BR102022005416A2 - AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS - Google Patents

Abstract

automatic telescopic mechanism by pulley system on telescopic ball rails. provides extraction and retraction movement by force of an electric motor (5) to telescopic ball rails in parallel profiled arrangement where each rail (1,2), - considering that they are composed of three rails here designated as smaller rail (19), intermediate (18) and larger (17) -, has its smaller rail (19) linked to the larger rail (17) of another rail (1,2) forming a type of telescopic pole with more stretching input, and, all the rails ( 1,2) as a whole integrated with a system of pulleys (10a, 10b) and rope (7,8) to provide automatic telescopic guidance to flexible (f), semi-flexible (sf) and/or rigid (r) structures linked to said telescopic ball rails (1,2).

Description

Introduction

[01] The present invention patent refers to the automation and constructive arrangement of telescopic ball rails, these rails are widely used in cabinet drawers commonly called slides, here in this patent object they constitute a profiled parallel link arrangement of one in relation to the other to provide length with its rails using a pulley system for mechanical translation using rope traction under the force of an electric motor, clockwise and counterclockwise, for automatic expansion and retraction of the so-called telescopic ball rails.

Application field

[02] The present invention patent is applied to the sectors of rectilinear telescopic mechanisms for driving flexible structures (F) such as awnings and tents; semi-flexible structures (SF) such as blinds and pleated tarpaulins; and rigid (R) such as sliding gates and window panes.

Problem to be solved

[03] There are few rectilinear automatic telescopic mechanisms on the market for small to medium-sized structures with double action of automatically expanding and retracting. There is the telescopic antenna widely used in old cars but its semi-flexible guide that runs through its interior makes it difficult for the telescopic to drive in its structure something beyond its own framework, as it bends easily; There are also electric actuators that are small in size and their interior works using an endless screw connected to a motor or in the form of a piston using compressed air, but their extension capacity is short as they only have one projectable stage. Notably, there are rectilinear automated telescopic mechanisms for large structures, such as hydraulic, pneumatic winches, etc., and which have many stages, however, when it comes to application in small to medium-sized structures, their application is difficult due to the high cost involved, mainly because they depend on fluids, and other functional limitations such as heavy weight and low portability, so that many small to medium-sized devices or structures are deprived of the same benefits that these have.

Current state of the art

[04] The current state of the art anticipates a document that deals with a telescopic mechanism applied to door closers, deposit number BR1120160098463A2,.data:.31/10/2014.e.published.em.01/08/2017, entitled . Telescopic Mechanism for Opening/Closing Sliding Doors consists of a system of pulleys and belts that expand and retract for a short straight advancement of a panel, unlike the object of this patent which is a straight forward mechanism. rectilinear made up of ball rails and not a panel, which allows for greater expansion range with the addition of rails; also has a different arrangement in its system of pulleys and belts as they depend on arms and levers that generate short straight advancement. original compact size when retracted, depending on just one fixed pulley while the other pulleys move with the mechanism in which they are attached to the time that makes it move, it is reiterated, in addition to the mechanical framework belonging to another type of technology, one is a short panel that moves forward, here it is a telescopic rod using ball rails, having a much wider range of applications.

[05] This patent for the Invention of Automatic Telescopic Mechanism by Pulley System on Telescopic Ball Rails has, among other advantages, offering a better relationship between resistance and portability; when applied to horizontal sliding gates, there is no need for a significant wall gap (retreat) for their collection; when applied to telescopic windows and telescopic internal doors, there is no need to cut masonry grooves in the window sill or floor, as the sheets are linked to the mechanism itself; when applied to tents, it allows for a single point of distribution, like an umbrella, and has low production costs as the parts that make up the mechanism are widely available on the popular market.

[06] The Automatic Telescopic Mechanism by Pulley System on Telescopic Ball Rails provides extraction and retraction movement by force of an electric motor (5) to the telescopic ball rails in parallel profiled arrangement where each rail (1,2), - considering which are made up of three rails designated here as smaller rail (19), intermediate rail (18) and larger rail (17) -, its smaller rail (19) is linked to the larger rail (17) of another rail (1,2) forming a type of telescopic rod with more stretching input, and all rails (1,2) as a whole integrated with a pulley system (10a, 10b) and rope (7,8) to provide automatic telescopic guidance to flexible structures (F ), semi-flexible (SF) and/OR rigid (R) once linked to the so-called telescopic ball rails (1,2) which, due to the entire set in this report here we call mechanism (15), therefore, the workflow takes place in the following steps: - The motor (5) rotates the spool (3,4) clockwise. - The spool (3,4) applies traction force to the stretching rope (7), winding it simultaneously with the unwinding of the take-up rope (8). - The stretching rope (7) involves the extraction of the telescopic rails (2) while the retraction rope (8) promotes the controlled extraction of said rails (2). - After the rails (2) have been completely extracted to the limit, their locking is ensured by tightening the tensioning rope (7) as the motor (5) stops rotating on the spool (3,4). - Reversing the direction of the motor (5) reverses the above process, resulting in a change in traction force for the retraction rope (8) while releasing and unwinding the stretching rope (7), thus completing the retraction of the rails ( two).

[07] The Invention Patent can be better understood from the following figures: Figure 1: - Exploded and perspective view of telescopic ball rails in profiled parallel link arrangement. Figure 2: - External profiled perspective view of linked rails, under pulleys and ropes. Figure 3: - Interior profiled perspective view of linked rails, under pulleys and ropes. Figure 4: - Perspective view of the driven mechanism. Figure 5: - Flat top view of driven mechanism. Figure 6: - Top perspective view of the mechanism in a resting state. Figure 7: - Flat top view of the mechanism in a resting state. Figure 8: - Perspective view of actuated mechanisms in a flexible structure arrangement (F), such as an awning, under retractable devices. Figure 9: - Flat front view of mechanisms under actuated retractable devices. Figure 10: - Perspective view of actuated mechanisms in a flexible structure arrangement (F), such as an awning. Figure 11: - Perspective view of driven mechanisms in a rigid structure arrangement (R), such as a sliding gate. Figure 12: - Flat front view of driven mechanism in rigid structure arrangement (R), such as a sliding gate. Figure 13: - Flat front view of actuated mechanisms in a rigid structure arrangement (R), such as a sliding gate and window, alluding to application in a symbolic house. Figure 14: - Perspective view of mechanisms under satellite gear, at rest. Figure 15: - Flat top view of mechanisms under satellite gear, at rest. Figure 16: - Perspective view of activated satellite gear mechanisms, alluding to application in a symbolic vehicle. Figure 17: - Flat profile view of mechanisms under satellite gear in a resting state, alluding to application in a symbolic vehicle. Figure 18: - Flat top view of satellite gear mechanisms activated with retractable devices, alluding to application in a symbolic vehicle. Figure 19: - Perspective view of satellite gear mechanisms driven in a semi-flexible structure (SF) arrangement, in reference to application in a symbolic vehicle. Figure 20: - Flat profile view of activated satellite gear mechanisms, alluding to application in a symbolic vehicle. Figure 21: Flat top view of mechanisms under satellite gear, at rest, in reference to application in a symbolic vehicle.

[08] Considering how much the figures illustrate, it is observed that the object of the invention patent: Automatic Telescopic Mechanism by Pulley System on Telescopic Ball Rails consists of a base rail (1), rail (2), spool (3 ), spool with gear (4), electric motor (5), satellite gear (6), draw rope (7), take-up rope (8), fixing bracket (9), front pulley (10a), rear pulley (10b), pulley bracket (11), retractable display (12a), retractable wire (12b), rope fastener (13), base rail fastener (14), mechanism (15), caster (16), larger rail (17), intermediate rail (18), smaller rail (19), thin telescopic tube (20) and electronic prototyping board (21) which, due to the set and especially the arrangement of the rails (1,2) under the pulleys (10a and 10b), works on a similar principle, by analogy, to the double extendable ladder widely used by electrical utilities to climb lighting poles, which through manual stretching of a rope that starts from the ground ladder passing through a pulley located in the upper part of said floor ladder, causes the mobile ladder that is immediately linked to it to protrude longitudinally in relation to it because the other end of the rope is attached to the lower part of said mobile ladder, already here in this patent object, for analogy, it should be reiterated, instead of stairs, these are telescopic rails in arrangement overlapping parallel in profile, and, instead of a ladder fixed to the floor, a rail serves as a base, here called base rail (1), attached by base rail fasteners (14) see fig. 8,14,15,17 and 20, so that the other connected and extendable rails (2) fulfill the function represented in the extendable ladder, so that in this patent object all the other rails (2) except the base rail - held by said fasteners (14) - see fig. 8,14,15,17 and 20, are ejectable according to the tension of the rope (7) exercised here not manually as in the analogy with the ladder but by force of an electric motor (5), for this it is necessary to have the of more than one pulley here called front pulley (10a) and rear pulley (10b) through which the rope, here called stretch rope (7) passes, see fig. 1 to 3, unlike the extendable ladder which only has one pulley because there is only one stage to be extracted and collected represented on the extendable ladder, in this patent object because there is more than one rail (1,2) to be extracted, designated here of base rail (1) and rail (2), there is therefore more than one pulley (10a, 10b) present, here referred to as rear pulleys (10b) and front pulleys (10a), see fig. 4 to 7, 14, 15.

[09] The pulleys (10a, 10b) are distributed from the front part of the base rail (1) where the first front pulley (10a) is present and where the stretching rope (7) passes from the engine ( 5), follows through the rear pulley (10b) present at the rear of the first movable rail (2) immediately linked to said base rail (1), following through its front pulley (10a) to also pass through the rear pulley (10b) of the rail (2) subsequent, which will also have a pulley (10a) in its front that receives the said rope (7) passing to the pulley (10b) present in the rear part of the rail (2) that pairs it, transits the rope ( 7), continuous, on other pulleys (10a, 10b) present at equal ends of the subsequent rails (2) in the same zig-zag mentioned above between them, anchoring the said rope (7) only at the rear of the last rail (2), namely the furthest from the base rail (1), see fig. 1 to 7. Thus, the extraction of the rails (2) which occurs when the said rope (7) is stretched by the traction force of the motor (5) implies that each pulley (10b) present at the rear of the rail (2) in solidarity with the front pulleys (10a), effect the effect of mechanical translation of each rail (2) generating displacement of the rails (2) where the pulleys (10a, 10b) are attached, without matching each other, much less overtaking each other, This difference in position where the rear pulley (10b) of one rail (2) always remains behind the front pulley (10b) of the other rail (2) that is its immediate partner is what guarantees the displacement of said rails (2) and, after tightening the rope (7), the extraction of the rails (2) stabilizes, without the possibility of unauthorized return, see fig. 4,5,8,10,11 and 13.

[10] The pulley support (11) is also present, installed on the front and back of the rails (2) see fig. 1 to 4, 9, 11, as a rod that holds the rear pulley (10b), it has two perpendicular extensions that are welded to the rear border of the rail (2) see fig. 1,3 to provide a more significant distance between the approaching pairs of pulleys (10a, 10b) thus avoiding pairing and allowing sufficient traction effect of the rails (1,2) involved in the mechanical translation, although the arrangement with which a rail (1,2), that is, welded next to the rail, see fig. 2,3,5 alone could guarantee the non-pairing of the position of the pulleys (10a,10b), it is a reinforcer.

[11] It should be noted that during the winding of the stretching rope (7) to extract the rails (2) the recovery rope (8) also unwinds, as it is wound on the same spool (3 ,4) but in the opposite direction to said stretching rope (7), in short, during the extraction of the rails (2) carried out by the stretching rope (7) via pulleys (10a,10b) attached to said rails (1, 2) a double action occurs where the winding of said stretching rope (7) implies the unwinding of the retraction rope (8) see. figs 4 and 5 which, in turn, will function as a softener for the ejection onto the rails (2) exerted by the former (7), since the end of the recoil rope (8) is attached to a fastener (13) present in the rail (2) furthest from the base rail (1), see fig. 4,5,8,20, it should be noted that this so-called rail (2) furthest away, in particular, as it is the last, can do without its internal gutters (18, 19) as it is not intended to eject anything at all. follow, as can be seen in fig. 3,4,6,9,12,14, on the other hand, considering that there are also spheres mediating the intermediate rail (18) of the smaller rail (19) fig.12 and 1, and, considering that some application requires less weight than mechanism (15) as a whole, the larger rail (17) can be dispensed with without compromising the functionality and characteristics of telescopic ball rails (1,2).

[12] In short, in the extraction stage, the traction transmitted by the stretching rope (7) that passes over the rails (2) to the rail (2) furthest from the base rail (1) in the fastener (13) of its rear part, occurs in dependence and via a system of pulleys (10a, 10b), starting from the pulley (10a) fixed on the base rail (1), from which the other pulleys (10a, 10b) undergo mechanical translation effect demanding work between the pulleys (10a, 10b) jointly which, as they are attached to extensible rails (2), perform through said mechanical translation the movement of being displaced and displacing the rails (2) to which they are attached, fulfilling all extraction when the rear pulleys (10b) of each rail (2) approach the front pulleys (10a) of the rails (2) that form an immediate pair, maintaining the anterior and posterior position, respectively, until the rope (7) is completely tensioned along all rails (1,2), including the rail (2) furthest from the base rail (1), then the rotation of the electric motor (5) is interrupted, thus completing the extraction stage, see fig. 4.5.

[13] The pulleys (10a and/or 10b) are located at the ends of the rail (17,19) of each rail (1,2), with the aid of fixing supports (9) see fig. 1,2, although they can be installed in direct contact with the gutter (17,19) without compromising functionality, the usefulness of said support (9) is due to the alternative of being able to use plastic pulleys such as those on a suspended clothes line , which cannot be welded to the rail (17,19) to avoid melting, in this case, the support can be threaded where nuts secure the pulley (10a,10b) above and below that passes through the support (9).

[14] The collection stage starts with the inverted rotation of the motor, causing a double action opposite to the double action of extraction to occur, that is, the stretching rope (7) which during extraction was demanded - coiled - by the motor (5), in this stage it will be gradually released, unwinding in synchronization with the winding of the pickup rope (8) which will return to the spool (3,4) passing from fig.4 and 5 to 6 and 7, as the other end of the retraction rope (8) is attached to the fastener (13) of the furthest rail (2), resulting in the gradual retraction of the rails (2) of the telescopic mechanism as a whole (15), thus completing the retraction stage, It should be added that at this stage there is a distance between the rear pulleys (10b) and front pulleys (10a), see fig. 6,7,14 and 15. The synchronized release of the stretching rope (7) concomitantly with the pulling of the recovery rope (8) implies the control and smoothing of the return of the rails (2) in the face of the rescue pull of said recovery rope ( 8), so that the option is reserved for said ropes (7,8) to be replaced by a belt without compromising functionality.

[15] The mechanism (15) will have the option of activation and control via a) smartphone, b) thermal sensor, c) wind sensor, d) keyless system e) nfc tags, f) remote control device, for both electric motor (5) will have the option of communicating with an electronic prototyping board (21) see fig. 8 and 10.

[16] The function of the mechanism (15) as a mechanical framework for flexible (F), semi-flexible (SF) and rigid (R) structures occurs with one or more mechanisms (15) depending on the example, when for tents fig . 14,15, awnings fig. 8 and 10, vehicle shelters fig. 16 to 21, sliding gates or windows fig. 13, he will act together, either in parallel pairs as shown in fig. 8 or not as shown in fig. 15,16,20,21. Regarding the satellite gear (6), as shown in fig. 14, 15,17,18,20,21, in this specific case there will be spools with gears (4) that can be linked by belts to the motor (5) or in direct contact with said satellite gear (6) which in turn will receive direct action from the motor (5) fig. 14.15, 17.19. The satellite gear (6) can use additional gears to accelerate or reduce speed in the geared spool (4), in order to equate differences in length of the telescopic mechanisms (15) and guarantee simultaneity between them all during extraction and retraction. In cases of application to sliding gates, windows, blinds, fig. 8,11,12,13, each mechanism (15) can be exclusive to the motor (5) in indirect contact via belt, rope (7,8) or direct contact with the spool linked to the motor (5) as shown in fig. 10 to 12.

[17] The driving of flexible (F) and semi-flexible (SF) structures by the mechanism (15) will feature a system of retractable devices (12a) installed on the pulley supports (11) and/or fixing supports (9) fig . 8 and 9 and will have the end of its retractable wire (13) in connection with the pulley and fixing supports (11,9) present on the rails (1,2) of another mechanism (15) that is close to it in order to give greater scope of support for flexible (F) and semi-flexible (SF) structures during the extraction and collection of the rails (2), as well as during the extraction stage, see fig. 8 and 18, bulging of the structure (F) and (SF) fig. 10 and 19, and, during the collection stage, favors a more compact return of said structures (F) and (SF), as shown in fig. 9, although the wires (12b) extend taut, given the internal helical spring specific to this type of device (12a), as the rails (2) are extracted and return equally taut when the rails (1,2) are retracted.

[18] The position of the retractable devices (12a) on each pulley support (11) follows the difference in height that allows them to stack on top of each other without colliding when retracted, which explains the difference in height of the pulley supports (11), as shown in fig. 9. It is worth mentioning that the retractable devices (12a) as well as their wires (12b) can be replaced by thin telescopic tubes (20) such as old radio antennas, with the diameter of soda straws, for example, specifically fulfilling the function of avoid bulging caused by the wires (12b), without compromising functionality.

[19] For rigid structures (R) such as sheets for sliding gates or windows, the parallel profile arrangement with which the rails (1,2) meet see fig. welded, is decisive for the telescopic fitting of sheets, for example, as they can be linked by bands or plates along the largest rail (17) or the intermediate one (18) if the largest rail (17) is dispensed with, in a perpendicular direction, see fig. 11 and 12, in order to allow a fan effect both in the extraction fig. 11,13 e19, regarding retraction, see fig. 12. If the mechanism (15) is activated on the floor and/or depends on suspended curtain rails, the option of using casters (16) at the ends of the rails (2) is reserved, as per the non-exhaustive example in fig. 12 and 13.

Claims (15)

1 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, refers to the automation and constructive arrangement of telescopic ball rails by pulley system, consisting of a base rail (1), rail (2), spool ( 3), spool with gear (4), electric motor (5), satellite gear (6), draw rope (7), take-up rope (8), fixing bracket (9), front pulley (10a), pulley rear (10b), pulley support (11), retractable display (12a), retractable wire (12b), rope fastener (13), base rail fastener (14), mechanism (15), caster (16), rail larger (17), intermediate chute (18), smaller chute (19), thin telescopic tube (20), electronic prototyping board (21), characterized by a set of telescopic ball rails (1,2) linked in parallel in profile. entre.sí, integrated into a system of pulleys (10a, 10b) which, using a rope (7,8) coming from the electric motor (5), provide automatic telescopic extraction and retraction in flexible structures (F), semi -flexible (SF) and rigid (R). 2 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 1, characterized by the parallel connection of the telescopic ball rails (1,2) by joining the smaller track (19) of each rail (1,2) with the larger rail (17) of another rail (2), by welding or factory. 3 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claims 1 and 2, characterized by the additional option of profiled parallel connection between the rails (1,2) from internal rails to the larger rail (17), that is, making use of the intermediate rail (18) and smaller rail (19) of each rail (1,2) together with the intermediate rail (18) and smaller rail (19) of another rail (2), dispensing with so I use the larger gutter (17). 4 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 1, 2 and 3, characterized in that the rails (1,2) have pulleys (10a, 10b) installed at their ends, pulley supports (11), fixing brackets (9), fasteners (13), retractable devices (12a) and thin telescopic tubes (20). 5 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 4, characterized by the installation of pulleys (10a, 10b) distributed from a pulley (10a) on the front part of the rail base (1), and on the following rails (2): front pulleys (10a) and rear pulleys (10b) at the front and back, respectively, with the exception of the rail (2) furthest from the base rail (1) , which only has fasteners installed (9,13). 6 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 1, 4 and 5 characterized by the pulleys (10a, 10b), being crossed by a stretching rope (7) which, coming from the spool (3,4) in direct and/or indirect contact with the motor (5), its other end reaches the rail (2) furthest from the base rail (1). 7 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 6, characterized in that the rail (2) furthest from the base rail (1) has the pickup rope (8) attached to its fastener coming from the spool (3,4) in direct and/or indirect contact with motor (5). 8 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 6, characterized by the spool with gear (4) establishing indirect contact with the electric motor (5) via satellite gear (6). 9 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 8, characterized by the satellite gear (6) receiving direct contact with more than one spool (4), reserving the option of including additional gears reduction or acceleration. 10 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 4, characterized by retractable devices (12a) and/or thin telescopic tubes (20) interconnecting two or more telescopic mechanisms (15) with each other . 11 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 1, 2, 3 and 10, characterized by the connection of flexible (F), semi-flexible (SF) and rigid (R) structures be established perpendicularly and in strips along the largest (17) or intermediate (18) rail of each rail (1,2) in order to allow the fan effect. 12 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claims 1,2,3,10 and 11, characterized by the connection of the flexible (F) and semi-flexible (SF) structures being established in one piece with its extendable limit attached to the rail (2) furthest from the base rail (1). 13 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claims 1, 6, 7, characterized in that the rope (7,8) can be replaced by a belt. 14 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 1, 4, 11,12, characterized by the fasteners (13) and fixing supports (9) assist in linking the flexible structures (F ) and semi-flexible (SF) along the rails (1,2). 15 - “AUTOMATIC TELESCOPIC MECHANISM BY PULLEY SYSTEM ON TELESCOPIC BALL RAILS”, according to claim 1, characterized by the mechanism (15) having an electric motor (5) with the option of integration with an electronic prototyping board (21), and, drive and control via a) smartphone, b) thermal sensor, c) wind sensor, d) keyless system e) nfc tags, f) remote control device.