DE102010015854A1 - solar tracking - Google Patents

Abstract

Device for tracking at least one solar surface, the device comprising a fastening device on which the solar surface is fixed and a drive that moves the fastening device in a direction of rotation about an axis of rotation, the invention provides that the fastening device in a pivoting direction about a pivot axis , is movable, and that the axis of rotation and the pivot axis are coupled to one another by a guide device. The coupling is designed in such a way that a rotation of the fastening device about the axis of rotation in the direction of rotation simultaneously causes the fastening device to pivot in the pivoting direction. Furthermore, the guide device has a rail.

Description

The invention relates to a device for tracking a solar surface according to claim 1.

The efficiency of a solar surface is higher, the more perpendicular the radiation impinges on the solar surface. For fixed solar panels, however, the angle of incidence of solar radiation is not constant but depends on the movement of the earth around the sun. The deviation from the optimal angle of incidence of the solar radiation on the solar surface is referred to as a false angle. In order to be able to ensure efficient use of photovoltaic systems and solar thermal systems, it is necessary to largely avoid these false angles. This can be achieved by tracking the solar surfaces to the sun's course. The additional power, which can be provided by tracked solar panels, depends on the location of the solar system and is in photovoltaic systems between 40% -60%. The highest yield is achieved near the equator. By tracking solar panels of solar thermal systems, an increase in efficiency of up to 40% can be achieved.

Tracking systems for solar systems are well known. In the prior art, there are both uniaxial systems that trace the daily course of the sun from east to west, as well as biaxial systems, which take into account the season-dependent elevation of the sun in addition to the east-west course. Single-axis systems are relatively inexpensive, but due to the relatively imprecise adaptation of the solar surface to the position of the sun, the systems can not achieve the optimum yield.

In the prior art, two-axis systems are described in addition to the uniaxial systems. The known biaxial systems often involve complicated electronic control based on GPS or sensor signals. Other known designs are based on a complex mechanism.

The mechanical systems are usually controlled by time controls. The tracking starts at sunrise and ends after sunset. Some tracking systems also have a feedback, which moves the solar surface back to its starting position at the end of the day.

DE 10 2005 042 478 A1 describes a biaxial tracking system for solar systems. This has a pivoting head which is rotatable about a vertical axis and thus makes the azimuth alignment of the solar surface. The swivel head is driven by a geared motor. The time-dependent change in the inclination of the solar surface is achieved by a vertically extendable plunger, the extension of the plunger is effected by a cam control. The inclination adjustment of the solar surface to the season-dependent position of the sun is caused by a superposition of the first curve control (daily curve) with a second curve control (annual curve). The drive of the tracking system is controlled by means of a timer. The annual curve is incremented daily, which can be linked to the daily feedback of the tracking system after sunset.

In this case, it is fundamentally disadvantageous that the described device with the curve controls provides two separate tracking elements in order to simultaneously effect a time-of-day and season-dependent tracking of the system. This increases the production and material costs and also makes the system more susceptible to failure.

In addition to the current day and season, the geographical location of a solar system also influences the angle of incidence of the solar radiation. To tune the tracking system to the respective installation site, are in the DE 10 2005 042 478 A1 specially adapted curve controls provided.

The tracking system has two cam controls, both of which may need to be replaced. This is associated with a relatively high cost and therefore extremely unfavorable.

Object of the present invention is therefore to overcome these and other disadvantages of the prior art and to develop a device for biaxial tracking of solar systems, which allows a simple, robust and cost-effective mechanics an efficient adaptation of the solar surface orientation to the Sun's course. The device should also be quick and easy to install and operate.

Main features of the invention are specified in the characterizing part of claim 1. Embodiments are the subject of claims 2 to 11.

In a device for tracking at least one solar surface, wherein the device comprises a fastening device on which the solar surface is fixed and a drive which moves the fastening device in a rotational direction about an axis of rotation, the invention provides in that the fastening device is movable in a pivoting direction about a pivot axis, and in that the rotation axis and the pivot axis are coupled to one another by a guide device, such that a rotation of the fastening device about the axis of rotation in the direction of rotation simultaneously causes pivoting of the fastening device in the pivot direction, and in that Guide means comprises a rail.

The common guide device ensures a simple and inexpensive device for tracing the course of the sun. Due to the special design of the guide device also weight can be saved. This is of great interest especially for solar surfaces which are applied to a carrier or structure.

The device can be used for tracking solar surfaces of solar systems of all kinds. These include photovoltaic systems, which are used to generate electricity, as well as solar thermal systems, which are used in heat generation.

In a preferred embodiment, the rail has a curvature about the axis of rotation and a curvature about the pivot axis. This embodiment enables a tracking of the solar surface while taking into account the east-west gradient and the elevation of the sun.

It is furthermore preferred that each rail is adapted in its shape and orientation to a latitude of latitude assigned to it on which the device is used. This is particularly advantageous for effective tracking, since the angle of incidence of the solar radiation on a solar surface in addition to the hour angle and the elevation of the sun is also dependent on the latitude of the geographical location, and thus by the additional consideration of the latitude, a higher performance can be provided ,

It is therefore useful to provide several different rails. When used in the European area, for example, various rail designs for Northern Europe, Central Europe and Southern Europe are conceivable.

In this context, a further embodiment provides that the rail is replaceable. Such a configuration allows easy adjustment of the tracking to the respective site. The device can thus be manufactured in the manufacturing process with a standard rail, which can then be replaced depending on the application of the device with simple means against a specially adapted rail. With this configuration, a reusable device can be provided by simple means.

In a particularly preferred embodiment, the rail is configured such that its shape and orientation within the guide device reflect the average solar ephemerides of the latitude latitude on which the device is used. Such an averaging is an optimization, with the help of a daily constant tracking process can be made. Such a configuration is characterized in particular by a simple and inexpensive construction.

Due to the interpolation, the angle of incidence of the solar radiation on the solar surface is caused to be off the optimal, perpendicular angle of incidence. In order to ensure a meaningful use on the basis of the optimization, these error angles should amount to a maximum of ± 15 °. Skew angles within this range result in a yield reduction of only 2% -5% in modern high power photovoltaic cells. However, taking into account the cost savings associated with the optimization by simplifying the design, it makes sense to neglect a reduction in yield to this small extent in favor of a simplified construction.

The rail, is preferably a slotted guide, a flat guide or a guide tube. This allows a simple and robust design can be achieved.

To stabilize the rail, stiffening elements such. B. braces are used.

In a further embodiment, a guide slot is formed in the rail. In this way a secure guidance in the rail is guaranteed. Furthermore, such a rail has a simple geometric shape, which is why the raw material can be obtained inexpensively from the standard range of goods.

At least one guide element, which engages in the rail, preferably in the guide slot of the rail, is fastened to the fastening device. This advantageously ensures a robust guidance in the rail.

Another important embodiment of the invention further provides that an additional adjusting element is provided for fine adjustment of the output swivel angle of the solar surface to the latitude of the geographical location of the plant. One such adjustment increases the effectiveness of tracking. A further advantage is that the different rails can be used by the additional adjustment in a wide range of applications.

To facilitate assembly of the device, a further embodiment provides that a mark is attached to the device indicating the preferred azimuth orientation of the device in the home position.

Furthermore, the fastening device is preferably connected to a support frame. This is particularly advantageous, since in this way a means for receiving one or more solar surfaces is provided.

A particularly advantageous development provides that the device contains a drive, a simple control unit, such as a timer, a transmission, a rotation device and a guide device. The drive may be connected to the transmission via a coupling unit. To a transfer of forces, as z. B. can occur due to wind on the solar surface to keep the drive as low as possible, it is expedient to select a transmission which has either a self-locking or a brake. In addition, the use of a transmission with a large gear ratio is advantageous.

To protect the device against external influences such. As weather influences or Wildverbiss, the device may be completely or partially enclosed in a housing.

For a use of the device in the context of a larger photovoltaic or solar thermal system, a particularly advantageous embodiment, to couple the device with other, decentralized tracking units. The decentralized tracking units preferably have neither their own drive nor their own control. In such a case, the device preferably serves as a central unit whose drive is used as a central drive and their control as a central control. However, with the exception of drive and control, the further construction of the decentralized tracking units preferably corresponds to that of the device according to the invention.

Most solar thermal systems are designed to generate heat during winter and during the transitional period. Especially in summer, with long-lasting summer periods, these plants tend to overheat. This fact causes problems especially in southern regions with especially long and hot sun periods.

A further embodiment of the invention therefore provides that the device according to the invention can be provided with an additional device, which effectively tracks the solar surfaces when heat is needed, and if necessary, turns them out of the sun in order to avoid overheating. Such an additional device can be regulated for example by measuring the amount of energy available in the memory.

Further features, details and advantages of the invention will become apparent from the wording of the claims and from the following descriptions of exemplary embodiments with reference to the drawings.

Show it:

1 to 3 various embodiments of the device according to the invention,

4 Inventive variants of the guide device and

5 a device according to the invention for tracking decentralized tracking units by means of a central control unit and a central drive unit,

6 a possible design of the connection between the fastening device and the rail.

1 shows a device 10 with a stand. The figure shows the device 10 in the starting position at the morning time when the solar area 20 has a vertical position.

On the stand is the drive 11 and a rotatable rotatable device connected thereto 19 in the form of a cylinder tube. The cylinder tube of the rotary device 19 lies on a rail 31 at. The rail 31 is with a fastening device 40 via a guide element (not shown in this illustration). The fastening device 40 is with a support frame 14 connected, the total of four solar panels 20 wearing. The device 10 has a leadership facility 30 , With the help of the drive 11 can the leadership device 30 a rotation of the fastening device 40 about a rotation axis A and at the same time pivoting of the fastening device 40 to cause a pivot axis B.

2 shows a further embodiment of the device 10 with a guide device 30 , The management device 30 has a rail 31 having chain elements. The device 10 has a total of two solar panels 20 . which on a support frame 14 are fixed. The supporting frame 14 is with the fastening device 40 connected. The device 10 owns a stand. The drive 11 is arranged on the stand. The figure shows the device 10 in a position in the solar area 20 is inclined relative to the starting position.

3 shows an embodiment of the device 10 , a gearbox 17 , a controller 18 as well as a backdrop tour 34 , The drive 10 is with the gearbox 17 via a coupling element 16 connected.

The components of the device 10 are in a compact housing 15 , Between the case 15 and the support frame 14 is a fine adjustment 12 appropriate. With the help of this fine adjustment 12 can the tilt angle of the solar surface 20 adjusted to the geographical latitude of the plant location. On the housing wall, an externally visible marking is preferably attached. This marks the preferred azimuth alignment of the system in the starting position and thus simplifies the assembly of the device 10 ,

The rotation device 19 runs along the axis A. It is with the gearbox 17 connected and transmits those through the drive 11 generated movement on the guide device 30 , which a track-curved gate guide 34 having. In the slide tour 34 engages a guided-guided guide element 32 one. In the illustrated embodiment, a role as a guide element 32 used.

With the help of the drive 11 can the leadership device 30 a rotation of the fastening device 40 about an axis of rotation A in a direction of rotation a or a 'and at the same time pivoting of the fastening device 40 to cause about a pivot axis B in the pivoting direction b or b '.

4 shows variants of the rail according to the invention 31 , This can, for. B. as a slotted guide 34 with one or more guiding elements 32 be educated. The guiding elements 32 grab into a guide slot 33 the slide tour 34 one.

Another variant includes a guide tube 34 with two guiding elements 32 ,

Furthermore, a flat guide 35 with suitable guiding elements 32 for appropriate embodiment of the guide device 30 be used. The illustrated embodiments exclusively show rollers as guide elements 32 However, this should not be construed as a limitation.

5 shows a device according to the invention 10 in a multi-station tracking system 50 ,

The device 10 serves as a central unit whose drive as a central drive 51 and their control as a central control 52 is used to all of the eleven other decentralized tracking units 55 the multi-station tracking system 50 to operate. The construction of decentralized tracking units 55 corresponds to that of the device with the exception of drive and control 10 ,

To stabilize the multi-station tracking system 50 are weights 53 intended.

6 shows a possible embodiment of the connection between the fastening device 40 and the rail 31 ,

On the fastening device 40 is a guiding element 32 attached, which is in the rail 31 intervenes. The fastening device 40 is also with the rotation device 19 and the support frame 14 the device 10 connected. The supporting frame 14 grasp the solar surface 20 , In order to increase the stability of the arrangement is between the fastening device 40 and the support frame 14 A carrier 41 intended. The rail 31 is by a bracing 13 strengthened.

The invention is not limited to any of the prescribed embodiments, but can be modified in many ways.

All of the claims, the description and the drawings resulting features and advantages, including design details, spatial arrangements and method steps may be essential to the invention both in itself and in a variety of combinations.

LIST OF REFERENCE NUMBERS

A

axis

B

axis

a

direction of rotation

a '

direction of rotation

b

pan direction

b '

pan direction

10

contraption

11

drive

12

fine adjustment

13

brace

14

supporting frame

15

casing

16

coupling element

17

transmission

18

control

19

rotation means

20

solar surface

30

guide means

31

rail

32

vane

33

guide slot

34

link guide

35

guide tube

36

flat guide

40

fastening device

41

carrier

50

Multi-tracker arrangement

51

central drive

52

central control unit

53

Weight

54

connection

55

decentralized tracking unit

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102005042478 A1 [0006, 0008]

Claims (11)

Contraption ( 10 ) for tracking at least one solar surface ( 20 ), the device ( 10 ) a fastening device ( 40 ), on which the solar surface ( 20 ) and a drive ( 11 ), the fastening device ( 40 ) in a direction of rotation (a, a ') about an axis of rotation (A) moves, characterized in that • the fastening device ( 40 ) in a pivoting direction (b, b ') about a pivot axis (B), is movable, • that the axis of rotation (A) and the pivot axis (B) by a guide device ( 30 ) are coupled together such that a rotation of the fastening device ( 40 ) about the axis of rotation (A) in the direction of rotation (a, a ') at the same time the pivoting of the fastening device ( 40 ) in the pivoting direction (b, b '), • that the guide device ( 30 ) a rail ( 31 ) having. Contraption ( 10 ) according to one of claims 1, characterized in that the rail ( 31 ) has a curvature about the axis of rotation (A) and a curvature about the pivot axis (B). Contraption ( 10 ) according to claim 2, characterized in that the rail ( 31 ) is adapted in shape and orientation to a latitude associated therewith on which the device is used. Contraption ( 10 ) according to claim 3, characterized in that the rail ( 31 ) is interchangeable. Contraption ( 10 ) according to one of claims 1 to 4, characterized in that the rail ( 31 ) is designed such that its shape and its orientation within the guide device ( 30 ) the mean solar ephemerides of latitude on which the device ( 10 ) is used. Contraption ( 10 ) according to one of claims 1 to 5, characterized in that the rail ( 31 ) a slide guide ( 34 ), a guide tube ( 35 ), a flat guide ( 36 ) o. The like. Is. Contraption ( 10 ) according to one of claims 1 to 6, characterized in that in the rail ( 31 ) a guide slot ( 33 ) is trained. Contraption ( 10 ) according to one of the preceding claims, characterized in that on the fastening device ( 40 ) at least one guiding element ( 32 ), which is in the rail ( 31 ), preferably in the guide slot ( 33 ) of the rail ( 31 ). Device according to one of the preceding claims, characterized in that an additional adjusting element ( 12 ) for fine adjustment of the output pivot angle of the solar surface ( 20 ) is provided at the geographical latitude of the plant location. Contraption ( 10 ) according to one of the preceding claims, characterized in that on the device ( 10 ) a mark is attached, which the preferred azimuth orientation of the device ( 10 ) in the starting position. Contraption ( 10 ) according to one of the preceding claims, characterized in that the fastening device ( 40 ) with a support frame ( 14 ) connected is.

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