BR202022007941Y1 - ARRANGEMENT INTRODUCED IN A PAIR OF SHOES FOR FIXING METALLIC STRUCTURES - Google Patents

Abstract

ARRANGEMENT INTRODUCED IN A PAIR OF SHOES FOR FIXING METALLIC STRUCTURES. The present constructive arrangement refers to a model of a pair of adjustable and adaptable fixing shoes for fixing metal structures, more specifically for supporting photovoltaic plates, in solar energy generating facilities.

Description

FIELD OF CONSTRUCTIVE PROVISION

[1] This constructive arrangement refers to a model of a pair of adjustable and adaptable fixing shoes for fixing metal structures on roof structures, wooden or metal, more specifically for supporting photovoltaic plates, in energy generating facilities solar.

FUNDAMENTALS OF THE CONSTRUCTIVE PROVISION

[2] As the technical community is aware, the use of solar energy is divided into two most used means, that is, use in the form of heat or in the form of light.

[3] In the first method, the system works using a means of capturing heat by circulating a liquid from a water tank or supply network inside a solar collector and storing it in a thermal reservoir, also known as a boiler.

[4] In other words, in solar collectors, where solar energy is captured, this energy is converted into heat, heating the water present in the collectors. As soon as the water is heated, it goes back to the boiler, where it will be stored until it is consumed. As hot water is consumed, colder water is supplied to the boiler, so there is no shortage of hot water and the heating process continues. Occurring higher consumption of hot water, an auxiliary system is activated to help with the heating system.

[5] In the second medium, the photons contained in sunlight are converted into electrical energy through the use of photovoltaic solar cells.

[6] More particularly, photovoltaic power generation is performed by photovoltaic effect, in which a silicon crystal panel with N-type doping and PN junction is irradiated with sunlight to generate an electromotive force due to photovoltaic energy.

[7] For this purpose, such solar panels must be firmly fixed and positioned in sunny places and at a precisely pre-defined angle, in order to obtain the best possible use of solar incidence.

[8] Unlike existing energy sources such as fossil raw materials, sunlight is a clean energy source that does not pose the risk of global warming such as greenhouse gas emissions, noise, environmental destruction, etc. , and there is no fear of burnout. Unlike other types of wind and sea water, solar power generation facilities are free of installation and maintenance costs.

[9] However, in the case of photovoltaic panels and their structures, there is an inconvenience with regard to temperature variation cycles that occur during the day and night. This temperature variation, in addition to being one of the main causes of deterioration in the efficiency of photovoltaic generation, also causes deterioration of the mounting brackets.

[10] Corroborating these problems is the weather, such as humidity, acid rain, dust and other products from climatic phenomena, which also contribute to the deterioration of structures.

[11] In order to avoid deterioration of the support structures, or even facilitate their maintenance, the technical environment has developed the use of increasingly resistant materials and with a constructive disposition that makes it easy to uninstall and install the support structure of the solar panels, or even change components.

[12] In particular, the photovoltaic module includes a metal structure, preferably aluminum, to suppress the total weight of the structure, usually installed on roofs or on the ground. To avoid damaging the structure, in many cases shims are installed to eliminate vibration caused by the force of the wind and to compensate for expansion and retraction of the solar panels. However, such shims deteriorate over time and need to be replaced. This structure is fixed on the wooden or metallic structure, which supports the roofs.

[13] Normally, this fixation on roof structures is carried out by means of rigid footings, consisting of perforated bases crossed by screws.

[14] Despite the use of these provisions, several inconveniences are generated due to the rigidity of this fixation model, through the traction force in flexion or even shear, caused by the strong action of winds on the structures that support the photovoltaic panels.

[15] Thus, it should be noted that it is desirable for such structures to be minimally flexible, as well as versatile for easy adaptation, assembly and disassembly for maintenance, through the use of more efficient support shoes.

[16] Some constructive dispositions were developed to help the fixation of metallic structures. For example, document US2006156648 of 01.04.2006 presents a fixing kit for mounting solar panels on a roof that includes a base plate, threaded pin, anchor bolts, spacer and recess. The baseplate includes holes to accommodate anchor bolts to secure the baseplate to the roof beam. The threaded stud is attached and extends vertically from the base plate. The spacer is inserted over the pin so that it passes through an opening in the spacer, and is secured by a nut. The spacer acts as a lift to mount the board above the roof, thus allowing for drainage. The spacer includes a recess to accommodate the head of an anchor bolt. The winding is captured between the baseplate and spacer, creating a water-free environment underneath the assembled unit. The recess slides under the roof tiles to prevent water from entering the structure, and includes a flange to accommodate the baseplate, and a retainer to accommodate the screw heads underneath. Such a model has the major disadvantage of requiring the base element to be fixed to the roof beam with anchor bolts, which generates excessive operations, cost and risk of damaging the beams.

[17] Document JP2015090821 of 06.11.2013 presents a device with the objective of reliably holding a cell, allowing a cover to be locked, in a fitted state, for a connector base where a conductor for electrical connection is provided in a housing but not to be unlocked without the use of a key, i.e. the connector includes: a connector base having a housing provided with a central hole and a cell arrangement surface where a cell for electrical connection is disposed , and a conductor for electrical connection, provided in the housing, so as to be located on the cell arrangement surface; a cap, having a rod with one arm being inserted into the center hole, removable to the base of the connector, and being fitted thereto by turning while inserting the shaft with one arm into the center hole; and a unique key to unlock the connector base and cover.

[18] Document US20150249423A1 of 25.02.2015 presents a system that provides for a rail and a solar module positioned at an outer end of the array, a frame around a periphery of the solar module, a flange along an edge of the solar module which is arranged at the outer edge of the array, where the flange can project into the frame below the solar module. A clamp assembly can be disposed under the solar module and can mechanically secure the solar module to the rail, the clamp assembly can include a clamp body and a base, and the clamp body and the base can cooperate to secure the flange between the clamp body and rail.

[19] The utility model presented in document CN207348276U of 26.05.2017 provides a kind of connection element for a photovoltaic panel, where the connector includes a fastening clip and the buckle, whose fastening clip is integrated in a similar way to the Greek letter pi . The fixing clip on both sides defines the slot end to be used to install the photovoltaic panel, the fixing clip defines the fastener to be connected with the buckle, and the fixing clip defines the fastener to be connected with the buckle. It is noted as an advantage, as described, is that the permanent tooth that the connector is fixed makes the installation of the photovoltaic panel stable and firm, while supporting the fastening buckle.

[20] Document BR202020016807U2 of 18.08.2020, by the inventor himself, presents an adjustable and adaptable clamp model for fixing metal structures, more specifically for supporting photovoltaic panels, in solar energy generating installations. Its purpose is to provide a clamp for fixing a solar panel capable of withstanding phenomena caused by wind force or preventing loosening due to vibration, in addition to providing a versatile and adjustable means of fixing during installation, being easily assembled without the need to drill holes in the structure or the material to which the structure is attached, preventing damage to the structure and thus reducing labor costs. It consists of a set formed by an upper claw, formed by a rectangular body that provides a beaded or knurled lower surface, with the function of serving as a slingshot against slipping, and a central hole, while it bears an inferior-posterior narrowed intermediate lock, whose frontal projection that it touches the thread of a screw, when it crosses the hole at its lower-front end, functioning as a thread. The end of the screw enters the central hole of a cylindrical latch equipped with a guide block that, when inserted through a "U"-shaped rail with tabs and rotated under the tabs of said rail, with the bolt extended, can lock profiles or gutters under the upper jaw when the screw is tightened. The fact that the intermediate lock is narrow allows profiles or gutters to be fitted, taking advantage of the space formed below the sides of the upper claw, in a transverse and rectangular position between the gutters, or even angled. This makes it possible to correct small differences in angles, typical occurrences during the assembly of metallic structures.

[21] Document BR2020210174825Y1 of 02.09.2021, by the same inventor, refers to an adjustable and adaptable fixing clamp kit, in the form of metallic structures, for fixing and supporting photovoltaic plates, in solar energy generating installations. It consists of a fastening assembly formed by a profile, supported on the roof by a plurality of supports, and containing a plurality of pairs of fastening claws, which bear respective solar panels between them. Each support has the shape of a thin plate, equipped with an oblong hole in its front half, and a hole in its back half, which is passed through the upper end of a screw, which fixes it between two nuts. Said screw has a medium neck with a stop at the top and a self-tapping thread at the bottom end, with the function of being fixed to the roof structure. The positioning of the support can be adjusted by raising or lowering the pair of nuts. The rectangular-sinusoidal top of a screw is provided in the oblong hole, which has the function of being lifted, fitted and turned inside the profile hole, serving as a lock on the support, after tightening a nut on the screw attached to the top rectangle- sinusoidal. The fastening claw has a rectangular shape with a curved edge, and is equipped with slings on the inside, while rectangular appendages protrude from two of the edges of the curved edge, with the function of serving as a limiting stop when the edge of the fastening claw rests on the plate. solar. Said claw has a central hole through which a screw equipped with a nut is inserted, which is fitted behind the rail of the profile for fixing and tightening the fastening claw, when resting on the solar panel. The fastening claw has a front half and a back half, which fit together, the front half being in an "L" shape, latero-inferiorly containing small rectangular appendages and centrally a hole with a screw equipped with a nut, which is fitted by behind the profile rail for fixing and tightening the fixing claw, when resting on the solar panel. The vertical face of the front half has rectangular openings, parallel to each other, while the back half has a sinuous appendage, which fits inside one of the rectangular openings themselves, while the upper edge bears a joint and transverse flap with a slingshot on the edge, with the function of leaning and holding on to the solar panel.

[22] The document BR 202020016544-0 U2 of 13.08.2020 describes a device for fixing photovoltaic modules of variable thickness, comprising fixing elements provided with threads that are fixed to the bases of the roofs and that project above them for anchoring rails supporting the terminal clamps for fixing the photovoltaic modules, said terminal clamps (5) used to fix the modules at the ends and formed by an inverted “T”-shaped body provided in the center with a threaded hole through which a screw is installed together with another "L"-shaped element provided with a through hole in its upper part and at the other end, orthogonal projections that fit into a base, predominantly parallelepiped in shape and provided with grooves and a slot in its lower portion . The intermediate clamps for fixing the modules by the centers are also formed by an inverted “T”, provided with a threaded hole in the center for the passage of a threaded screw, the upper part being composed of a “T” shaped body provided with a Drilling in the center, the “T” body being provided at the bottom on both sides, with metal grounding plates, rectangular in shape and provided with projections. The utility model aims to provide a set of clamps for fixing any thickness of photovoltaic modules on roofs, allowing correction of small positioning errors that occurred during the assembly of the panels, before definitive fixation. These and other objectives are pursued with the arrangement comprising fastening elements provided with threads that are fixed to the bases of the roofs and that project above these for anchoring the support rails of the fastening clamps of the photovoltaic modules, being said terminal clamps used for fixation of the modules by the ends and formed by an inverted “T” shaped body provided in the center with a threaded hole through which a screw is installed together with another “L” shaped element provided with a through hole in its upper central part and at the other end, orthogonal projections that fit into a base, predominantly parallelepiped in shape and provided with grooves and a slot in its lower portion, which allow the assembly of modules of different thicknesses.

[23] Document US11296648B1 of 05/14/2021 teaches a solar panel racking system that can include end clamps, middle clamps, bottom clamps, L foot adapter sets, rails, and “L” foot sets. The solar panel racking system minimizes tooling by fitting many of the mounting components in place. End, middle, and bottom clamps can snap over the sides of the rail and lock into blasted top portions of the rail sides. The top portions are structured to prevent upward movement of the top braces, middle braces, and bottom braces. The L-Foot Adapter body of the L-Foot Adapter Assembly fits over the bottom retaining portions of the rail sides and secures the Gutter to an L-Foot Assembly. The end braces, middle braces, bottom braces, rails, and L-foot adapter assemblies are independent of the L-foot assemblies, allowing a selection of L-foot assemblies to be used as appropriate with the solar panel shelving system.

[24] Analyzing the documents cited above and known from the state of the art, as can be seen, none fully presents the constructive characteristics of the set of clamps for fastening, object of the present patent.

[25] Document WO2017027463 of 08.08.2016 illustrates a method and system to facilitate the quick and easy installation of structural components used in solar mounting systems. In one aspect, the system includes a retaining member configured to secure a solar panel module or other rack components to a rail. The retaining element can create a mechanical and electrical connection between components. In one aspect, the retaining member includes a retaining cap and a base member. In one aspect, the retainer cap and base member are configured to secure the solar components to the rail. In another aspect, the rail retainer member includes a connector that is configured to hold the retainer cap, base member and solar panel or similar component together.

[26] Solar mounting and structural components require proper means of bonding and grounding due to regulations. Embodiments of the present invention provide a retaining element to facilitate quick and easy installation of structural components commonly used in solar mounting systems. In one aspect, the retainer is configured to secure a solar panel module or other shelving components to a rail, forming a connection between the retainer and the rail. In another aspect, the retaining element can be used in any situation where a mechanical and electrical connection between components is desired.

[27] In one aspect, the retaining member is configured to provide a mechanical and electrical connection to various solar mounting systems. In another aspect, the retainer includes fasteners that are configured to create the electrical and mechanical connection to the various components of the solar mounting systems. In an exemplary aspect, the fasteners may include protrusions that are configured to engage conductive layers of solar mounting systems and, in some cases, penetrate non-conductive layers of solar mounting systems to create electrical connections with the conductive layers of solar mounting systems. solar mounting system. The protuberances may have a variety of structures, including, but not limited to, hemispherical, pyramidal, prismatic, ramp-shaped, or any similar structure that serves to engage conductive layers and penetrate a non-conductive layer in a rail or similar structural connection, such as feet on L, module clamps, climbers, and other component connections within a solar mounting system. In one embodiment, the fastener is of a material stronger than the conductive material of the rail, as well as any non-conductive layer.

[28] In one embodiment, the rail fastener includes two general components: a retaining cap and a base member. In one aspect, the retainer cap and base member are configured to secure the solar panel to a track, with the base member slidingly sliding an interior profile of the track and the cover configured to secure the solar panel or other solar component. , and the upper part of the gutter. In another aspect, the gutter retaining member includes a connector that is configured to secure the retaining cap, the base member, and the solar panel or similar component.

SUMMARY OF THE CONSTRUCTIVE PROVISION

[29] Based on these and other various aspects and needs of the technical environment, and seeking to apply the experience acquired in the practice of mechanics, the inventor developed the present constructive arrangement, idealizing the present " ARRANGEMENT INTRODUCED IN A PAIR OF SHOES FOR FIXING METALLIC STRUCTURES ", applicable for fixing metal structures on roof structures, made of wood or metal, more specifically for supporting photovoltaic panels, in solar energy generating installations.

[30] Another objective of the present invention is to provide a clamp for fixing a solar panel capable of withstanding phenomena caused by wind force or preventing loosening due to vibration.

[31] In addition, another objective of the present invention is to provide a versatile and adjustable fastening means during installation, being easily mounted on the structure or on the material in which the structure is fixed, avoiding damage to the structure and thus reducing labor costs. constructions. Furthermore, the present invention provides a pair of footings that can be installed easily and quickly on earth structures, on slabs.

[32] The present constructive arrangement, object of the present patent, consists of a pair of shoes formed by two elements, an upper and a lower one, the upper one being fixable to the lower end of the metallic structure, while the lower element can be fixed in the structure of roofs, made of wood or metal. The upper element is equipped with two lateral slings, which are attached to the side of the lower element by fitting. The fact that the pair of shoes is interlockable allows it to be easily connected and disconnected without the use of special tools, which facilitates assembly and maintenance if necessary.

[33] In more detail, the upper element has a rectangular base with an orifice, while two of the edges, positioned opposite each other, jointly bear "L" elevations equipped with slingshots. Said orifice is equipped inferiorly with elevation containing rectangular and radial openings, promoting a castle shape, while the lower element bears an annular recess.

[34] This feature differs the present constructive arrangement from the others, given that it works in an inverted way, with a peculiar layout, where the upper element is equipped with an elevation inferiorly containing rectangular and radial openings, promoting a castle shape, while the lower element contains an annular recess. This causes the pair to work inside the aluminum profile and has the function of locking the fixing screw, turning the lower element when the screw is inserted over and through the upper element, locking it inside. of the rail automatically. In the models available on the market, the film is located on the upper part of the part and the rotation for locking the shoe is performed manually.

[35] Thus, the present patent was designed aiming to obtain a pair of fastening shoes with the fewest possible parts, conveniently configured and arranged to allow it to perform its functions with unparalleled efficiency and versatility, without the inconveniences already mentioned.

BRIEF DESCRIPTION OF THE FIGURES

[36] Below, for a better understanding and understanding of how the "PROVISION INTRODUCED IN A PAIR OF SHOES FOR FIXING METALLIC STRUCTURES", which is claimed here, are presented the attached illustrative drawings, where you can see:

[37] FIG. 1 - Shows a top perspective view of the pair of shoes for fixing metallic structures, object of this patent.

[38] FIG. 2 - Shows a top view of the pair of metallic structure fixing shoes.

[39] FIG. 3 - Shows an exploded perspective view of the pair of steel structure fixing shoes.

[40] FIG. 4 - Shows a lower perspective view of the upper element, an integral part of the pair of metallic structure fixing shoes.

[41] FIG. 5 - Shows a bottom view of the upper element, an integral part of the pair of metallic structure fixing shoes.

[42] FIG. 6 - Shows a side view of the pair of metallic structure fixing shoes.

[43] It should be noted that these figures are merely representative, and may vary, as long as they do not deviate from what was initially required.

DETAILED DESCRIPTION OF THE CONSTRUCTIVE ARRANGEMENT

[44] According to the description above, the "DISPLAY INTRODUCED IN A PAIR OF SHOES FOR FIXING PHOTOVOLTAIC INSTALLATIONS PLATES" is a pair of shoes (1) formed by an upper element (2) and a lower element ( 3), the upper element (2) being fastenable to the lower end of metal structures supporting photovoltaic panels, while the lower element (3) can be fastened to roof structures, whether made of wood or metal.

[45] The upper element (2) has a rectangular base (4) with an orifice (5), while two of the edges, oppositely positioned, jointly bear "L" elevations (6) equipped with slingshots (7). Said orifice (5) is characterized by being equipped inferiorly with elevation (8) containing rectangular and radial openings (9), promoting castle shape, while the lower element (3) contains an annular recess (10).

[46] It can thus be seen from the foregoing that the "PROVISION INTRODUCED IN A PAIR OF METALLIC STRUCTURES FIXING SHOES" is characterized as an accessory for photovoltaic generation structures of great utility, presenting all the practical qualities and functionality that fully justify the application for a patent as a Utility Model.

[47] It will obviously be appreciated that while the above has been described by way of illustrative example, all other modifications and variations made to this constructive arrangement, as it would appear to those skilled in the art, are considered to be within the broad scope and ambit of this Model. of Utility, according to the set of claims below.

Claims (1)

[1]. "PROVISION INTRODUCED IN A PAIR OF METALLIC STRUCTURES FIXING SHOES", applicable for fixing metallic structures on roof structures, wooden or metallic, more specifically for supporting photovoltaic plates, in solar energy generating installations, being capable of withstanding phenomena caused by wind force or prevent loosening due to vibration, being versatile and adjustable during installation, being connectable and disconnectable without the use of special tools, working inside the aluminum profile by locking the fixing screw, turning the shoe and locking the same inside the rail automatically; said pair of shoes (1) is formed by an upper element (2) and a lower element (3), the upper element (2) being fastenable to the lower end of metallic structures supporting photovoltaic plates, while the lower element ( 3) it can be attached to roof structures, whether made of wood or metal; the upper element (2) has a rectangular base (4) with an orifice (5), while two of the edges, oppositely positioned, jointly bear elevations in "L" (6) equipped with slingshots (7); Said orifice (5) is characterized by being equipped inferiorly with elevation (8) containing rectangular and radial openings (9), promoting castle shape, while the lower element (3) contains an annular recess (10).