DE10116783A1 - Device for locating extended supports for securing flat solar panels of consists mounting anchor fitted with cable tensioner - Google Patents

Abstract

The device consists of an L-shaped anchor (2), one limb (7) of which has a flat web base for mounting the anchor against e.g., a house wall, whilst a second flat limb (8) provides for mounting against a roof truss beam. This limb can be detachable and at the top has sleeve (9) through which can be inserted the threaded shaft of an eye bolt (10). This serves to secure and tension a wire cable (15). The first limb has a U-shaped cutout to accommodate a gutter.

Description

The invention relates to a device for fixing elongated Support elements for fastening flat solar components in the context of a Mounting system for flat solar components, two or more elongated support elements, especially wire ropes, at least in their preferably middle assembly area in a common plane, preferably parallel to each other.

The attachment of solar components should be done as cheaply as possible so that the Amortization of investment costs is completed as soon as possible. however In addition to the purely economic aspect, attention should also be paid to the Energy balance to be directed. For example. is a cumbersome screwing on elongated and voluminous aluminum profiles common, being completely does not take into account that aluminum with an extremely energy-intensive process must be melted, this energy expenditure in no relation to the energy that can be generated with a solar cell. Therefore it is already suggested been to switch to a filigree fastening technique as possible, for example by means of tensioned steel cables. The energy balance looks better here, however even have thicker steel cables with a cross section of 5 mm, for example comparatively high flexibility, which can only be achieved by means of high tensile forces of around 0.5-1 t tames. So far, however, there are no clamping devices for such in the trade high tractive forces available. Also, solar systems are often used on home or Garage roofs installed where the anchoring of such strong tensioned ropes brings additional problems.

This results in the problem initiating the invention, an inexpensive one and easy-to-use tensioning device and anchoring for steel cables too create with the tensile forces between 0.5 t and 1 t possible.  

Furthermore, solar systems are often used by the operator concerned, not infrequently a handyman, installed himself, who only has a limited set of tools and is therefore not in a position to, for example, the currently set To be able to check and adjust tensile forces of a tensioned wire rope. From this there is an additional problem that an inventive Fixing element should be able to, even when installing with the simplest Tool to be able to provide information about the current rope pulling force.

The primary problem is solved by an arrangement with one on one Building, e.g. house wall, roof structure or wall, or on a foundation fixed or fixable anchor element with an annular head; one Eyelet or hook element with a rotationally symmetrical shaft that through the annular head of the anchor element is inserted or insertable and has an external thread; as well as one on the external thread of the eyelet or Threaded screw element.

An integration of anchoring and tensioning device takes place here meets all requirements. The jig comprises two for tensioning the rope mutually displaceable elements, one of which at the same time as an anchoring element with fastening elements, e.g. Push-through openings for screws is formed. This allows this item with a double function, executed safely with sufficient strength be, for example, bent from a 5 mm or even thicker sheet steel blank. The on the other hand, displaceable tension element carries the for Rope anchor required eyelet or hook. and therefore also fulfills one Dual function. With its rear shaft, this eyelet element experiences one Guide in the sleeve (formed by bending) of the anchoring element. By the arrangement of anchorage and Eyelet element results in a very low use of material. The threaded element finally contains an important for the operability of the clamping device Reduction in the form of a (very) flat thread pitch. The threaded element can be provided on the outside with a hexagon or the like, so that it can be easily gripped with a wrench and rotated to the  to tension the relevant rope. The one derived from a rotary motion Clamping movement has the further advantage that by using a Wrench with a long or even extended handle for the purpose Rope tension applied torque can be further reduced.

A single, adjustable one is basically enough to tension a rope Tensioning element, while at the opposite end of the rope a (immovable, d. H. rigid) anchoring option is sufficient, provided that with the (only) Sufficient adjustment is possible to achieve the desired rope To be able to apply traction. To solve the secondary problem of the ad the current rope traction can therefore be in the traction transmission chain at any Place between the two on a building, foundation or the like Anchoring elements an element for displaying the current rope tension value be switched on. Spring elements are particularly suitable for this, since in these the deflection is proportional to the applied force. At the degree of The current rope traction can therefore be read from the deflection. Of course one could such a tensile force display element in the area of a rope end without Adjustment possibility or even arranged within the (in such a case divided) rope However, this is impractical because in this case the person hiring the cannot read the current voltage state itself and therefore always two Individuals are required for an appropriate setting. The traction The display element is therefore preferably in the area of an adjustable cable Arranged voltage element. Here is the space between the Anchor element on the one hand and a hook and interacting with it Eyelet element on the other hand, since in the arrangement according to the invention in this Range the rope tensile force into a compressive force acting between the two elements is converted. Thus, a compression spring with a sufficiently large Stiffness are used, their compression state is a measure of the current Rope tension is. By applying a scale calibrated in millimeters Such a (pressure) spring element can therefore have a spring constant taking into account the multiplication factor, the rope tensile force can be calculated. Naturally could also be a (tension) spring element between the hook or eye element and the rope be hung up.  

Advantageous embodiments of the invention are set out in the appended subclaims remove.

Further features, details, advantages and effects of the invention result from the following description of a preferred embodiment of the invention as well as from the drawing. Here shows:

Fig. 1 is a side view of a fixing element of the invention;

FIG. 2 shows a section through FIG. 1 along the line II-II;

Fig. 3 is a plan view of Fig. 1 in the direction of arrow III: and

Fig. 4 shows the detail IV from Fig. 3.

The two main components of the fixing element 1 of the invention are the predominantly planar anchoring part 2 on the one hand and the predominantly elongated eyelet part 3 on the other. In the embodiment shown, the anchoring part 2 is in turn subdivided into a fastening part 4 and a head part 5 releasably attached thereto. These two parts 4 , 5 each have approximately congruent, preferably square, tabs for mutual connection by means of screws 6 which extend through mutually aligned bores of both tabs. Of course, in another embodiment, the anchoring part 2 can also be made in one piece.

The base area of the anchoring part 2 can be approximately characterized as L. While one leg 7 of the L is given a T-profile by a flat and centrally welded flat iron and is thus insensitive to bending even under high loads, the guide sleeve 9 for the eyelet part 3 is arranged at the free end of the other leg 8, the latter Longitudinal axis runs approximately parallel to the leg 7 with a T-profile. The tensioning direction and thus also the direction of the tensile force to be absorbed is thus defined and points in the direction of the T-profiled leg 7 .

The other leg 8 also has a flat shape, which lies in one plane with the central web 12 of the T-profile 7 and therefore does not show any tendency to deform even with high tensile forces.

The T-profile leg 7 can have 12 mounting holes on its central web and also - as symmetrically as possible - on the longitudinally welded stiffening flat bar 13 . While with the former an attachment to one side of a rafters is possible, the stiffening flat iron 13 also gripping under the relevant rafters, the latter are used for screwing to a house wall or the like. However, the eyelet element 3 is preferably rotated by 180 ° from the other End face inserted into the guide sleeve 9 , so that there is a more favorable statics.

A recess 11 in the inside of the T-profile leg 7 is able to grip under or encompass any gutter when installed on a rafter, and gives the base of the fixing element 1 an approximately U-shaped shape.

The division of the anchoring part 2 into two parts 7 , 8 also allows the leg 8 to be connected, for example, to a rail, for example cemented vertically into the floor in the form of a point foundation, for example also T-shaped. As a result, a rope or the like can be anchored with the simplest means even without an existing building. For further simplification, an annular element can also be formed directly on such a rail.

At the rear end of the shaft 14 of the eyelet part 3 , which has approximately twice the length of the guide sleeve 9 , there is an external thread onto which two threaded elements 16 with an external hexagon are screwed, which can counter each other. Since the outer diameter of the shaft 14 corresponds approximately to the inner diameter of the guide sleeve 9 , the outer circumference of a screwed-on threaded element 16 is significantly larger than the sleeve diameter - the threaded element 16 is supported on the rear end face of the guide sleeve 9 . This force is transmitted with rotation of the front threaded member 16 relative to the eyelet 3 in the latter and received from this a mounted tensioning rope 15 °.

Instead of an eyelet 10 , a hook, a U-shaped part or the like can also be provided for hanging the tensioning cable 15 .

As can be seen in FIG. 1, the fastening part 4 can be detached from the head part 5 and fixed again in a position rotated by 90 °. Here, the gutter recess 11 reaches the area behind the threaded elements 16 and does not hinder their rotation by means of a wrench. This configuration is particularly suitable for the anchoring and tensioning of a steel cable 15 on the top of a concrete flat roof encircled by a wall, in which case the cables 15 are tensioned from wall to wall. The steel cable 15 is threaded through the eyelet 10 and then fixed to itself, in particular clamped.

Since the length of the threaded shaft area of the eyelet part 3 and also the depth of the gutter recess 11 may be 1 to 5 cm, preferably 2 to 4 cm, there is a large scope for rope tensioning.

In FIG. 4 it can be seen that a compression spring 17 , for example a spiral spring, can be inserted between the end face of the guide sleeve 9 facing away from the cable 15 and the threaded elements 16 serving for locking, which surrounds the shaft 14 of the eyelet part 3 and is thereby guided is. The compression spring 17 can be clamped between two washers 18 , 19 , which derives the spring force on the mutually movable parts 2 , 3 . The tensile force increased with tension of the rope 15 leads to a compression of the compression spring 17 , the length of which can be measured in order to be able to determine the rope tensile force with sufficient accuracy. To avoid calculation errors, a reference to a mounting element the deflection force of the spring 17 in kilopond kp, Newton N, tons t or the like. a calibrated scale and / or a marking 20 , in particular on an extension 21 parallel to the shaft 14 . An annular disk 18 , 19 is particularly suitable for this, since the distance between the two disks 18 , 19 corresponds to the current spring length 17 and thus the cable tensile force. The zero point 22 of such a scale can therefore in a fixed (to axis 14 parallel) spaced from the plane of the respective (with the extension 21 is provided) wheel 18, 19 can be arranged, wherein the (uncompressed) length of the spring corresponds to the 17th This scale is read from the relative position of the other ring disk 19 , 18 .

An advantageous property of the anchoring part 2 is that it can be used without an eyelet part 3 for anchoring rod-like supporting elements if a particularly high stability of the supporting structure is required.

Further modifications are conceivable. Thus, the leg 7 profiled in the example T can be stiffened by a welded tube instead of by a welded flat iron 13 . The anchoring part 2 can be realized with flags, tabs or the like which can be cemented into a wall, etc.

Tensioned ropes 15 can run at any angle of inclination in order to enable the solar panels to be oriented to the south. For this purpose, the anchoring elements 2 can be cemented in at an appropriate angle, and / or the ropes 14 are guided over deflecting elements, in particular rollers, which can be fastened or stored on the foundations for the anchoring elements 2 or on their own foundations.

All parts can be made of stainless steel and / or galvanized.

Claims (18)

1. Element for fixing elongated support elements for fastening flat solar components, wherein two or more elongated support elements, in particular wire ropes ( 15 ), are arranged at least in their preferably central assembly area in a common plane, preferably parallel to one another, characterized by

• a) an anchor element ( 2 ) fixed or fixable to a building, for example a house wall, roof truss or wall, or to a foundation with an annular or sleeve-shaped head ( 9 );
• b) an eyelet or hook element ( 3 ) with a rotationally symmetrical shaft ( 14 ) which is inserted or can be inserted through the ring-shaped or sleeve-shaped head ( 9 ) of the anchor element ( 2 ) and has an external thread; such as
• c) a threaded element ( 16 ) which can be screwed onto the external thread of the eyelet or hook element ( 3 ).

2. Fixing element according to claim 1, characterized in that the anchor element ( 2 ) is formed from one or more sheet metal blanks, in particular is bent. 3. Fixing element according to claim 2, characterized in that the head ( 5 ) of the anchor element ( 2 ) has the shape of a hollow cylinder which is formed by bending the sheet metal blank. 4. Fixing element according to one of claims 1 to 3, characterized in that the anchor element ( 2 ) has a fastening part ( 4 ). 5. Fixing element according to one of the preceding claims, characterized in that the fastening part ( 4 ) of the anchor element ( 2 ) has a flat base surface ( 12 ) with screw openings for screwing onto a beam of a roof truss. 6. Fixing element according to claim 5, characterized in that the base surface ( 12 ) of the fastening part ( 4 ) of the anchor element ( 2 ) has a top-side notch or recess ( 11 ). 7. Fixing element according to claim 6, characterized in that the top-side notch or recess ( 11 ) in the base surface ( 12 ) of the fastening part ( 4 ) of the anchor element 82 ) corresponds approximately to or is greater than the cross-section of a gutter. 8. Fixing element according to one of the preceding claims, characterized in that the fastening part ( 4 ) of the anchor element ( 2 ) has a base plate ( 13 ) extending perpendicular to its base surface ( 12 ). 9. Fixing element according to one of claims 4 to 8, characterized in that the base plate ( 13 ) of the fastening part ( 4 ) projects beyond it on both sides. 10. Fixing element according to one of the preceding claims, characterized in that fastening bores are provided in the regions of the base plate ( 13 ) which project beyond the base surface ( 12 ) of the fastening part ( 4 ). 11. Fixing element according to one of the preceding claims, characterized in that the fastening part ( 4 ) of the anchor element ( 2 ) is detachably connected to the head ( 5 ). 12. Fixing element according to claim 11, characterized in that the connection between anchor ( 2 ) and eyelet or hook element ( 3 ) by means of flat, overlapping next to each other and screwed together sheet metal tabs. 13. Fixing element according to claim 11 or 12, characterized in that the anchor element ( 2 ) pivoted through an angle about an axis perpendicular to its base surface ( 12 ) on the head element ( 5 ) can be fixed. 14. Fixing element according to claim 13, characterized in that the Swivel angle is about 90 °. 15. Fixing element according to one of the preceding claims, characterized in that the head ( 5 ) and fastening part ( 4 ) of the anchor element ( 2 ) are molded together. 16. Fixing element according to one of the preceding claims, characterized in that the hanging eye ( 10 ) of the eyelet or hook element ( 3 ) is formed by bending the shaft ( 14 ) thereof. 17. Fixing element according to one of the preceding claims, characterized in that the outer diameter of the shaft ( 14 ) of the eyelet or hook element ( 3 ) is only slightly smaller than the inner diameter of the head ( 5 ) of the anchor element ( 2 ). 18. Fixing element according to one of the preceding claims, characterized in that the eyelet or hook element ( 3 ) from the head ( 5 ) of the anchor element ( 2 ) can be removed in order to insert a rod-like support element directly and to fix it with a threaded element ( 16 ) can.