GR1010306B - Self-supported shelters with covering photovoltaic elements and shading fabric - Google Patents

Abstract

The invention relates to single-sided or double-sided shading shelters capable of carrying photovoltaic elements placed outdoors. Said shelters consist of a pole and a single-sided or double-sided deployment rafter of frame of at least 2.5m, placed at least every 2.5m in length. The members of the structure are connected to each other with special connectors which ensure the reclining of the above rafters. The invented shelters are able to be deployed in unlimited length; they are calculated according to the latest-version Eurocodes and can withstand very severe weather conditions.

Description

DESCRIPTION

SELF-SUPPORTED ROOFS WITH PHOTOVOLTAIC ELEMENT COATING

AND SHADE FABRIC

The invention refers to self-supporting shading canopies, without front support beams, with a coating of photovoltaic elements on the upper array of joists, with shading fabric on the lower array of joists, in order to provide full shading and parallel reclining of the roof so that there is a greater possibility of adjusting the angle of solar incidence, with a roof self-supported by an adjustable brace or braces so that the sun's rays are not blocked from reaching the photovoltaic elements by braces.

The innovation of the solar roof covering technique, much heavier than the usual shading fabrics, consists in adding to the shading carrier one or more supports (struts) which increase the bearing capacity of my roof. Also, the innovation consists in the fact that despite the existence of the two supports, the roof has the possibility of reclining the zygoma, so that the maximum incidence of solar radiation is achieved and this is due to the special connectors that ensure the connections of the individual elements of the roof. In addition, the innovation consists in the way of placing the shading grid in order to provide complete shading coverage of the gaps of the photovoltaic elements.

The development of the base beams of the roof is done at least 2.5m from beam to beam.

In Figure 1 a typical three-post canopy is illustrated in three dimensions.

Figure 2 shows the roof plan.

Drawing 3 of the side view also shows the foundation of the system, which consists of individual footings with dimensions of at least 0.80m x 0.80m x 0.80m. The pole is sunk into the shoes and anchored, while where necessary, a bearing plate of at least 10mm thickness is placed which is anchored with an anchor or with metal plugs to the foundation, and to further ensure the anchoring, stiffness triangles are added which are welded to the bearing plate and the pole.

The vertical post, can be cylindrical, hollow or "H" type, has a single diameter cross-section, a dimension of at least 114mm and a thickness of at least 2.5mm.

The cheekbones are made of pipes with a diameter of at least 48mm and a wall thickness of at least 2mm, the cheekbones of the carrier upstream and downstream are connected via a hinged connection to the head of the post with a hub plate of at least 5mm thickness as shown in the corresponding detail drawing of the drawings issue, the hub plate connection screw and cheekbones are at least M10. (Figure 4)

The two supports of the cheekbones are pipes with a diameter of at least 48mm and a wall thickness of at least 2mm. The connections to the vertical post are achieved with a "collar" connection ring which is clamped to the post, a plate is welded to the ring onto which the struts are screwed, the thickness of the ring plate and hub plate is at least 5mm (Figure 5).

This type of connection provides the ability to adjust the height of the connection and in combination with the ability to rotate the zygomatic rods on the head of the pole as well as the possibility of shifting the zygomatic-strut connection, the optimal incidence of radiation on the photovoltaic element is achieved.

These connections are part of the innovation of construction.

The connections of strut jaws are achieved through a connection ring (collar at least 30mm wide and at least 2mm thick) which is clamped to the yoke and the strut is screwed into the hole of the collar extension (Figure 6). Alternatively, the strut can be placed on a welded plate on the yoke (cantilever pipe of the roof).

The trusses of the structure are connected to the zygomas by means of special die-cast aluminum links and zygoma clamping ring (Figure 7) or by pressed split links.

This connection has the advantage of shifting the purlin to desired positions.

The extreme horizontal elements are connected with special corner connectors type C or TAF (Figure 7). This method of connection ensures the possibility of replacing any of the connected elements in case of damage.

Transverse support pipes are placed below and are used for the installation of a shading cover which can be made of various materials, such as polyethylene netting, cloth (PVC), sheet metal, etc. (Drawing 2)

Claims (1)

Self-supporting canopy without front support beams, which allows the free movement of vehicles. The yoke is supported by struts with special connectors that allow tilting, the roof crossmembers with special cast aluminum connectors, as detailed in the technical description. The system is specially made to carry photovoltaic cells and a cloth that covers the gaps left by the photovoltaic cells providing dual benefits of shading and the possibility of exploiting green energy. The possibility of reclining the zygoma, cantilever beam, provided due to the special pieces, in order to achieve the maximum desired slope of the roof. The placement of a parallel shading mesh under the photovoltaic elements, which allows covering the shading gaps of the photovoltaic elements and the easy replacement of the shading mesh.