BR202021017840U2 - ARRANGEMENT INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS - Google Patents

Abstract

This is an orbital movement device (10) for sliding gap closure panels (PN) of the type provided for balconies between internal and external areas, windows, balconies, boxes and others; said orbital movement device (10) comprises a body in the form of a cubic block (11) receiving a set of sliding elements (12), for example pulleys, for displacement on tracks (S1) of housings (T1) provided in profile (F1) part of the glazing system (SV), profiles (F1) which is complemented by an upper profile (F2) and support profile (P2) of the panel (PN), said cubic block (11) of the orbital movement device (10) foresees that from the lower edge and aligned with the vertices (11a) and edges (11b) appendages (11c) of ordinarily trapezoidal shape of little thickness (e1) will develop to compose radial stabilizing platforms (PE) when sliding of all orbital movement device (10) in the tracks (S1) of the housings (T1) of the profile (F1), mainly when the orbital movement device (10) enters or leaves the outlet box (CS) of various glazing systems .

Description

ARRANGEMENT INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS TECHNICAL FIELD

[1] This utility model deals with a new arrangement introduced in an orbital movement device for sliding panels closing gaps of the type provided for balconies between internal and external areas, windows, boxes and others where, notably, said device orbital movement presents innovative constructiveness that composes functional improvements in its use, especially for foreseeing: (i) inclusion of stabilizing platforms practiced in the vertices of the multifaceted body, whose main function is to eliminate the conventional and known instability of this type of component during its movement along of the profile and, mainly, aims to prevent the handling device from bumping when passing through the output box; (ii) installation of sintered bronze bushings and stainless steel fasteners, ensuring an extended useful life of the device in question, mainly in regions with greater oxidation, such as on the coast; (iii) provision of safety elements installed on the flat upper face of the multifaceted body that receives the pulleys, which prevents the orbital device from moving when passing through the outlet box without the need for 90° displacements through additional aesthetically compromising profiles and (iv ) male and female connectors that can be attached to a pair of opposite faces of the multifaceted body of the orbital movement device for juxtaposition and elimination of gaps between other orbital devices when sliding and/or articulating the closing panels. The incorporation of the proposed improvements composes an innovative orbital movement device in the market, providing better conditions of use and durability.

HISTORY OF THE TECHNIQUE

[2] The existing gap closing systems on the market and designed for closing gaps between internal and external areas, windows, balconies, boxes and others, generally comprise a set of profiles such as a leveling profile, parking profile, bed profile of panels, upper and lower rails, outlet boxes and other elements installed at the edges of the span and which make it possible for the pulleys to slide, which, in turn, are fixed to sliding panels made of different materials, such as glass, wood, polycarbonate or other materials.

[3] The aforementioned pulleys for sliding the closing panels are conventionally composed of a set of bearings coated in nylon installed on an orthogonal pin fixed to a plate, which, in turn, is installed on the profile of the closing panel, and said bearings slide in inner tracks of the upper and lower rails of the closing system. Both the orthogonal pin and the base profile are made of metal.

[4] Said pulleys have a series of inconveniences such as, for example, the affected sliding of the closing panels in paths formed by straight and angular rails such as 45° or 90° resulting in vibrations, locking or even the derailment of the pulleys, a fact that could lead to the dismantling of the base profile panels.

[5] With these drawbacks in mind, the applicant, who is active in the area of product development for closing various spans, is the depositor of document n◦. BR 10.2019.007708-5 which deals with an orbital system for opening and closing spans through the sliding of various elements, which is comprised of a set of sliding elements that act orbiting in a multifaceted body itself to be mounted on the extreme edge of the upper profile for supporting the panel and idealized for sliding said panels on double track top rails; said sliding elements move in the vertical position to distribute the force resulting from the weight of the panels free of axial efforts on the axes of the elements; On the faces of the body, one or more fastening elements are arranged for fastening the corresponding sliding elements, which, in turn, act on double support tracks for the upper rails during straight sliding, angular sliding or rotation movement of up to 360° of the panel in said sliding system.

[6] Although this conventional model solves the inconveniences found in conventional pulley and bearing models, it is a fact that the instability of this type of cubic block or orbital system still presents the inconvenience of shaking or suffering jolts, especially when passing through the output box, a fact that until the present day, before the present technical solution represented by the sliding platforms, had not yet been solved.

[7] It is also known that in some locations in the national territory, particularly those with a high incidence of humidity and salinity, such as on the coast, or even in the urban environment whose air is loaded with a high rate of corrosive elements, it is It is common to see that in both cases, the natural effects develop corrosion in the metals of the pins, bushings and other components for installing the pulleys, especially since they are not resistant against corrosion, impairing their sliding and displacement.

[8] As an example, micro bearings are, for the most part, made of carbon steel, and their service life on the seafront, as well as in an urban environment with a high rate of corrosive elements in the air, is approximately one year, requiring maintenance and replacement of these elements with unwanted frequency.

[9] Alluded degradation of bearings and the like, caused by non-resistance to corrosion due to the corrosive elements expected in the air and/or salinity of coastal locations, also promotes the locking of pulleys/bearings mounted on the sliding panels, often locking or discontinuing the slide, which may eventually require greater effort from the user, even an abrupt movement, resulting in the derailment of the panel, putting people close to the area where the gap is closed at risk.

[10] To reduce this inconvenience, constant maintenance is necessary in order to analyze the degraded elements and replace them, reducing the risk of accidents, however, making the periodic execution of preventive maintenance costly.

[11] Other models of orbital pulleys were found in specialized databases, as seen in the topic below, however, the models found differ from the innovative orbital movement device, and one of the drawbacks of conventional orbital pulleys used in systems with movement of panels that pivot in the opening of the span, as, for example, in the balcony glazing system, consists of the need for an outlet box to allow the opening of the panels. Each panel has a specific output box and when using more than one output box, the pulleys, when passing through these openings, suffer bumps and can get stuck, being necessary to realign them on the rail to continue the movement. This inconvenience stems from the fact that said conventional pulleys do not include stabilizing elements, thus making it impossible to move the panels properly.

[12] Right now, the lack of stabilizing elements in sets of conventional pulleys associated with the constructive characteristics of the piece, which notably present a certain level of natural instability, intensify any trepidations and instabilities, generating not only noise and discomfort for the user when movement of the closing panels, as well as bringing insecurity when moving the panels, especially when they pass through the exit box, whether for opening or closing the balcony or equivalent.

[13] It is also widely known that conventional orbital blocks, when moved to open the spans, do not park uniformly, generating varied spacing between the devices and, consequently, between the panels, causing an unpleasant look.

ANALYSIS OF THE STATE OF THE TECHNIQUE

[14] One of the documents found from n◦. EP3175069 (METALGLAS BONOMI) deals with a hinge device for a mobile panel system with sliding guides comprising gripping means comprising a transport body for supporting and locking the panel configured by a guide portion suitable to be accommodated in the guide and to allow device sliding; a panel portion attachable to the panel wherein the panel portion is rotatable with respect to the guide allowing rotation of the panel; gripping means suitable for operating during rotation of the panel with respect to the guide comprising a panel gripping group comprising an engaging member and a guide member suitable for engaging each other by threading together, in a rotated configuration of the panel with respect eagle.

[15] Another document of n◦. EP3260640 (METALGLAS BONOMI) presents a movable panel system comprising an upper guide and at least one panel operatively connected to the upper guide to slide axially and rotate vertically relative thereto. The movable panel system comprises suitable sliding, support and gripping means to allow the axial sliding and rotation of the panel with respect to the guide, comprising a pair of devices composed of a first carriage device, which supports the panel in sliding and in rotation and a second trolley device that supports it in sliding.

[16] The aforementioned devices, despite understanding the orbital concept of the pulley, that is, a quadrilateral body receiving a set of bearings, differ from the orbital movement device in question, as will be seen below, especially because they do not have stabilizing platforms, safety elements and sintered bronze bushings that make up several functional improvements to the existing orbital concept on the market.

[17] Thus, it is a fact that the documents cited in the paragraphs above, despite belonging to the same field of application, do not present any of the characteristics of the object now perfected, thus guaranteeing that it meets the legal requirements of patentability.

FUNCTIONAL IMPROVEMENTS

[18] One of the functional improvements of the orbital movement device consists in the fact that the cubic block foresees stabilizing platforms incorporated to the lower base of the cubic block, more precisely projecting from the lower vertices of said block that act, mainly, as elements that eliminate the instability of the device during its movement along the profile and, mainly, it aims to avoid that the device suffers jolts when passing through the output box.

[19] Another functional improvement is related to the fact that all assembly bushings are made of sintered bronze, produced by mixing various elements in powder form - copper, zinc, tungsten, graphite and others - which, when sintered, allow for porosity between them. , which is filled with oil in a vacuum chamber promoting self-lubrication when requested through movement, releasing graphite that is contained in the alloy that makes up the bushing and oil contained in the microporosity and the fastening elements such as screws and pins are made in stainless steel.

[20] The cylindrical elements installed on the flat top face of the cubic block feature a specially developed configuration to, together, compose guides for safe sliding on the embossed tracks used on the internal sides of the glazing profile, providing better conditions of use, especially with in terms of stability during the displacement of said glass panels or other material, including greater durability in relation to other devices on the market.

[21] Another functional improvement practiced in the present orbital movement device, optional in relation to the cubic block, consists in the fact that said block can foresee that, in two of its lateral opposite faces, corresponding connectors with male and female fitting are fixed , respectively, whose quick and flexible coupling allows the coupling of a second orbital movement device with precision of the distance between the panels and the stability of the set when the panels are open, reducing gaps between orbital devices installed in closing panels.

[22] Alternatively, the male and female connectors can also be molded in the cubic block itself, composing a single piece, whose lateral opposite faces now incorporate male and female couplings, eliminating fixation by means of screws,

OBTAINED ADVANTAGES

[23] Therefore, the main advantage of the present patent consists in the fact that the stabilizing platforms incorporated in the cubic block of the orbital movement device solve a stability problem already known in the state of the art, preventing the orbital movement device from suffering jolts when passing through the outbox.

[24] Another advantage lies in the fact that sintered bronze bushings substantially increase the durability and longevity of the bushings, since the wear that occurs due to the low rotation that said bushings are subjected to due to the small movement course is almost negligible. of a panel. Through the use of sintered bushings, the orbital movement device guarantees a useful life of more than fifty years, according to tests submitted in a laboratory approved by ABNT.

[25] Another advantage is related to the cylindrical elements on the flat upper face of the cubic block, which prevent the orbital device from moving when passing through the output box without the need for 90-degree displacements through additional profiles that are aesthetically compromising the environment where the gap closing panels are installed.

[26] Another advantage is related to the provision of male and female quick and flexible coupling connectors, each coupled or integrated to two opposite faces of the cubic block, whose main function is to standardize and stabilize the spacing between the orbital devices and , consequently, stabilize glass panels or other material when opening or closing.

DESCRIPTION OF FIGURES

[27] To complement the present description in order to obtain a better understanding of the characteristics of the utility model and in accordance with a preferential practical implementation of the same, accompanies the description, in annex, a set of drawings, where, in an exemplified way, although not limiting, the following was represented:

[28] figure IA represents an exploded perspective view of the elements that make up the orbital movement device for sliding panels closing the spans in question;

[29] figure 1B represents an enlarged detail Ά' of the cubic block presented in perspective;

[30] figure 1C illustrates the enlarged detail illustrated in the previous figure shown in lower perspective;

[31] Figure 2 shows an assembled perspective view of the orbital movement device;

[32] Figure 3 shows a top view of the mounted orbital movement device;

[33] figure 4 represents a side view of the mounted orbital movement device;

[34] figure 5A shows a longitudinal sectional view A.A indicated in figure 3;

[35] figure 5B shows a view in diagonal section B.B indicated in figure 3;

[36] figures 6A and 6B represent views in perspective of the orbital movement device installed in the closing panels and displacement profiles;

[37] figure 7 shows a longitudinal section view C.C indicated in the previous figure of the assembly of the orbital movement device in the displacement profiles;

[38] figure 8A shows a perspective view of the device with male and female connectors exploded in relation to the installation faces of the multifaceted body;

[39] Figures 8B represent a perspective view of the drive device with male and female plug-in connectors mounted on the corresponding faces;

[40] figure 8C shows a view in longitudinal section of the drive device with fitted male and female plug-in connectors;

[41] Figures 8D and 8E show top views of the movement device with the respective connectors installed in the closing panels;

[42] figures 8F and 8G show enlarged details 'B' and 'C shown in figures 8D and 8E, showing in detail the fitting behavior performed between orbital devices with mounted connectors in order to standardize spacing;

[43] figure 8H illustrates a longitudinal section of the devices connected by means of the connectors, illustrating the mode of coupling between the parts;

[44] figure 9A shows a perspective view of a variation of the drive device with connectors incorporated into the multifaceted body; It is

[45] Figure 9B shows a longitudinal sectional view showing the device with built-in connector.

DETAILED DESCRIPTION OF THE OBJECT

[46] With references to the illustrated drawings, this utility model refers to a "DISPLAY INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS", more precisely, it is an orbital movement device (10) for sliding of gap closing panels (PN) of the type foreseen in balconies between internal and external areas, windows, balconies, boxes and others. Said orbital movement device (10) comprises a body in the form of a cubic block (11) receiving a set of sliding elements (12), for example pulleys, for displacement on tracks (S1) of housings (T1) (see Figure 7) provided in a profile (F1) that is part of the glazing system (SV) (Figs. 6A and 6B), profiles (F1) which are complemented by an upper profile (F2) and a support profile (P2) of the panel (PN) .

[47] According to this utility model, said cubic block (11) of the orbital movement device (10) provides that from the lower edge and aligned with the vertices (11a) and edges (11b) appendages (11c) of ordinarily trapezoidal shape of little thickness (e1) composing radial stabilizing platforms (PE) when the entire orbital movement device (10) slides on the tracks (S1) of the housings (T1) of the profile (F1), mainly when the movement device orbital (10) enters or leaves the output box (CS) (See Figs. 6A and 6B), avoiding vibrations or jolts.

[48] The lower flat base (11') of the cubic block (11) has a central recess (r1) equipped with a through hole (o1) for passing through the central pin (PC).

[49] On the upper face (11d) of said cubic block (11) develops a set of four tubular projections (11e) organized and equidistant, each able to accommodate a cylindrical element (20), in turn, each formed by a hollow tubular piece (21) (21a), whose internal diameter is designed to accommodate the respective tubular projection (11e) (see Fig. 5B) and also provides, on its external face, a waistband (21b) and lower cylindrical skirt (21c ). Said belting (21b) is dedicated to sliding on protruding rails (J1) (Fig. 7) provided on the inner faces of the parallel side walls (L1) of the profile (F1). The lower base of each tubular part (21) provides a short support shoe (21d) (see figure 5A) on the flat face (11d) of the cubic block (11). The cylindrical elements (20) are fixed to said tubular projections (11e) by means of screws (30).

[50] The cylindrical elements (20) (see Detail of Fig. 6), in addition to allowing better sliding performance in relation to the profile (F1), act as stabilizers of the orbital movement device (10) when passing through the box of output (CS) of the span glazing system.

[51] Each flat face of the cubic block (11) of the orbital movement device (10) provides a threaded hole (11g) for mounting screws (40) made of stainless steel that fix pulleys (12) made of polyacetal together with bushings ( 50) made of self-lubricating sintered bronze, configuring total resistance of the device (10) to corrosion.

[52] Cited cubic block (11) (see figures 8A to 8E) of the orbital movement device (10), in a constructive option, can receive quick and flexible coupling connectors (60), of the male (61) and female type ( 62) for standardization of spacing (EP) between said devices (10), each male connector (61) and female (62) being fixed on two opposite faces (Fc1) and (Fc2) of the cubic block (11) and fixed by screws (40).

[53] Preferably, the male connector (61) is comprised of a rectangular base (61a), whose face (61a') develops, near the upper ends (61b) and from the edges (61c) a pair of projections (61d ) and with a 'U' cross-section that form arms with trapezoidal elevations (61d'), practiced close to the free ends of each arm of the projections (61d) to couple the respective one in the female connector (62). Between the projections (61d) a circular step (61e) is projected with a central hole (61f) for passing through the screw (40).

[54] The female connector (62), in turn, has a rectangular base (62a) whose lower vertices have a cutout (62a') that form rotated 'L' shaped steps that cause the transposition of the radial stabilizer platforms (PE) to accommodate the connector (62) on the wall (Fc2), and the opposite end of the female connector (62) develops a pair of bumps (62b) of 'U' cross-section that form arms with trapezoidal elevations (62b') practiced on the internal face of the same to couple the respective one in the male connector (61). Said shoulders (62b) are adjacent to a bulge (62c') developed from the flat base (62c) forming a resting channel for the trapezoidal elevations (61d') of the male part (61) when coupled. Below the projections (62b) there is a circular step (62d) and centralized, with a central hole (62d') for passing through the fastening screw (40).

[55] When opening the orbital movement devices (10) and (10'), it is possible to check the coupling between the quick coupling connectors (60), male (61) and female (62) of two devices (10) adjacent ones, achieving not only the stabilization of the system, but also the standardization of the spaces (EP) between the panels (PN).

[56] In a second constructive and optional variation, the orbital movement device (10'') (figures 9A and 9B) provides that the quick and flexible coupling connectors (60), in male and female form, are integrated into the cubic block (11") composing a single piece, so that the face (Fel") develops the projections (61d"), while the face (Fc2") develops the projection (62b").

[57] The device brings significant advantages in relation to state-of-the-art documents, fitting perfectly into the criteria that define the utility model, that is, it performs the combination and modification of already known elements, bringing a new form or disposition, resulting in functional improvement in its use or manufacture.

[58] The preferred embodiment of the present utility model has been described, and any modifications and/or changes must be understood as within the scope of the presented utility model.

Claims (6)

"DISPLAY INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS", more precisely, it is an orbital movement device (10) for sliding span closing panels (PN) of the type foreseen in balconies between internal areas and external, windows, balconies, boxes and others; said orbital movement device (10) comprises a body in the form of a cubic block (11) receiving a set of sliding elements (12), for example pulleys, for displacement on tracks (S1) of housings (T1) provided in profile (F1) part of the glazing system (SV), profiles (F1) which is complemented by an upper profile (F2) and support profile (P2) of the panel (PN). characterized by a cubic block (11) of the orbital movement device (10) foreseeing that from the lower edge and aligned with the vertices (11a) and edges (11b) appendages (11c) of ordinarily trapezoidal shape of little thickness (e1) develop ) to compose radial stabilizing platforms (PE) when the entire orbital movement device (10) slides on the tracks (S1) of the housings (T1) of the profile (F1), mainly when the orbital movement device (10) enters or leaves outbox (CS); the lower flat base (11') of the cubic block (11) has a central recess (r1) provided with a through hole (o1) for passing through the central pin (PC); on the upper face (lld) of said cubic block (11) develops a set of four tubular projections (lie) organized and equidistant, each capable of accommodating a cylindrical element (20), in turn, each formed by a tubular piece (21) hollow (21a), whose internal diameter is designed to accommodate the respective tubular projection (lie) and also provides, on its external face, a belt (21b) and lower cylindrical skirt (21c); said belting (21b) is dedicated to sliding on protruding rails (J1) provided on the inner faces of the parallel side walls (L1) of the profile (F1); the lower base of each tubular part (21) provides a short support shoe (21d) on the flat face (11d) of the cubic block (11); the cylindrical elements (20) are fixed to said tubular projections (11e) by means of screws (30) and act as stabilizers of the orbital movement device (10) when passing through the output box (CS) of the span glazing system "DISPLAY INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS", according to claim 1, characterized in that each flat face of the cubic block (11) of the orbital movement device (10) provides a threaded hole (11g) for assembling screws (40) made of stainless steel that will fix pulleys (12) made of polyacetal together with bushings (50) made of self-lubricating sintered bronze configures device resistance (10). "DISPLAY INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS", according to claims 1 and 2, and in a constructive option characterized by a cubic block (11) of the orbital movement device (10), receiving connectors of quick and flexible coupling (60), male (61) and female (62) for standardization of spacing (EP) between said devices (10), each male (61) and female (62) connector being fixed on two faces opposite sides (Fe1) and (Fc2) of the cubic block (11) and fixed by screws (40). "DISPLAY INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS", according to claims 1, 2 and 3 characterized in that the male connector (61) of the quick and flexible coupling connectors (60) is comprised of a base rectangular (61a), whose face (61a') develops, close to the upper ends (61b) and from the edges (61c) a pair of bumps (61d) and cross-section in 'U' that form arms with trapezoidal elevations ( 61d') practiced near the free ends of each rebound (61d). "DISPLAY INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS", according to claims 1, 2 and 3 characterized in that the female connector (62) of the quick and flexible coupling connectors (60) is comprised of a rectangular base (62a) whose lower vertices have a cutout (62a') that form rotated 'L' shaped steps that cause the radial stabilizer platforms (PE) to pass through to accommodate the connector (62) on the wall (Fc2), and the opposite end of the female connector (62) develops a pair of bumps (62b) of 'U' cross-section that form arms with trapezoidal elevations (62b') practiced on their inner face to couple the respective to the male connector (61); said projections (62b) are adjacent to a bulge (62c') developed from the flat base (62c) forming a resting channel for the trapezoidal elevations (61d') of the male part (61) of a second device (10'); below the projections (62b) there is a circular step (62d) and centralized, with a central hole (62d') for passing through the fastening screw (40). "DISPLAY INTRODUCED IN ORBITAL MOVEMENT DEVICE FOR SLIDING SPAN CLOSING PANELS", according to claims 1 and 2 and in a second constructive and optional variation, characterized by an orbital movement device (10'') foreseeing that the connectors of quick and flexible coupling (60), in male and female form, are integrated into the cubic block (11") as a single piece, so that the face (Fe1") develops the projections (61d"), while the face (Fc2) ") develops the overhang (62b").

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