DE19718358A1 - Photovoltaic modules for solar installation - Google Patents

Abstract

The photovoltaic (PV) modules are alignable to the sun and includes several, separated support posts (8-10), each locating a PV module (3), rotatable about a vertical axis and aligned at a preset angle to the horizontal. For the simultaneous rotation of the PV modules is provided a circulating, driven element. The rotary mounting of the PV modules contains a gear wheel (7), while a circulating chain runs over the gear wheels. A drive gear wheel also engages the chain. A spring-loaded gear wheel may engage the chain for equalising thermal length expansion.

Description

The invention relates to a solar system with sun-orientable photovoltaic mo dulen (PV modules).

Solar systems are used to generate electrical energy from solar radiation and For reasons of economy, on the one hand, the structure should be as simple as possible exhibit. On the other hand, because of the movement of the sun over the horizon, there is one azimuthal tracking of the flat or tabular PV modules required.

To solve this problem it is provided that at least two at a distance orderly support columns each a PV module rotatably mounted about a vertical axis is and aligned at a predetermined angle to the horizontal (elevation angle) and a rotating driven on for simultaneous rotation of the PV modules Drive element is provided.

This means that a drive and a simultaneous drive need not be provided for each module Adjustment of the modules by the same angle is guaranteed.

It is expediently provided that the rotary mounting of the PV modules on the Supporting columns has a gear and a rotating chain ge over the gears leads, in which, in addition to the driven gears, a drive gear engages. This The chain and / or the gears can be used components.  

In order to compensate for thermal elongations, a spring action is applied to the drive chain gear.

A particularly inexpensive solar system can be achieved by opening the construction of the individual support column a used partial axle of a rigid car axle inserted is set, on whose rotatable wheel carrier the PV module is attached.

In order to securely wrap the Abtries gears even in a row-like arrangement To ensure several support columns, it is provided that the drive wheel and / or the tensioning wheel is laterally offset from the row so that the drive chain with a given wrap angle over the gears of the PV modules is led.

In order to easily adapt to the different heights of the To achieve sun run over the seasons, the PV modules are designed to a horizontal axis can be swiveled manually and in the individual swivel position can be locked.

To prevent contamination, it is provided that the drive chain is guided through protective tube sections.

An embodiment of the invention will now be described with reference to the accompanying figures are explained. It shows:

Fig. 1 is a perspective overall view of a ses on the gable roof of a Wohnhau arranged photovoltaic system with six photovoltaic devices,

Fig. 2 is a schematic representation of the adjustment of the angle of a tabular PV module (photovoltaic module) relative to a single photovoltaic device to the horizontal plane,

Fig. 3 shows an embodiment of a chain tensioning device and

Fig. 4, the integration of a drive shaft in the drive system of the photovoltaic system.

The photovoltaic system 1 shown in FIG. 1 has six photovoltaic units 2 . Each photovoltaic unit 2 has a panel-shaped PV module 3 , which emits an electrical voltage when the sun is shining and is carried by a holding frame 4 with a device 5 . The actuating device 5 enables a manual gradual adjustment of the angle (adaptation to the height angle of the sun position via Hori zont), which the PV module 3 includes with the horizontal plane, and consists of a sleeve 5 which engages between two frame parts 4 a and 4 b which can be pivoted relative to one another a with a pin 5 b engaging in the sleeve, the depth of penetration into the sleeve 5 a of which can be fixed by a pin not shown, which can be inserted into transverse bores 5 c of the sleeve.

The support frame part 4 b is welded to a perforated support plate 6 , the perforation of which corresponds to the perforation of the rotatable wheel carrier 7 of a rigid axle of a motor vehicle. The vertical support column 8 for the individual PV module is namely the half 9 of a used rigid axle of a car, which has been extended by a tube 10 of the same diameter by welding. The pipe 10 is passed through the bricking of the roof D and anchored in the beams of the roof structure. The brake shoes have been removed from the wheel carrier.

Between the support plate 6 and the top of the wheel carrier 7 , a gear 11 is arranged in the form of a disused pedal wheel of a bicycle and is rotatably connected to the wheel carrier with the wheel carrier when screwing the carrier plate.

The electrical connection line 12 from the PV module 3 to a switchgear, not shown, arranged in the house is guided from the outside through a hole in the support column and thus through the roof D.

In order to achieve a simultaneous pivoting of all PV modules 3 about a vertical axis (azimuth movement), a drive chain 13 composed of used bicycle chains is guided over the toothed wheels 11 of all photovoltaic units 2 . The drive chain 13 is simultaneously guided in the manner shown in FIGS . 1, 3 and 4 via a tension gear 14 and a drive gear 15 . These gears are also used bicycle sprockets.

According to Fig. 1 and 3 8 of the middle photovoltaic unit 2 the left in FIG. 1 series is out of the photovoltaic devices through the roof D a support tube 16 in the vicinity of the support column on which the idler gear 14 is mounted horizontally slidable and rotatable and which has a pressure spring unit 17 engaging the bearing of the tensioning wheel. The position of the support tube 16 relative to the support column 8 is such that a secure wrap around the gear 7 of the central photovoltaic unit is ensured. The resilient action on the tensioning wheel 14 compensates for thermal chain elongation between summer and winter.

The middle photovoltaic unit of the row on the right in FIG. 1 is assigned a further support tube 18 guided through the roof D, in the interior of which a drive shaft 19 is rotatably mounted. At its upper end, the drive gear 15 carrying drive shaft can be rotated ver by a drive unit, not shown, arranged in the roof. The drive unit adjusts the drive shaft 19 step by step in certain time intervals, for. B. every two hours by a predetermined angle of rotation for a period of a few seconds, and rotates the drive shaft after sunset in the morning position. Thus, the drive unit runs under energy consumption only for a period of time in the minute range during an operating day.

The arrangement of the support tube 18 relative to the middle right unit 2 is in turn chosen so that by guiding the chain around the drive gear 15 a secure Tel lumschlaltung the chain around the gear 7 of the middle column is achieved.

Without the special assignment of the tubes 16 and 18 to the support columns 8 of the middle units, the drive chain 13 would mesh with the gears 7 of the middle units only tangentially without sufficient wrap.

The support columns 8 and the support tubes 16 and 18 are supported against each other by essentially horizontal struts 20 . There are shown in Fig. 1 dashed lines clamping devices 21 for stiffening the system 1 against vibrations, which can occur when the system is exposed to wind.

Furthermore, the drive chain 13 is guided as far as possible between the gears 7 , 14 and 15 in plastic pipe sections 23 to prevent contamination in order to prevent contamination.

Claims (7)

1. Solar system with sun-orientable photovoltaic modules (PV modules), characterized in that on at least two spaced support columns ( 8 ; 9 , 10 ) each have a PV module ( 3 ) rotatably mounted about a vertical axis and under one pre-given angle to horizontal (height angle) is aligned and that a rotating driven drive element ( 13 ) is provided for simultaneous rotation of the PV modules. 2. Solar system according to claim 1, characterized in that the rotary bearing of the PV modules ( 3 ) on the support columns ( 8 ) has a gear ( 7 ) and on the gears ( 7 ) a circumferential chain ( 13 ) is guided in the in addition to the driven gears ( 7 ), a drive gear ( 15 ) engages. 3. Solar system according to claim 1 or 2, characterized in that a spring-loaded gear ( 14 ) engages in the drive chain ( 13 ) to compensate for thermal elongations. 4. Solar system according to at least one of claims 1-3, characterized in that a used partial axis ( 9 ) of a rigid car axle is used to build up the individual support column, on whose rotatable wheel carrier ( 7 ) the PV module ( 2 ) is fastened . 5. Solar system according to at least one of claims 1-4, characterized in that the drive wheel ( 15 ) and / or the tensioning wheel ( 14 ) is laterally offset against a number of PV modules ( 3 ) such that the drive chain ( 13 ) with a predetermined wrap angle over the gears ( 7 ) of the PV modules. 6. Solar system according to at least one of claims 1-5, characterized in that the PV modules manually pivotable about a horizontal axis ( 4 a, 4 b) and in the individual pivot position ( 5 a-c) can be locked. 7. Solar system according to at least one of claims 1-6, characterized in that the drive chain ( 13 ) is guided through protective tube sections ( 22 ).