DE102022111639A1 - Photovoltaic module arrangement with foldably coupled, essentially rectangular photovoltaic modules - Google Patents

Abstract

In a photovoltaic module arrangement for arranging at least two, essentially rectangular photovoltaic modules, which are foldably coupled to one another by means of at least one joint, the at least one joint is designed as a rod hinge along each side of the essentially rectangular photovoltaic modules.

Description

Background of the invention

The invention relates to a photovoltaic module arrangement for arranging at least two, essentially rectangular photovoltaic modules, which are foldably coupled to one another by means of at least one joint.

Photovoltaic module arrangements, which can also be referred to as photovoltaic systems, generally include a large number of photovoltaic modules, which convert the radiant energy of sunlight into an electrical voltage by using the photoelectric effect. In order to arrange such photovoltaic modules in a suitable position and orientation relative to the sun, various types of photovoltaic module arrangements are known. Such types include arrangements installed in a stationary manner on building roofs or in open spaces, as well as arrangements in which the photovoltaic modules are foldably coupled to one another and in this way can be moved together and apart in particular in order to be stowed in particular in a container.

Underlying task

The invention is based on the object of improving a photovoltaic module arrangement with photovoltaic modules that are foldably coupled to one another in such a way that they are particularly easy to manufacture and easy to store.

Solution according to the invention

This object is achieved according to the invention with a photovoltaic module arrangement for arranging at least two, essentially rectangular photovoltaic modules, which are foldably coupled to one another by means of at least one joint, the at least one joint being designed as a rod hinge along each side of the essentially rectangular photovoltaic modules.

With such a solution according to the invention and such a rod hinge, which can also be referred to as a band hinge or piano hinge, a particularly compact, statically rigid and at the same time particularly cost-effective arrangement of foldable, retractable and extendable photovoltaic modules is created.

In the photovoltaic module arrangement according to the invention, the at least two photovoltaic modules are preferably designed with a module surface and at least one support strip supporting this module surface, and the rod hinge is formed along the support strips. With such a rod hinge, a direct, immediate static connection to the adjacent support bar and thus a support that advantageously extends over the entire length of the support bar is created.

The individual support bar is preferably designed with a substantially rectangular cross-sectional shape when viewed in cross section. The support strip of this type is simple and inexpensive to produce, and at the same time the cross-sectional shape of this type enables a stable supporting effect and an advantageous folding effect in relation to the stationary and rigid arrangement of photovoltaic modules to be created here, especially in the extended state.

The substantially rectangular cross-sectional shape of the support bar is preferably designed with a first, slightly oblique side which is inclined to a second side of the substantially rectangular cross-sectional shape at an angle of between 75° and 85°, in particular between 78° and 82° . With such a slightly inclined side of the support strip according to the invention, a support for the associated photovoltaic module or modules can advantageously be created at the same time.

With two adjacent first, slightly sloping sides, two support surfaces of adjacent photovoltaic modules to be placed against one another are advantageously designed. These support surfaces can be placed against one another when the photovoltaic modules according to the invention are unfolded and in this way the photovoltaic modules involved can be supported directly against one another.

The rod hinge according to the invention is preferably designed with a hinge axis which, viewed in cross section, is arranged essentially in a corner of the essentially rectangular cross-sectional shape of the support strip. A joint axis supported in this way is statically arranged in a particularly rigid manner and at the same time a spatially advantageous position of the associated joint is created.

The individual support bar is preferably designed with a continuously cast aluminum profile. By means of such a continuously cast profile made of aluminum or an aluminum alloy, the inventive design of a rod hinge along one side of a photovoltaic module can be produced particularly cost-effectively and at the same time statically stable and durable in relation to environmental conditions.

Particularly preferably, the rod hinge is formed by means of at least one hinge recess in one of the support strips into which a hinge is inserted cylinder of the other support bar engages. The rod hinge of this type can be produced in a particularly cost-effective manner simply by removing material from at least one of the support strips.

Furthermore, the rod hinge is advantageously designed by means of a hinge rod which is inserted into hinge cylinders arranged one behind the other. As a single component, the hinge rod forms a plurality of individual hinge parts in cooperation with the hinge cylinders, which together create the rod hinge according to the invention and which thus produce both a folding and a supporting effect over the length of the associated photovoltaic module.

Furthermore, the support strips according to the invention are particularly preferably designed to be sealed against one another. The seal in particular prevents water in the form of rain or the like from getting between the support strips. This means that ice formation in particular can be prevented in this area between the support strips.

Brief description of the drawings

• 1 eine perspektivische Ansicht eines Ausführungsbeispiels einer erfindungsgemäßen Photovoltaikmodulanordnung im eingefahrenen Zustand,
• 2 die Ansicht gemäß 1 der Photovoltaikmodulanordnung während des Ausfahrens,
• 3 die Ansicht gemäß 1 der Photovoltaikmodulanordnung im ausgefahrenen Zustand,
• 4 eine Seitenansicht von Photovoltaikmodulen der Photovoltaikmodulanordnung gemäß 1 im eingefahrenen Zustand,
• 5 eine perspektivische Ansicht der Photovoltaikmodule gemäß 4 während des Ausfahrens,
• 6 eine perspektivische Ansicht der Photovoltaikmodule gemäß 4 im ausgefahrenen Zustand,
• 7 eine perspektivische Ansicht eines Eckbereichs eines Photovoltaikmoduls gemäß 6 im montierten Zustand mit dessen Stützrahmen,
• 8 die Ansicht gemäß 7 im unmontierten Zustand,
• 9 die Ansicht gemäß 7 im teilmontierten Zustand,
• 10 eine perspektivische Ansicht eines Mittelbereichs eines Photovoltaikmoduls gemäß 6 im teilmontierten Zustand,
• 11 eine perspektivische Ansicht eines Teils des Stützrahmens des Photovoltaikmoduls gemäß 6,
• 12 eine perspektivische Ansicht zweier oberer Längsstützleisten von Stützrahmen gemäß 11,
• 13 das Detail XIII gemäß 12 in vergrößerter Ansicht im ausgefahrenen Zustand mit Seitenstützleisten und Kabelschächten,
• 14 die Ansicht gemäß 13 mit zusätzlicher Kabelführung,
• 15 das Detail XIII gemäß 12 in vergrößerter Ansicht im eingefahrenen Zustand,
• 16 eine perspektivische Ansicht zweier unterer Längsstützleisten von Stützrahmen gemäß 11,
• 17 das Detail XVII gemäß 16 in vergrößerter Ansicht im eingefahrenen Zustand,
• 18 das Detail XVII gemäß 16 in vergrößerter Ansicht im ausgefahrenen Zustand mit Seitenstützleisten, Rollenschiene und Rückhalteelementen,
• 19 das Detail IXX gemäß 18 in vergrößerter Ansicht,
• 20 eine perspektivische Unteransicht eines Teils zweier unterer Längsstützleisten gemäß 16,
• 21 eine perspektivische Seitenansicht eines Teils eines Photovoltaikmoduls an dessen unterer Längsstützleiste mit Rollen und Rollenschiene,
• 22 eine perspektivische Draufsicht eines Teils zweier Photovoltaikmodule an deren unteren Längsstützleisten mit Rückhalteelementen,
• 23 die Ansicht gemäß 18 mit Schienenverbinder und einem Teil einer Erdankervorrichtung,
• 24 eine perspektivische Seitenansicht einer ersten Ausführungsform eines Zugmittelantriebs für die Photovoltaikmodulanordnung gemäß 1,
• 25 das Detail XXV gemäß 24,
• 26 eine perspektivische Seitenansicht einer zweiten Ausführungsform eines Zugmittelantriebs für die Photovoltaikmodulanordnung gemäß 1 und
• 27 das Detail XXVII gemäß 26.

An exemplary embodiment of a solution according to the invention is explained in more detail below using the attached schematic drawings. It shows:

• 1 a perspective view of an exemplary embodiment of a photovoltaic module arrangement according to the invention in the retracted state,
• 2 according to the view 1 the photovoltaic module arrangement during extension,
• 3 according to the view 1 the photovoltaic module arrangement in the extended state,
• 4 a side view of photovoltaic modules according to the photovoltaic module arrangement 1 in the retracted state,
• 5 a perspective view of the photovoltaic modules according to 4 while driving out,
• 6 a perspective view of the photovoltaic modules according to 4 in the extended state,
• 7 a perspective view of a corner area of a photovoltaic module 6 when assembled with its support frame,
• 8th according to the view 7 in the unassembled state,
• 9 according to the view 7 in partially assembled state,
• 10 a perspective view of a central region of a photovoltaic module according to 6 in partially assembled state,
• 11 a perspective view of part of the support frame of the photovoltaic module 6 ,
• 12 a perspective view of two upper longitudinal support strips of support frames 11 ,
• 13 the detail XIII according to 12 in an enlarged view in the extended state with side support strips and cable ducts,
• 14 according to the view 13 with additional cable routing,
• 15 the detail XIII according to 12 in an enlarged view in the retracted state,
• 16 a perspective view of two lower longitudinal support strips of support frames 11 ,
• 17 according to detail XVII 16 in an enlarged view in the retracted state,
• 18 the detail XVII according to 16 in an enlarged view in the extended state with side support strips, roller rail and retaining elements,
• 19 the detail IXX according to 18 in an enlarged view,
• 20 a perspective bottom view of part of two lower longitudinal support strips 16 ,
• 21 a perspective side view of part of a photovoltaic module on its lower longitudinal support bar with rollers and roller rail,
• 22 a perspective top view of part of two photovoltaic modules on their lower longitudinal support strips with retaining elements,
• 23 according to the view 18 with rail connector and part of a ground anchor device,
• 24 a perspective side view of a first embodiment of a traction drive for the photovoltaic module arrangement 1 ,
• 25 the detail XXV according to 24 ,
• 26 a perspective side view of a second embodiment of a traction drive for the photovoltaic module arrangement 1 and
• 27 the detail XXVII according to 26 .

Detailed description of the exemplary embodiment

A photovoltaic module arrangement 10 is created by means of a container 12, the outer skin of which is designed with a container bottom surface 14, two container end surfaces 16, two container side surfaces 18 and a container ceiling surface 20. The container 12 is used to hold a plurality of photovoltaic modules 22, which can be moved out of the container 12 by means of roller rails 24 and can also be moved back into it.

The individual photovoltaic module 22 in turn has several module surfaces 26, which are individually surrounded or enclosed by a module frame 28, in particular in the form of an L-profile or C-profile. There is a cable 30 on each module surface 26, which is connected there and is used in particular to carry away electrical current, which is generated by the module surface 26 when the module surface 26 is irradiated with sunlight.

For each photovoltaic module 22, four module surfaces 26 are provided next to each other in a portrait format arrangement, the module surfaces 26 arranged in this way being surrounded by a support frame 32. The support frame 32 is made of an extruded aluminum profile by means of support strips 34, with two side support strips 36, three central support strips 38, a lower longitudinal support strip 40 and an upper longitudinal support strip 42 being provided. The side support strips 36 and the central support strips 38 are also referred to here as first support strips, while the longitudinal support strips 40 and 42 are also referred to as second support strips.

To connect the support strips 34 to the associated support frame 32, the side support strips 36 have a first stop surface 44 on the front side for placing a longitudinal support strip 40 or 42 and a second stop surface 46 on the side, also for placing the respective longitudinal support strip 40 or 42. On the first support strips, i.e. the side support strips 36 and the central support strips 38, a module groove 48 is formed on the side for receiving the edge of an associated module surface 26, in particular of its module frame 28. Likewise, a module groove 50 is formed on each of the second support strips, i.e. the lower longitudinal support strips 40 and the upper longitudinal support strips 42, towards the top and bottom. The respective module frame 28 is inserted into these module grooves 48 and 50 and in this way is positively enclosed or enclosed by the support strips 34.

The first and second support strips are each coupled in a stationary manner by means of a connector 52. The connector 52 includes a first connector section 54 in the form of a connector head and a second connector section 56 in the form of a connector pin. The connector pin is inserted into a front end region 58 of one of the first support strips, while the connector head protrudes from this end region 58. By means of an adjusting device 60 on the second connector section 56, the position of the connector head relative to the connector pin can be changed and fixed. The adjusting device 60 is accessible through an adjusting opening 62, which is formed in the respective first support bar. A connector groove 64 is formed along the associated second support strip, into which the connector head is to be inserted laterally and on which it then engages behind. With the connector head engaging behind in this way and its fixation with the introduction of tensile force towards the first support bar, the second support bar can be coupled to the respective first support bar in a stable and yet releasable manner.

A cable duct or cable duct 66 for receiving at least one of the cables 30 is formed along the length of one of the side support strips 36. For this purpose, the side support strip 36 is designed laterally with a groove or a U-shaped basic shaft shape 68, onto which a shaft cover 70 is clamped. In the side support strip 36, as alternatively or additionally in one of the central support strips 38, a cable opening 72 is formed which passes through the respective strip. Through the cable opening 72, cables 30 can be laid in the plane or thickness of the support strips 34 themselves and thus within the thickness of the support frames 32. At the end regions of such cable ducts 66 there is a movable cable guide 74, in particular in the form of a link chain, a bellows or a bendable hose, by means of which the cables 30 are protected and at the same time movably guided or guided from a cable duct 66 into the subsequent cable duct 66 could be. The respective cable guide 74 has an end region 76 on each of its two front ends, by means of which the cable guide 74 is inserted into the cable shaft 66 there and is held in a form-fitting manner in this way.

The cable duct 66 can alternatively or additionally also extend along or within one or more of the center support strips 38.

Like in particular 15 until 19 can be clearly seen, the lower longitudinal support strips 40 and the upper longitudinal support strips 42 each have a substantially rectangular cross-sectional shape 78, with a first side 80 of this cross-sectional shape 78 being slightly inclined. A second Page 82, a third page 84 and a fourth page 86 then form the remaining rectangular shape. The slightly sloping side 80 forms a mutual support or support surface 88 for the unfolding support frames 32, as particularly shown in FIG 13 , 18 and 19 is clarified. A sealing groove 90 is embedded in the support surface 88, in each of which there is a sealing bead 92. With two adjacent first, slightly sloping sides 80, two support surfaces of adjacent photovoltaic modules 22 to be placed against one another are designed. These support surfaces are placed against one another when the photovoltaic modules 22 are unfolded and in this way the photovoltaic modules 22 involved are supported directly against one another. Alternatively, a rod-like or rope-like strut can be provided as a stiffener between two adjacent photovoltaic modules 22.

The cross-sectional shape 78 also has a first corner 94 and a second corner 96 on the outside in relation to the support frame 32 formed with it. In the area of the first corner 94, a joint 98 is designed in the form of a rod hinge, by means of which two support frames 32 are coupled to one another in an articulated or foldable manner. A joint axis 100 of this joint 98 extends over the entire length of the associated longitudinal support strip 40 and 42. Alternate hinge recesses 102 are also formed in the longitudinal support strips 40 and 42 involved, so that hinge cylinders 104 remain in sections in succession for each longitudinal support strip 40 and 42. A rod-shaped hinge rod 106 is finally inserted into these hinge cylinders 104, which are then placed one inside the other in a “comb-like” manner, and with this the joint axis 100 is formed.

In the lower longitudinal support strips 40, two roller recesses 108 are also formed in the area of the respective second corner 96, distributed over the longitudinal extent of the longitudinal support strips 40. Furthermore, at the second corners 96 on each of the two roller recesses 108, a roller 110 is held freely rotatable by means of a rod-shaped roller axis 112. The rollers 110 have a roller radius 114 and a roller width 116 and roll on the roller rail 24 located underneath. With two lower longitudinal support strips 40 pivotally mounted on one another, this results in a total of four rollers 110 protruding downwards from the longitudinal support strips 40, two of which lie close to each other and as such form a pair of rollers (see in particular 19 ).

There are two roller rails 24 laid out in parallel alignment above the ground in front of the container 12 and anchored there in a fixed manner. The individual roller rail 24 is divided into individual, successive rail sections, which are rigidly coupled to one another by means of rail connectors 118. These rail connectors 118 are supported in a stationary manner downwards into the ground by means of earth anchor devices 120.

Each roller rail 24 is designed with a first roller rail surface 122 and a second roller rail surface 124. Between these roller rail surfaces 122 and 124 there is an upwardly projecting guide web 126. Of a pair of rollers mentioned above, one roller 110 is then located on one side of the guide web 126 on the first roller rail surface 122 while the other roller 110 is on the other side of the guide web 126 is located on the second roller rail surface 124.

Furthermore, there are two retaining elements 128 on the lower longitudinal support strips 40 in the area of a roller rail 24. The individual retaining element 128 is equipped with a rod 130 passing through the associated longitudinal support strip 40, an upward-pointing operating head 132 with a pivotable operating lever 134 and a downward-pointing one Locking bar 136 designed. In the adjacent roller rail 24 there is then a locking opening 138 in the respective roller rail surface 122 or 124, into which the locking bar 136 can engage and thus hook onto the roller rail 24.

In such a photovoltaic module arrangement 10, a plurality of photovoltaic modules 22 are foldably coupled to one another by means of at least one joint 98. Each photovoltaic module 22 is formed from several module surfaces 26, which are individually enclosed by a module frame 28 that is particularly L-shaped or C-shaped in cross section. The module surfaces 26 are then enclosed together with their module frames 28 by the supporting support strips 34, which form the respective support frame 32. The lower ones of these support strips 34 are supported by two rollers 110 on an associated roller rail surface 122 or 124 and can be moved there. The associated support bar 34 specifically has a roller recess 108 in which an associated roller 110 is at least partially accommodated. With the rollers 110 partially integrated into the support strips 34, an extremely compact design is created for storing the photovoltaic modules 22 in the container 12 and at the same time a particularly smooth and smooth extension and retraction of the two rollers 110 per module fold and roller rail.

The lower and upper support strips 34 are identical in construction and cross-sectional as lower longitudinal support strips 40 and upper longitudinal support strips 42, respectively tet designed with a substantially rectangular cross-sectional shape 78. The essentially rectangular cross-sectional shape 78 of these support strips 34 is designed with the first, slightly oblique side 80, which is at an angle of between 75° and 85°, in particular between 78° and 82°, to the second side 82 of the essentially rectangular cross-sectional shape 78 ° is tilted.

The rollers 110 are designed with the roller radius 114 such that this roller radius 114 is larger than half of the side 80, 82, 84, or 86 of the essentially rectangular cross-sectional shape 78. The roller 110 is further designed with a roller running surface that is essentially flat when viewed in longitudinal section. The roll width 116 is between 1.5 and 2.5 times, in particular between 1.8 and 2.2 times, the roll radius 114. The roll axis 112 is also designed to be fixed in relation to the associated support bar 34.

The joint 98 is designed as a rod hinge. As explained, the rod hinge is formed in particular along the upper and lower support strips 34 and is formed by means of the mutually following hinge recesses 102 in the two opposite support strips 34, with a hinge cylinder 104 of one support strip 34 engaging in the hinge recess 102 of the other support strip 34. The hinge rod 106 is then inserted into the hinge cylinders 104 arranged one behind the other.

The photovoltaic modules 22 are each designed with the module surfaces 26 located therein with the support frame 32 which completely encompasses or encompasses these module surfaces 26. With two joints 98 each, an upper joint 98 and a lower joint 98, these photovoltaic modules 22 are then successively coupled to one another in a W-shape or zigzag shape by means of their two support frames 32. The respective module surface 26 is rectangular and the support frame 32 is, as shown, designed with four outer supporting support strips 34, which are arranged along each of the four sides of the associated module surface 26. For each photovoltaic module 22, four module surfaces 26, each arranged in portrait format, are arranged next to each other and the support frame 32 is designed with a central support strip 38 between each two of these module surfaces 26. There are two support strips 34 aligned at right angles to one another and coupled to one another in a stationary manner by means of an associated connector 52, the connector 52 with the first connector section 54 protruding from an end face of the first support strip 34 and protruding into a longitudinal side of the second support strip 34. By means of the adjusting device 60, the first connector section 54 can be adjusted and fixed as a connector head relative to the second connector section 56.

The retaining elements 128 pass through both the associated support strip 34 and the roller rail 24 located there. With them, the photovoltaic modules 22 are in particular in 6 shown, extended state on the roller rails 24 and further retained in the surrounding soil by means of the ground anchor devices 120 and thus secured in particular against lifting due to wind forces acting on the photovoltaic modules 22. The associated rod 130 can be rotated by means of the operating lever 134, which causes the locking bar 136 to be hooked and unhooked at the associated locking opening 138. The locking openings 138 are each designed as an elongated hole passing through the associated roller rail 24.

In the 24 until 27 Two embodiments of traction drives 140 are illustrated, by means of which the movement of the photovoltaic modules 22 is carried out when extending and retracting on the roller rails 24. The individual traction drive 140 extends along an associated roller rail 24 over its entire longitudinal extent.

The traction drive 140 according to 24 and 25 is designed with a traction means 142 in the form of a belt which has teeth 144 facing outwards. Furthermore, the belt also has inwardly facing (not visible) teeth and is mounted with these on associated gears 146. The rotational movement of the traction means 142 is to be driven by means of a drive motor 148, which is to be optionally plugged into at least one drive socket 150 on one of the gears 146 and whose rotational movement is to be transmitted, in particular by means of a coupling shaft 152, to an adjacent traction drive 140 on a parallel roller rail 24. The orbital movement of the teeth 144 on the traction means 142 is then transmitted in a force-conducting manner by means of a coupling device 154 in the form of a T-shaped foot to the respectively assigned photovoltaic modules 22 and in particular to their lower longitudinal support strips 42.

In the embodiment according to 26 and 27 the traction means 142 is designed in the form of a chain.

Finally, it should be noted that all features mentioned in the application documents and in particular in the dependent claims, despite the formal reference made to one or more specific claims, should also be given independent protection individually or in any combination.

Reference symbol list

10

Photovoltaic module arrangement

12

Container

14

Container floor area

16

Container end face

18

Container side surface

20

Container ceiling surface

22

Photovoltaic module

24

Roller rail

26

Module area

28

Module frame

30

Cable

32

Support frame

34

Support bar

36

Side support bar (first support bar)

38

Middle support bar (first support bar)

40

lower longitudinal support bar (second support bar)

42

upper longitudinal support bar (second support bar)

44

first stop surface on side support bar (front side)

46

second stop surface on side support bar (side)

48

Module groove (side, first support bar)

50

Module groove (bottom/top, second support bar)

52

Interconnects

54

first connector section (connector head)

56

second connector section (connector pin)

58

front end area of the first support bar

60

Adjustment device

62

Adjustment opening

64

connector groove

66

Cable duct on side support bar

68

Basic shaft shape

70

manhole cover

72

Cable opening

74

Cable routing

76

End area of the cable guide

78

Cross-sectional shape of the support bar

80

first, slightly slanted page

82

second page

84

third party

86

fourth page

88

Support surface of the support bar

90

sealing groove

92

sealing bead

94

first corner (joint axis)

96

second corner (roller axis)

98

joint

100

Joint axis

102

Hinge recess

104

Hinge cylinder

106

Hinge rod

108

Roller recess

110

role

112

Roller axis

114

Roll radius

116

Roll width

118

Rail connector

120

Earth anchor device

122

first roller rail surface

124

second roller rail surface

126

Guide bridge

128

Retaining element

130

Rod

132

Control head

134

Control lever

136

Locking latch

138

Locking opening

140

Traction drive

142

traction means

144

Tooth

146

gear

148

drive motor

150

Drive connection

152

coupling shaft

154

Coupling device

Claims (10)

Photovoltaic module arrangement (10) for arranging at least two, essentially rectangular photovoltaic modules (22), which are foldably coupled to one another by means of at least one joint (98), characterized in that the at least one joint (98) is designed as a rod hinge along each side of the in Essentially rectangular photovoltaic modules (22) are designed. Photovoltaic module arrangement according to Claim 1 , characterized in that the at least two photovoltaic modules (22) are each designed with a module surface (26) and at least one support strip (34) supporting this module surface (26) and the rod hinge is formed along the support strips (34). Photovoltaic module arrangement according to Claim 2 , characterized in that the individual support strip (34), viewed in cross section, is designed with a substantially rectangular cross-sectional shape (78). Photovoltaic module arrangement according to Claim 2 or 3 , characterized in that the substantially rectangular cross-sectional shape (78) of the support bar is designed with a first, slightly oblique side (80) which is at an angle of between 75 to a second side (82) of the substantially rectangular cross-sectional shape (78). ° and 85°, in particular between 78° and 82°. Photovoltaic module arrangement according to one of the Claims 2 until 4 , characterized in that two supporting surfaces (88) of adjacent photovoltaic modules (22) to be placed against one another are designed with two adjacent first, slightly sloping sides (80). Photovoltaic module arrangement according to one of the Claims 2 until 5 , characterized in that the rod hinge is designed with a hinge axis (100) which, viewed in cross section, is arranged essentially in a corner (94) of the essentially rectangular cross-sectional shape (78) of the support strip (34). Photovoltaic module arrangement according to one of the Claims 2 until 6 , characterized in that the individual support bar (34) is designed with a continuously cast aluminum profile. Photovoltaic module arrangement according to one of the Claims 2 until 7 , characterized in that the rod hinge is formed by means of at least one hinge recess (102) in one of the support strips (34), into which a hinge cylinder (104) of the other support strip (34) engages. Photovoltaic module arrangement according to one of the Claims 2 until 8th , characterized in that the rod hinge is designed by means of a hinge rod (106) which is inserted into hinge cylinders (104) arranged one behind the other. Photovoltaic module arrangement according to one of the Claims 1 until 9 , characterized in that the support strips (34) are designed to be sealed against one another.

Images