DE202008013209U1 - Modular system of a frame for solar systems - Google Patents

Abstract

Frame for solar systems (01) consisting of an upper part (02), a central part (03) and a lower part (04), characterized in that the said parts result in different, but compatible variants a modular system.

Description

The The invention relates to a modular system of a frame for solar systems and its coordinated components according to the preamble of Claim 1

State of the art

tracking devices for solar collectors or Solar modules are used to maximize the energy yield of solar systems in that the solar radiation in the most favorable angle - usually vertical - up the solar collector, the solar module, the reflector means or the on the solar collector or the solar cell focusing radiation concentrator meets. For this it is necessary to determine the position of the solar collectors, the solar modules, the reflector means or the solar collectors or solar cells focusing radiation concentrators the changing Track the sun. Such tracking devices are known.

Known Racks for Solar systems are designed to be the same as the sun illuminated areas for energy either not at all, only uniaxial or only tracking biaxially. Because it depends from the respective location of a solar system, depending on terrain and Shadows or the specific solar radiation angle One of the possible variants is used during the course of the day. The individual models of known frames are usually not optimized for, to put a variant of the situation to the election.

When Disadvantage of known solar systems with tracked energy production areas are the comparatively higher Operating costs are known due to the wear of Drive components through maintenance and repair work and by the Spare parts procurement arise.

Known drive solutions for driving both the azimuth and the elevation axis of tracking devices are linear drives with trapezoidal thread spindles as well as belt, cable or chain drives in combination with electric worm geared motors. Occasionally, the use of helical geared motors can be observed.

With increasing size of the area of tracked carrying equipment the demands on the load capacity and the precision of the Drive. With increasing size of the nachzuführenden area For example, the weight of the carrying device and its corresponding increases Moment of inertia and for example, the wind load potentially acting on them. Since turning and swiveling radii are proportional to the size of the nachzuführenden area increase, lead Wind-induced movements - such as vibrations - increasingly bigger moments back to the drive, the conventional wear Increase drives and parts of the construction tire. The occurrence of such moments is made possible by the play of conventional drive solutions, in which linear drives with trapezoidal thread spindles or worm geared motors used, favored.

The long service life required by the frames of solar systems places high demands on details of the drive. The use of linear drives with trapezoidal thread spindles or worm geared motors is in the application in the field of Nachführeinrchtungen due to the friction and sliding wear and the flank wear of the usually made of copper alloys (bronze, brass, gunmetal) made nuts (for linear drives with trapezoidal screws) and worm wheels (worm gears) in several ways disadvantageous. Although allow linear drives with trapezoidal screws and worm gear motors coping with the demanded by the tracking capacity, translation performance (for example in the form of multi-stage worm gear) and braking effect (the latter by the self-locking of the worm gear). However, the design-related backlash of the nuts in linear drives with trapezoidal threaded spindles and the worms in worm gear contradicts generally the need for backlash of Nachführeinrichtungen. Auxiliary designs to optimize the pressure of nuts or screws to reduce the backlash are just as the alternative use of ball screws instead of trapezoidal threaded spindles for cost reasons unattractive. The use of linear drives with trapezoidal screws and worm gears but also beyond disadvantage, since the already constructively provided backlash further increases with increasing wear, making these designs the requirement for backlash with increasing hours of operation know less and less fair. Ultimately, the life of linear drives with trapezoidal screws or worm gears by the wear of the nuts (in linear drives with trapezoidal screws) and worm wheels (worm gears) is significantly lower than the usually for more than 20 years life designed total tracking device. As a result, these transmission types of business management requirement for minimal effort for maintenance, repair and replacement parts of tracking devices can not do justice because their installation leads to significant expenses for necessary maintenance, repair and replacement parts. The installation of linear drives with trapezoidal screws and von Schne ckengetriebemotoren is also due to their comparatively low efficiency of disadvantage, they are compared with the efficiency of the proposed solution within the scope of the invention.

to Realization of a low-wear and maintenance-friendly drive of trackers is the belt, Rope or chain drive particularly suitable, wherein the traction means (belt, Rope or chain) placed around a circular arc or full circle and with this for power transmission connected is. The traction means is the driving wheel over two Supplied pulleys, which are upstream of the driving wheel so that the traction means sufficient tight wrap around the driving wheel reaches, the one Slippage of the traction device during power transmission or by forces that For example, act by wind on the tracking device prevents. Such a construction is state of the art.

disadvantage arise in such a belt, rope or chain drive through the insufficient storage of the driving wheel, due to it to fatigue breaks the transmission output shafts can come on which the driving Wheel is sitting. Another disadvantage of the mounting of the driving wheel the transmission output shaft of the geared motor is the associated Installation effort in case of repairs or becoming necessary Installation of a replacement gearmotor, since in this case the entire Chain drive must be disassembled.

The Designs of the drives known tracking devices are for a discontinuous tracking optimized. This means, the adjustment is made by short switch-on intervals of Drives. In the case of the use of concentrator cells, d. H. from Solar cells on which concentrated by a concentrator Light falls, can be a continuous tracking become necessary because even small angular deviations from the state to the sun to losses in energy production can, as soon as the bundled Light beam no longer hits the solar cell exactly. An appropriate one continuous drive increased but the requirements for its wear resistance, its life and its ease of maintenance. Conventional drive solutions, in which linear drives with trapezoidal thread spindles or worm geared motors can be used neither the here demanded low wear, nor the required here Freedom from play.

Known Racks for Solar systems, the need be able to cope with the wind load acting on the system. conventional Systems try to get around this problem by taking the wind-loaded ones surfaces the support device already at low wind speeds turn the wind, so the carrying devices as well as the suspension of the Relieve the carrying device and its components. The bases be known tracking devices either as extraordinary massively constructed and founded in heavy foundations columns or but executed as wide on the ground upstanding platforms, on where the racks rotate on bogies or slideways can be. As a result, a profitable use of tracked systems designed difficult in windy regions. Because subframes as columns accomplished are, these are pillars auszusteifen by considerable and expensive material costs, while the over a Pillar as Levers have been in the foundations introduced moments just to have by producing sufficiently sized and therefore expensive foundations become. If the rack is standing upright on a platform requires this the correspondingly expensive Construction of this platform and a no less complex substructure for receiving solar collectors, solar modules, reflector means or radiation concentrators.

Known Racks are common designed for use on level terrain to be set up. This is especially true for those racks that are wide on rigidly installed on a platform standing on the ground are or be moved on this rotating. If frames also only low heights have as much as possible They can provide low wind resistance and / or save material not easily on slopes or on hilly terrain be used.

to Control of known tracking devices are mostly fault-prone electronic controls used.

task

outgoing From this prior art, the invention is based on the object a rack for To propose solar systems, depending on the requirements of his Use can be interpreted differently.

This includes the task, the variants of a possible tracking with Drive design variants to equip, which is characterized by high Load capacity, zero backlash, wear resistance, high reliability and long life and low power consumption and their maintenance and other maintenance costs including necessary Spare parts cost-effective and if necessary, continuous tracking is permitted.

It also includes the task of carrying device for receiving the solar panels, solar modules, reflector means or concentrators based on the desired area size and the energy harvesting units to be mounted as wind load stable, variable and cost-effective.

Furthermore It includes the task of a lightweight and inexpensive substructure to suggest, according to the size and the Weight of the carrying device for receiving the solar collectors, solar modules, Reflector means or concentrators, depending on the location-specific wind load and depending on the site-specific terrain produced and / or adapted locally can and depending on the nature of the ground on different ups can be mounted.

Further it includes the task to propose a reliable control of tracking.

invention exposition

These The task is solved by a modular system of a frame for solar plants solved according to the teaching of claim 1.

The modular system according to the invention Frames for Solar systems and its coordinated components are based on the idea, the assemblies of a rack in different, but to design compatible variants, so that one the terrain situation, the terrain-specific Shading, the wind, the solar radiation angle, the claims the module, collector, reflector or concentrator technology used as well as the business premises of the respective project a combination of different variants of each Assemblies and their specific design can meet.

According to the invention the modular system consisting of an independent support device for solar collectors, Solar modules, reflector means or on solar collectors or solar cells Focusing radiation concentrators - hereinafter referred to as solar sails - with product-internal standardized Breakpoints as a first assembly. This becomes torsionally stiff Truss structure made of suitable materials, where the truss structure based on the breakpoints standardized within the product is designed. The standardized inside breakpoints allow the use of the solar sail on different substructures, without having to change the attachment points constructively.

By design is a suspension of the Solar sails in the center of gravity usually not possible. The solar sail has therefore at its underside attachment points to a mass balance weight to be able to attach. In case of a trackable Variant of the frame is mounted there a balance weight, so that the system is in equilibrium about the azimuth axis, whereby the energy expenditure for the electromotive flaps reduced by the azimuth axis.

The Assembly of solar collectors, solar modules, reflector means or Radiation concentrators of different dimensions is by a these elements carrying battens allows that on the truss structure is clamped.

According to the invention the modular system consists of a central part, which is a second assembly represents and to connect to the solar sail over the in-house standardized breakpoints. The solar sail is through this central part is connected to the lower part as the third module, the solar sail depending on the design of the middle part either is fixed or tracked uniaxial or biaxial can.

houses the middle part provide a mechanism for tracking the solar sail three embodiments at. In the first embodiment the tracking happens by folding the solar sail around the azimuth axis lying obliquely in space and the folding of the solar sail around the horizontally lying in space Elevation axis. This variant is a gimbal Storage of the solar sail. In the second embodiment, the solar sail becomes rotated around the azimuth axis lying vertically in space and around the aslant in the room lying elevation axis folded. Optionally, individual can Axles - preferred the elevation axis - fixed be so that either a one- or two-axis tracking is possible. In the third embodiment the elevation is over realized a lever mechanism, with the rotating mechanism of the azimuth axis connected vertically in the room. The peculiarity of this third embodiment is that the lever mechanism necessarily runs a curved path, the rigid is attached to the middle part, wherein the lever mechanism at the place of Set up to an angle of incidence of the sun becomes. Depending on the design of the tracking drive and the lower part s is an elevation of about 25 ° about 90 ° or about 45 ° to about 110 ° possible. in the Fall of a flap around the azimuth axis or a pivoting means the cam mechanism leaves depending on the design of Nachführantriebs and the lower part of the solar sail East and west to an angle from the horizon of approx. To fold 25 °, resulting in a total swivel angle of the azimuth axis of about 130 °. In the case of a rotary movement of a vertically in-space azimuth axis 360 ° rotation is possible.

in the Case of the first embodiment - a gimbal Storage - is the suspension of the solar sail connected to the azimuth axis, while the elevation axis with the part is connected, which is attached to the lower part. In the event of the second and third embodiments is the suspension of the solar sail connected to the elevation axis. This is then mounted on the pivoting about the azimuth axis joint, which on the Lower part is attached.

The Flaps around the elevation axis as well as the flaps or optionally the rotation about the azimuth axis takes place by means of a roller chain drive, consisting of the driven wheel, that with the axis to be moved connected, depending on the embodiment finite or infinite Roller chain, at least two pulleys and a self-supporting driving pinion and a clamping coupling with which the Output shaft of the geared motor on the stub shaft of the shaft of the self-employed two-sided stored drive pinion is plugged. The counter torque of the Aufsteckmotors is by means of a Zugdruckstange from the middle part added. This has the advantage of flanging the geared motor is not necessary.

Of the Roller chain drive has the advantage that it has a high, low-wear and backlash-free power transmission allows. Backlash is provided by the pulleys that make up the chain to the drive pinion, by wrapping the roller chain around the drive pinion allow more than 180 °, so that no slippage of the chain is possible even at high moments. in the case of pan or rotation angles of less than 360 °, the Roller chain on a circular arc segment attached to the axle to be moved guided and there fixing in at least one place and at least attached to a point with a spring-loaded clamping device. in the Trap of a non-returning tracking a rotating azimuth axis about 360 °, as they near the polar circle could be interesting the chain is non-positive connected to the driven wheel, wherein at least one of the pulleys is designed as a tension roller or another device for tension the chain is present.

Of the Advantage of a spring-loaded clamping device is the due to temperature fluctuations or age-related changes in length continuously balance the chain. By the same high chain tension will increase the backlash and precision of the Drive further increased. At the same time guaranteed a consistent chain tension a longer life of the chain.

The independent two-sided mounting of the drive pinion has the advantage that the Radial forces that acting through the chain on the drive pinion, not for permanent breaking lead through the high bending moments, as they occur in a shaft supported only on one side.

Of the by the self-employed Storage of the drive pinion enabled Use of a clamping coupling with which the shaft on which the drive pinion of Chain drive sits, connected to the output shaft of the geared motor becomes, as well as this possible Expected renouncement of a gear motor flange has the advantage that the geared motor as plug-on motor is particularly easy to maintain is mounted. In this way it can be exchanged without that the rest of the drive system, especially the chain drive, must be disassembled. The separation The geared motors of the chain drive also has the advantage that Geared motors are readily used at the customer's option can.

at The selection of eligible geared motors is the spur gear motor to give preference to the spur gear made of hardened spur gears. Helical gear have a very low friction, since the mesh the toothing represents a rolling process. As a result of the low Friction have helical gears with hardened spur gears as well a very long service life with low wear, at the same time a very high accuracy over a big Period guaranteed. Therefore, the efficiency of a hardened gear pair is also a spur gear very high. It is around 0.98, while the Efficiency of a worm gear, for example, depending on the translation between 0.6 and 0.8.

Of the Use of helical geared motors has the advantage that spur gear Already by design extraordinarily have little play and this design-based game of spur gear also increases very slowly due to the low wear. In order to lets itself through the use of helical geared motors meet both the requirement, the for example, to reduce wind-induced movement of the solar sail, which favors by play in the drive is, as well as the demand for high life and the demand after a permanently precise tracking in the Case of continuous tracking.

Of the high efficiency of the helical geared motors has a clear Increasing efficiency of power consumption compared to the usual in tracked Solar systems are used for the use of worm geared motors Episode. This is especially an advantage when the solar sail continuously tracked shall be.

Spur gears leave a higher Speed variability too, as a worm gear. The installation of spur gears in Nachführeinrichtungen offers therefore the advantage of the tracking device Utilization of the upper speed range of the drive motor or by Coupling with other fast-running auxiliary engines faster in desired To be able to move positions as this is possible with worm geared motors.

to Application get synchronous or asynchronous motors, which by means of Frequency conversion can be driven variably in the speed. The use Of permanent magnetically excited synchronous motors is the preference admit it is a cost effective continuous tracking allow. Permanent magnetically excited synchronous motors also have the advantage of high speed variability, what the adjustment speed the solar sail in case of need to good comes.

There Spur gears are not self-locking, is the spur gear motor equipped with a spring-loaded holding brake. By the very high Reduction can this holding brake based on the from the tracking device returning Torques be very small.

The Use of standard parts in the drive sector, such as standardized roller chains, Standard motors or standardized clamping clutches, has advantages in the worldwide procurement of spare parts.

The high reduction ratio and the high efficiency of the spur gears allows the use of very small and inexpensive standard brake motors.

The Control of tracking takes place by means of an electronic or by means of an electrical Control. Preferably, an electrical control is used, whose reference point is the rest position of the solar sail at 12:00 o'clock Local time is. This rest position takes the solar sail, if it does not track it becomes. The resting position has the advantage of being a natural position of the solar sail means in the horizontal wind movements at least attack surface offers. A timer is given calendar-dependent start times. When the start time is reached, the solar sail swings into position a limit switch east. The solar sail will then fade during the day West moves until the position of a limit switch reaches west is. Here is between the discontinuous and the continuous tracking to distinguish. In the case of discontinuous tracking is the tracking at intervals for switched on for a short time. Then the solar sail rushes to the state of the Sun a little ahead and pauses until the sun's level Setting the solar sail ahead of a certain value. in the Case of continuous tracking pivots the solar sail at the same time and at the same speed the movement of the sun. After reaching the limit switch West this drives Solar sails back to the rest position and stays there until Reaching the start time. Unless continuous tracking of the Elevation axis needed is controlled as shown above, the elevation angle is set, by the elevation axis according to annual clock on the relevant Season associated limit switch is driven.

This is according to the invention Middle part mounted on a three-legged base, which is a third Represents assembly.

The Lower part consists of three support tubes of the same or different lengths with gusset plates mounted in several places, with holes for fasteners are provided. The support tubes are with wind associations stiffened each other. At the top end, the support tubes are above gusset plates attached directly to the middle section. In the upper third are the support tubes also with turnbuckles connected to the middle part. At the bottom are the support tubes on the attached gusset plates on displacer posts, bored piles or conventional Concrete foundations attached. The lower part can with different Spreading of the support tubes be set up, with a merger of the three Stützrohe the Training a pillar consisting of three adjacent support tubes corresponds.

The Tripod allows it, the middle part in its vertical position regardless of terrain to align exactly, which is an oblique position of the tripod in Relation to the desired vertical axis of the middle part by means of the lower end of the Center part attacking turnbuckles can be compensated.

The Advantages of the three-legged design of the lower part are created by the possibility of interpretation the spread and the height the support tubes and by the configuration of the windings connecting the support tubes with low adaptation services site-specific wind load and terrain situations be fair, where at the same time comparatively little material is used so that a lightweight and inexpensive construction becomes possible.

The Tripod needed also less expensive foundations, as the known bogies or columns, provided the spread of the tripod the abzutragende moment in a sufficiently large radius into the ground.

By the variation of the lengths the support tubes can the three-legged parts also installed in hilly terrain and on slopes which makes even difficult terrain for the production of solar energy can be opened. The adaptability the construction to the terrain will still be through the possibility increased for attachment to different foundations.

The embodiments The invention are shown schematically in the drawings and will be explained below by way of example.

It demonstrate:

1 A frame for solar systems in side view;

2 the frame according to 1 in view from behind;

3 the biaxial bearing of the upper part on the middle part with chain or belt drives in lateral view of the elevation axis;

4 the biaxial bearing of the upper part on the middle part with chain or belt drives in a lateral view of the azimuth axis;

5 the biaxial bearing with vertical, chain or belt-driven azimuth axis and guided by a cam lever mechanism for adjusting the elevation axis in side view;

6 the biaxial bearing with vertical, chain or belt-driven azimuth axis and a crank mechanism for adjusting the elevation axis in side view.

In 1 is a rack for solar systems 01 shown in a side view, consisting of a top 02 consisting of an independent carrying device 13 for solar collectors, solar modules, reflector means or radiation concentrators focusing on solar collectors or solar cells 05 , at which a mass balance weight 15 is mounted, from a central part 03 consisting of a top part 02 carrying fastening system 06 , a drive system 07 and a base attached to the base 08 and a lower part 04 consisting of the support tubes 09 , the attached gusset plates 10 , the tension locks acting on the middle part 11 and the wind federations 12 composed. The lower part is at the bottom of its gusset plates on foundations 14 connected.

In 2 is the frame for solar systems 01 according to 1 from behind, creating a point of attachment 16 at the top 02 for the mass balance weight 15 you can see. Also the middle part 03 with a drive system 07 and the pedestal mounted on the base 08 which rises above the lower part is better seen in this view.

In 3 is the mechanics for biaxial tracking of the upper part 02 in the middle part 03 to be seen as a biaxial bearing, this side view of the circular arc segment of the drive of the elevation axis 19 shows. Furthermore, the elevation axis lying horizontally in space 18 and the azimuth axis lying obliquely in space 17 to recognize, on which the standardized in the construction kit suspension 06 of the top 02 sitting. On the circular arc segment 19 a finite belt or a finite chain is guided, the or via pulleys 21 around the driving wheel 22 to be led. The geared motor driving the elevation axis is hidden in this view. However, the also seen to drive the azimuth axis in the profile shows the two-sided storage 28 self-supporting driving wheel of belt or chain drive 22 as well as the clamp coupling 23 , with which the output shaft of the spur gear 26 the geared motor 24 is stuck on the stub shaft of the shaft, which is connected to the driving wheel. In addition, the spring-loaded holding brake 25 to recognize.

In 4 is the mechanics for biaxial tracking of the upper part 02 in the middle part 03 to see, this side view shows the circular arc segment of the drive of the azimuth axis. Furthermore, the elevation axis lying horizontally in space 18 and the azimuth axis lying obliquely in space 17 to see. Here is the standardized in the kit suspension 06 of the top 02 , The illustration shows in particular the drive of the elevation axis, consisting of the spring-loaded holding brake 25 , the geared motor 24 and its spur gear 26 , the clamp coupling 23 , the two-sided storage 28 self-supporting driving wheel of belt or chain drive 22 , as well as the position of the pulleys in the belt or chain drive and lying on the arc segment of the elevation axis chain 20 as well as their attachment 38 ,

In 5 is the mechanism for tracking the upper part 02 in the middle part 03 see, where the azimuth axis 42 lying vertically in the room. The azimuth axis is fixed with a circular arc or arc segment 35 connected, on which a belt or chain drive is guided, a self-supporting driving wheel 22 is fed, which in turn via a clamp coupling 23 with a spur gear 26 the geared motor 24 and the spring-loaded holding brake 25 connected is. In 5 is the drive unit 22 . 23 . 26 . 24 . 25 the azimuth axis 18 stand firmly in the room with the vertical the azimuth axis 42 connected while the belt or chain drive 35 frictionally with the base of the middle part 08 connected is. As 6 shows, an execution in reverse order is possible, wherein the drive unit 36 firmly on the base of the middle section 08 is mounted while belt or chain drives 35 non-positively with vertical in-space azimuth axis 42 connected is.

In 5 the drive of the elevation axis takes place 17 by means of a lever mechanism, consisting of an angle lever 30 , a uniaxial joint 33 and an adjustable guide rod 31 that with a joint 34 to the standardized in the kit suspension 06 of the top 02 is attached. The angle lever 30 is with the vertical axis in the azimuth axis 42 firmly in a joint 40 connected and running with a leadership role 29 mandatory a cam 39 off, with the cam 39 firmly with the base of the middle section 08 connected is.

In 6 the drive of the elevation axis takes place 17 by means of a crank mechanism consisting of the crank 41 that with a uniaxial joint 33 with the adjustable guide rod 31 connected with a joint 34 to the standardized in the kit suspension 06 of the top 02 is attached and that of a geared motor 37 which is fixed to the vertically in-space azimuth axis 42 connected is.

Claims (28)

Frame for solar systems ( 01 ) consisting of an upper part ( 02 ), a middle part ( 03 ) and a lower part ( 04 ), Characterized in that said components provide a modular system in different but mutually compatible variants. Frame for solar systems ( 01 ) according to claim 1, characterized in that the upper part ( 02 ) as a truss structure made of suitable materials ( 13 ), wherein the construction is based on breakpoints ( 06 ), where the upper part ( 02 ) at the middle part ( 03 ) and which are standardized in the kit. Frame for solar systems ( 01 ) according to claim 1, characterized in that the upper part on its underside fixing points for mass balance weights ( 16 ), which are standardized in the kit and where mass balancing weights ( 15 ) can be attached. Frame for solar systems ( 01 ) according to claim 1, characterized in that the upper part ( 02 ) mounted lathing for attachment of solar energy recovery devices with clamps is attached. Frame for solar systems ( 01 ) according to claim 1, characterized in that the middle part ( 03 ) is optionally fixed or has a mechanism for uniaxial - or biaxial tracking of the upper part. Frame for solar systems ( 01 ) according to claim 1, characterized in that the middle part ( 03 ) for receiving the upper part with breakpoints ( 06 ), which are standardized in the kit and to which the upper part is attached. Frame for solar systems ( 01 ) according to claim 5, characterized in that the mechanism for tracking the upper part ( 02 ) in the middle part ( 03 ) is designed as a biaxial, wherein the tracking of the upper part by folding around the obliquely lying in space azimuth axis ( 17 ) and by folding around the horizontally located in the space elevation axis ( 18 ) happens. Frame for solar systems ( 01 ) according to claim 5, characterized in that the mechanism for tracking the upper part ( 02 ) in the middle part ( 03 ) a rotation about the vertical in-space azimuth axis ( 42 ) and folding the elevation around the horizontal elevation axis ( 17 ) happens. Frame for solar systems ( 01 ) according to one of claims 7 to 8, characterized in that one or two axes of the tracking mechanism of the middle part ( 03 ) with a chain or belt drive ( 19 . 20 . 21 . 22 ), wherein the chain or belt is the driving wheel ( 22 ) via two pulleys ( 21 ), so that the wrap angle of the chain or belt around the driving wheel is greater than or equal to 180 °. Frame for solar systems ( 01 ) according to claim 8, characterized in that the elevation axis ( 17 ) the Nachführmechanik the middle part with a crank mechanism ( 37 . 41 ) is driven, wherein the output shaft of the geared motor is placed on the stub shaft of the crank mechanism, wherein the counter-torque of the Aufsteckmotors is received by means of a Zugdruckstange from the central part. Frame for solar systems ( 01 ) according to claim 5, characterized in that the mechanism for tracking the upper part in the middle part ( 03 ) a rotation about the azimuth axis ( 42 ) and the elevation via a lever mechanism ( 30 . 33 . 31 ) realized with the rotating mechanism of the azimuth axis ( 42 ), the lever mechanism ( 30 ) necessarily a curved path ( 39 ), which rigidly to the base of the middle part ( 08 ) is attached. Frame for solar systems ( 01 ) according to claim 11, characterized in that the rotation about the azimuth axis of the tracking mechanism of the middle part with a chain or belt drive ( 19 . 20 . 21 . 22 ), whereby the chain or belt ( 20 ) the driving wheel ( 22 ) via two pulleys ( 21 ), so that the wrap angle of the chain or belt around the driving wheel is greater than or equal to 180 °. Frame for solar systems ( 01 ) according to one of claims 9 and 11, characterized in that the driving wheel ( 22 ) of the belt or chain drive acting on the respective axle ( 19 . 20 . 21 . 22 ) stored separately on two sides ( 28 ) and the output shaft of the geared motor on the stub shaft of the shaft of the self-bilaterally mounted drive pinion ( 22 ) by means of a clamping coupling ( 23 ) is plugged, wherein the counter torque of the Aufsteckmotors is received by means of a Zugdruckstange from the central part. Frame for solar systems ( 01 ) according to any one of claims 9 and 11, characterized in that in the case of rotation of the azimuth axis ( 42 ) of the tracking device in the middle part ( 03 ) of below 360 ° of the belt or chain drive on a circular arc segment attached to the axis to be moved ( 19 ) and there at least one Steep ( 38 ) is fixed and fixed at least one place with a spring-loaded clamping device. Frame for solar systems ( 01 ) according to any one of claims 9 and 11, characterized in that in the case of rotation of the azimuth axis ( 42 ) of the tracking device in the middle part ( 03 ) of 360 ° of the belt or the chain the axis to be moved on a circular path ( 35 ), wherein at least one of the deflection rollers ( 21 ) of the chain or belt drive is designed as a tensioning roller. Frame for solar systems ( 01 ) according to claim 13, characterized in that helical geared motors ( 26 . 24 ) with hardened spur gears are used. Frame for solar systems ( 01 ) according to claim 16, characterized in that the helical geared motors ( 26 . 24 ) with spring-loaded holding brakes ( 25 ) are equipped. Frame for solar systems ( 01 ) according to claim 13, characterized in that the spur gear motor ( 26 . 24 ) can be equipped with another fast-running auxiliary engine. Frame for solar systems ( 01 ) according to claim 16, characterized in that permanently excited synchronous motors are used. Frame for solar systems ( 01 ) according to one of claims 7 to 19, characterized in that an electrical control is used, the reference point is the rest position of the solar sail at 12:00 local time, in which the upper part is moved in phases of rest, and a timer calendar-dependent start times are given and the upper part is moved upon reaching the start time in the course of the day from the position of a limit switch East in the position of a limit switch West, with both a discontinuous and a continuous tracking is possible, wherein in the case of discontinuous tracking the upper part of the state of the sun a little bit leading and persisting until the sun's position precedes the setting of the solar sail by a certain value, while in the case of continuous tracking the top is moved at the same time and with the same speed as the movement of the sun. Frame for solar systems ( 01 ) according to claim 20, characterized in that the elevation axis is adjusted in the case of a discontinuous tracking by the elevation axis is driven by the annual clock on the associated season of the limit switch. Frame for solar systems ( 01 ) according to claim 1, characterized in that the lower part ( 04 ) of three support tubes ( 09 ) of equal or different length with gusset plates attached at several points ( 10 ), which are provided with holes for fasteners. Frame for solar systems ( 01 ) according to claim 22, characterized in that the support tubes ( 09 ) with wind associations ( 12 ) are mutually stiffened. Frame for solar systems ( 01 ) according to claim 22, characterized in that the support tubes at the upper end with gusset plates ( 10 ) directly at the base of the middle part ( 08 ) are attached. Frame for solar systems ( 01 ) according to claim 22, characterized in that the support tubes ( 09 ) in the upper third with turnbuckles ( 11 ) with the base of the middle part ( 08 ) are connected, by means of which the vertical axis of the middle part can be adjusted independently of the terrain and relative to a possible obliquity of the tripod. Frame for solar systems ( 01 ) according to claim 22, characterized in that the support tubes ( 09 ) at the lower end with the gusset plates ( 10 ) on displacement posts, bored piles or conventional concrete foundations ( 14 ) can be attached. Frame for solar systems ( 01 ) according to claim 22, characterized in that the lower part ( 04 ) can be set up with different spread of the support tubes. Frame for solar systems ( 01 ) according to claim 22, characterized in that a combination of the three support tubes ( 09 ) corresponds to the formation of a column consisting of three adjacent support tubes.