addition, instead of attaching a single solar panel 3 to the support structure 11, it may also be possible to attach a plurality of solar panels to the support structure 11, the plurality of solar panels also being substantially suspended in the center of gravity.

Advantageously, a control system can also be provided for controlling the first and / or the second drive mechanism. The operating system is not shown in the figures. The control system can be arranged to control the first drive mechanism or can be arranged to control the second drive mechanism or can be arranged to control the first and the second drive mechanism. The control system can be located at the fastening system, wherein it can for instance be accommodated in a closed cabinet. Alternatively and / or additionally, the control system may be remote from the mounting system, controlling the first and / or the second drive mechanism remotely. For example, the control system may be located in the building on which the mounting frame and / or the mounting system is installed.

The control system may be provided with information, for example in the form of tables, about the position of the sun during the day. This information depends on the location. A user can optionally set the location once, after which the operating system can select the corresponding sun position table. Alternatively and / or additionally, the mounting system may be provided with a GPS module with which the location can be determined, which can subsequently be supplied to the control system as an input signal to select the corresponding sun position table. Depending on the selected sun position table, the first and / or the second drive mechanism can be controlled to adjust the position of the solar panels in the first direction of rotation and / or the second direction of rotation.

In one embodiment, the mounting system can be provided with a lux sensor for measuring the amount of light on site. For example, the solar panels can be placed in a horizontal position, almost parallel to the underlying structure, when there is insufficient light. In such a horizontal position, the solar panels are less sensitive to weather influences from, for example, wind. Wind can then easily be passed under the solar panels.

The operating system core can be accessed remotely and / or can operate autonomously. For example, the control system can be arranged that on receiving an error signal from a first and / or a second drive mechanism, it only gives a message, but it can switch off the relevant first and / or second drive mechanism. Many variants are possible to set up the operating system.

For the sake of clarity and a compact description, measures are described herein as being part of the same or different embodiments. However, it will be clear that the shown and / or described measures can be combined with each other and that such combinations fall within the scope of the claims.

The invention is not limited to the exemplary embodiments shown here. Many variants are possible and will be apparent to those skilled in the art within the scope of the following claims.

Claims (14)

CONCLUSIONS A mounting frame for mounting a row of solar panels on an underlying structure comprising - at least two mounting feet on a bottom arranged for mounting on the underlying structure, and provided on the top with an arm pivotably attachable to the base; - a connecting rod arranged between the at least two arms, wherein the solar panels can be attached in a row to the connecting rod; - wherein the solar panels are adjustable in a first direction of rotation via a first drive mechanism and in a second direction of rotation via a second drive mechanism; - wherein the first drive mechanism engages an end of the arm for pivoting the arm to adjust the solar panels in the first direction of rotation; - wherein the arm is an L-shaped arm comprising an enclosed angle between two legs of the L-shaped arm that is greater than 90 °. A mounting frame according to claim 1, wherein the solar panels are adjustable substantially around their center of gravity. 3. Mounting frame according to claim 1 or 2, wherein the solar panels are mutually coupled so that the solar panels of the row of solar panels can be adjusted in the second direction of rotation by driving the second driving mechanism of a single solar panel. A mounting frame according to any one of the preceding claims, wherein the solar panels of a row of solar panels are mutually coupled via a coupling rod that extends substantially along the connecting rod. 5. Mounting frame according to one of the preceding claims, wherein the solar panels can be attached to the connecting rod via a support. The mounting frame according to claim 5, wherein the support is configured to suspend a solar panel substantially in its center of gravity. A mounting frame according to claim any one of the preceding claims, wherein the second drive mechanism is connectable with a support of a solar panel to adjust the solar panels of the row of solar panels via the connecting rod in the second direction of rotation. A mounting frame according to any one of the preceding claims, wherein the row of solar panels in the first direction of rotation is adjustable between a first angle of approximately -70 ° and a second angle of approximately + 30 °. A mounting frame according to any one of the preceding claims, wherein the solar panels are adjustable in a row in the second direction of rotation between a first angle of approximately -45 ° and a second angle of approximately + 45 °. 10. Mounting frame as claimed in any of the foregoing claims, further comprising a control system for controlling the first and the second drive mechanisms for adjusting the angle of the solar panels depending on the position of the sun. 11. Mounting system comprising at least two mounting frames according to one of the preceding claims, which can be mutually coupled. A mounting system according to claim 11, wherein the first drive mechanism is connectable to a plurality of arms for simultaneously adjusting a plurality of rows of solar panels in the first direction of rotation. A mounting system according to claim 11 or 12, wherein second driving mechanisms of a plurality of rows of solar panels can be driven simultaneously. A set of parts comprising at least mounting feet, arms and a mounting rod for assembling a mounting frame according to any of claims 1-10 and / or for assembling a mounting system according to one of claims 11-13.