FR2951148A1 - HUNTING FOOT FOR ELEVATOR AND ITS DEPLOYMENT METHOD - Google Patents

Abstract

A method of deploying an elevator foot flap comprising sliding telescopic panels (8, 9, 14) including a proximal panel (8) and a distal panel (9), the proximal panel (8) being pivotally attached under a shower cabin elevator and being integrally provided with a compass (1) limiting the pivoting so that the telescopic panels are approximately vertical when the compass (1) is deployed, the distal panel (9) in the deployed position being away from the elevator car , and the panels (8, 9, 14) being initially placed approximately parallel to the floor of the elevator car and locked in this position, in which - the panels (8, 9, 14) are unlocked, which causes them to pivot to a vertical position and the opening of the compass (1), - the compass (1) being provided with a multifunctional part (2) provided towards the distal end of the compass (1), comprising two projections, one of folding (5) and the other locking (6) directed s to the inside of the plates, the locking projection (6) initially blocking the deployment of the distal panel (9), - the opening of the compass (1) producing the rotation of the multifunctional part (2) and the projection of blocking (6) and consequently the unlocking of an element of the distal panel (9), thus allowing the vertical expansion of said distal panel (9) and consequently of the optional intermediate panel (s) (14), and in which the distal panel (9) drives down the optional intermediate panel (14), lift feet and compass for their implementation.

Description

Elevator foot fighter and its deployment method

The present invention relates to a method of deploying an elevator foot fighter, a hunt feet, a compass for their implementation and its applications. The construction and installation of lifts for existing buildings is subject to safety regulations. The French standard XP / P / 82-511 and 611 of April 1999 imposes the presence of a protective device of at least 750 mm height installed under the elevator car in order to prevent access to the space located directly below said cabin. This device comprising at least one panel the width of a landing door and protecting the above height is called hunt feet. It protects the feet of users when the cabin does not stop exactly at a level. If the offset is important, this device protects from a fall in the elevator shaft. If the installation of such devices is relatively easy in the new facilities, since it is sufficient to design a bottom of elevator shaft deep enough, the renovation creates problems, especially in the case of shallow elevator shaft funds . Indeed, in existing buildings, the bottom of the cage is often insufficient to contain the entire height of the protective device when the elevator car is in the lowest level. It would therefore be desirable to have a hunt feet comprising several telescopic panels or even better, also retractable. Such a hunt should be able to deploy in the active position, preferably slowly to avoid shocks, to be able to lock in the active position and resist a radial thrust (perpendicular to the direction of movement of the elevator.) But after long unsatisfactory searches , the Applicant has developed a method of deployment of a protective device and a protective device satisfactory, based on a hinge compass provided with a multifunctional piece of original design.The problems encountered were in particular as follows : - imagine a simple, safe and effective procedure for both opening and closing a foot guard and to this end imagine a tilting step 5 and an original device, - limit the speed of opening tilt, given the weight of parts, - retain panels when tilting - allow deployment of panels at the end of tilting 10 - lock r the compasses (or struts) when folding the assembly. Therefore, the present application is directed to a method of deploying a foot flush comprising two, three or four sliding telescopic panels including a proximal panel and a distal panel, the proximal panel being pivotally attached under an elevator car. and being integrally provided with a pivot-limiting compass so that the sliding telescopic panels are approximately vertical when the compass is deployed, the distal panel in the extended position being remote from the elevator car, and the panels being initially placed approximately parallel to the floor of the elevator car and locked in this position, in which - the panels are unlocked, which causes their pivoting to a vertical position and the opening of the compass, - the compass being provided with a multifunctional part provided to the distal end of the compass, said multifunctional part comprising two projections 25 directed towards the inside plates, one of folding and one of locking, the locking projection initially blocking the deployment of the distal panel, the projections being preferably longitudinally offset relative to each other vis-à-vis the compass, - the opening of the compass producing the rotation of the multifunctional part 30 and the blocking projection and consequently the unlocking of an element of the distal panel, thereby allowing the vertical expansion of said distal panel and consequently of the one or more optional intermediate panels, and in that the distal panel drives down the optional intermediate panel (s).

The projections may be longitudinally superimposed but they are preferably offset relative to each other vis-à-vis the length of the compass So one can be described as "distal" and the other "proximal" . A hunt feet implemented in the invention comprises two, three or four but preferably two or three, particularly three sliding telescopic panels. A higher number of sliding telescopic panels is technically possible but weighs down and unnecessarily complicates the hunt of the invention. The unfolded height of the panels may range from 1.5 to 0.3, preferably from 1.0 to 0.4, especially from 0.8 to 0.4, most preferably from 0.75 to 0.55 meters. The height of each panel may range from 0.75 to 0.10, preferably from 0.60 to 0.15, in particular from 0.4 to 0.25, more particularly from 0.30 to 0.25 meter. The proximal panel is pivotally attached under an elevator car. It can be directly attached to it, but under preferential conditions of implementation of the invention, the proximal panel is indirectly fixed to the cabin by a formwork which is itself fixed to the cabin. The pivot axis of the proximal panel is preferably provided approximately parallel to the floor of the elevator car. The proximal side of the compass is pivotally attached to the elevator casing or car and distal side preferably near the distal side of the proximal panel. The panels are initially placed approximately parallel to the floor of the elevator car and locked in this position. By "approximately parallel" is meant here that the panels form an angle ranging from 30 ° to + 30 °, advantageously from 20 ° to + 20 °, preferably from 10 ° to + 10 °, in particular are horizontal. Under preferred conditions of implementation of the method described above, the distal panel or an intermediate panel presses on the locking projection of the compass to lock it in the open position.

The present application also relates to a method of folding a flush above feet, especially after deployment as above, characterized in that - it causes the rise of the distal panel - a portion of the distal panel then pressing the folding projection of the multifunctional part which causes its pivoting and consequently the release of the compass, which allows the vertical pivoting of the panels - the locking projection of the multifunctional pivoting part 10 also and blocking the distal panel in the folded position . the panels are pivoted to fold them in approximately horizontal position. Under preferred conditions of implementation of the method described above, the raising of the distal panel causes the rise of the optional intermediate panel (s). The present application also relates, in particular to the implementation of the method described above, a flush comprising two, three or four sliding telescopic panels including a proximal panel and a distal panel, the proximal panel being in the deployed position the which is the closest to the elevator landing and being provided to pivot under an elevator car and also being integrally provided with a compass limiting the pivoting of the sliding telescopic panels so that said sliding telescopic panels are approximately vertical in the deployed position, the distal panel being in the deployed position the one furthest from the elevator landing, and the panels being initially placed approximately parallel to the floor of the elevator car and locked in this position, characterized in that the compass is provided with a multifunctional part integrally provided towards the distal end of the compass, said part The multifunctional projection comprises two projections directed towards the inside of the plates, the projections being preferably longitudinally offset from the compass, the distal panel comprising a member cooperating with the locking projection blocking the distal panel before deployment and after folding. when the distal panel comes into abutment, the distal panel also comprising a tongue forming a stop cooperating with the folding projection of the multifunctional part to push it at the end of folding stroke of said distal panel and cause the release of the compass and its beginning of closure . The sliding telescopic panels are advantageously mounted on slides.

Under preferential conditions of implementation of the invention, the hoof feet above further comprises a traction cable attached to the distal panel to fold the entire device, accessible from the bearing. The traction cable is advantageously stored in an automatic winder, for example a spring, fixed to the distal panel.

In still other preferred conditions of implementation of the invention, the hunt feet above also contains a damper installed between the distal panel and the proximal panel, preferably two dampers, when the flush includes only a distal panel and a proximal panel. A damper brakes the descent of the telescopic panel or panels other than the proximal panel which is fixed in translation. An above-mentioned foot flush comprising an intermediate panel advantageously encloses two dampers installed between the proximal panel and the intermediate panel and a single damper installed between the intermediate panel and the distal panel.

Preferably, the shock absorber (s) installed between the proximal panel and the distal panel work in thrust. In the presence of an intermediate panel, or dampers installed between the proximal panel and the intermediate panel advantageously work in thrust. The shock absorber (s) installed between the distal panel and the intermediate panel work in thrust or restraint, advantageously the latter. In still other preferred conditions of implementation of the invention, the device further comprises a jack, preferably two cylinders, to slow the tilting of the panels down during opening. These are preferably installed between a portion, preferably distal, of the proximal panel and a direct or indirect attachment point (formwork for example) on an elevator car. In still other preferred conditions of implementation of the invention, the hunt feet above is installed in a formwork. Thus, one can directly install the formwork with the hunt feet under a cabin of elevator. In a limited number of operations. The compass being a hinge compass, each of its ends is mounted on a pivot, the distal side to a proximal panel, the distal side to an elevator car or preferably to a storage form of the device. The pivot can unfold to determine the maximum opening of the panels, and fold for storage panels horizontally. In still other preferred conditions of implementation of the invention, a set of stops provided on the panels determines extreme positions of deployment and folding hunt feet of the invention. A preferred flush of the invention comprises a damper cooperating with a traction sling integral with the proximal panel to slow down the tilting opening of the sliding telescopic panels. Another preferred flush of the invention comprises a locking system in the folded position associated with an electrical contact signaling said folded position. In still other preferred conditions of implementation of the invention, a hunt feet of the invention comprises an articulated arm associated with one or more contacts signaling the extended position of said hunt feet, said hinged arm being on one side solidarity of the proximal panel and the other of the distal panel. The parts working the hardest hunt feet of the invention are advantageously made of steel. Some parts working hard for lightening purposes can also be made of aluminum or aluminum alloy such as panels, including distal or intermediate (s) optional (s). Note that in the present application, conventionally the indefinite article "a" must be considered as a generic plural (meaning "at least one" or "one or more"), except when the context shows the opposite (1 or "only one"). Thus, for example, when it is said above that a compass is provided, it is one or more compasses including two compasses, one on the left, the other on the right of the hunt feet.

It will be appreciated by those skilled in the art that the particular compass described above is an important part of the method and device and has been designed for their implementation. It allows the following functions starting from the position where the panels are stored: - folded or partially folded position of the compass: blocking the translation of the distal panel thanks to the locking projection of the multifunctional part by blocking a nipple of said panel distal, - open position of the compass: release of the translation of the distal panel by disengagement of the nipple from said distal panel, - open position of the compass: determination of the maximum open position of the panels and blocking of the panels in this position, - open position of the compass: blocking the descent of an intermediate panel and blocking the panels in this position by keeping the compass in the open position by pressing on the folding projection of the multifunctional part, - up or down position of the compass: unlocking and closing the compass by pressing the tongues forming a stop provided laterally on the distal side distal panel, 20 - folded or partially folded position of the compass: locking before closing the translation of the distal panel through the locking projection of the multifunctional part by preventing a nipple of said distal panel. This is why the present application finally relates to a compass comprising two branches and two ends, comprising integrally at one of its ends a multifunctional part installed on the inner side of the compass, said part comprising two projections advantageously arranged consecutively. in the longitudinal direction of the compass, the ends of the compass being arranged to pivot. The ends of the compass are advantageously bored in accordance with the pivot of its two branches. The length of each leg of the compass may range from 0.7 to 0.1, preferably from 0.5 to 0.15, in particular from 0.4 to 0.15, more particularly from 0.3 to 0.2. metre. The compass and protrusions must have a resistance adapted to their use. The branches of the compass are advantageously made of steel as the projections. A projection will advantageously be a nipple for example crimped, of diameter about 2 to 0.5 cm, particularly 1.5 to 0.5 cm and most preferably about 1 cm. Its length (dimension transverse to the length of the compass) will advantageously be from 0.5 to 5, preferably from 0.5 to 4, in particular from 1 to 3, particularly from 1.5 to 2.5 cm, and most particularly about 2 cm The devices object of the present invention have very interesting qualities. They allow in particular to be used for shallow lift bowls. They can only deploy in a semi-vertical position and have an automatic strut lock (compass). They have great resistance to radial force and the struts fold back automatically when folding the set. Deployment can be amortized. These qualities are illustrated below in the experimental part. They justify the use of hunt feet described above, in the protection of people during malfunctions or repairs of lifts.

This is why the present application finally relates to a method of protection in which a device above is installed under an elevator car. The devices described above also find their application in so-called "space saving" furniture retractable or collapsible. For example they can be used to deploy and store a projection screen, a telescopic ladder or a retractable staircase. The preferred conditions of implementation of the methods described above also apply to the other objects of the invention referred to above, in particular to hunt feet of the invention and vice versa.

The invention will be better understood with reference to the accompanying drawings in which - Figure 1 shows a perspective view of the distal end of a compass with a multifunctional part of the invention from the outside. FIG. 2 shows a perspective view of the distal end of a compass with a multifunctional part of the invention from the inside. - Figure 3 shows a side view of a flush comprising three telescopic sliding panels in unfolded position and a formwork, in a position between the unlocking and the arrival in approximately vertical position of the panels. FIG. 4 shows a perspective view similar to FIG. 3; FIG. 5 shows a perspective view analogous to FIGS. 3 and 4, the telescopic panels having arrived in almost the upward position, the compass being then fully open and ready to unlock. 6 shows a perspective view similar to FIGS. 3, 4 and 5, the telescopic panels being deployed in approximately vertical position; FIG. 7 shows a side view of a hoof 20 folded into a formwork.

In the following description, the mounting is experimental and various modes or embodiments are possible. For example, the multifunctional part is fixed by welding on a compass but can be made in one piece with the distal arm of the compass. In Figure 1, there is the distal end of a compass 1 of U cross section, on which is fixed by welding a multifunctional part 2 of the invention. The compass 1 being a hinge compass, each of its ends is mounted on a pivot, distally to a proximal panel 8, distally to an elevator car or as shown here, to a storage form 7. of the device. The multifunctional part 2 seen from the side is a plate 3 L-shaped, installed on the side of the closure of the compass. It comprises an elongate longitudinal fold 4 provided approximately parallel to the length of the arm of the compass 1. It comprises two projections 5 (hidden in this figure) and 6 directed towards the inside of the device. There is a distal protrusion called distal protrusion due to its distal projection position which is a steel crimped nipple about 1 cm in diameter and about 2 cm in length and a locking protrusion 6 also referred to as a proximal projection due to its position, which is itself a transverse bend of the plate 3 to provide a recess. In Figure 2, there are the same elements, as well as the folding projection which is a stud 5. In Figure 3, there is the formwork 7 approximately parallelepiped in which are folded at the origin panels. Unlocking the panels intervened, which caused their pivoting to the vertical (see arrow) and the partial opening of the compass 1 whose two branches are not yet aligned. There is a side of the proximal panel 8 and a small distal portion of the distal panel 9. The distal panel 9 is provided with a protruding section 10 installed parallel to the sides of the panels and provided with a nipple 11 transverse. Originally when the panels are folded into the formwork, the locking projection 6 in cooperation with the transverse stud 11 blocks the relative translation movements of the panels. In the position shown, the opening of the formwork caused the counterclockwise rotation (clockwise seen from the opposite side) of the panels and consequently the counterclockwise rotation (clockwise seen from the opposite side) of the distal arm of the compass 1 relative to its distal axis. rotation materialized by a pivot 12, and thereby the multifunctional part 2 of the invention gradually leaving the passage down to the transverse nipple 11 and thus to the distal panel 9. There is also a protruding lug provided laterally on the distal panel 9 and whose function will be explained later. Figure 4 shows a perspective view similar to Figure 3, during closing. We first observe the general symmetry of all the structural elements. The protuberant lugs 13 are then seen in a profiled corner installed laterally and distally on the distal panel 9. During closure, the protruding lugs 13 slidably push the nipple 5 of the multifunctional part 2 of the invention, causing its pivoting and consequently, that of the distal arm of the compass 1 with respect to its distal axis of rotation 12 and thus the beginning of the closing of the compass, thus allowing the panels to be pivoted for their storage in the formwork 7. FIG. lift before folding but can also illustrate the continuation of the full opening of the device (and its closure as shown below). The total opening of the compass 1 whose two branches are aligned has been reached. The transverse nipples 11 of the distal panel 9 are no longer blocked by the locking projections 6 of the multifunctional parts 2, the distal panel 9 can be driven by its weight and cause with it the intermediate panel not visible in this figure.

Figure 6 illustrates the continued full opening of the device. The distal panel 9 has been driven by its weight and has carried with it the intermediate panel 14. The descent of the panels has been slowed by a set of dampers 20, 21 provided between the proximal panel 8 and the intermediate panel 14 and between the intermediate panel 14 and the distal panel 9.

The intermediate panel 14 is laterally provided with L-shaped angles 15 which abut on the stud 5 of the multifunctional part 2 to limit the downward translation of the intermediate panel 14 and lock the compass. Likewise, a system of abutments limits the translation downward of the distal panel 9 with respect to the intermediate panel 14.

Figure 6 also illustrates the closure of the device. The traction, relayed by pulley, on an unrepresented cable connected to the formwork, produces the rise of the distal panel 9 whose proximal side abuts a distal fold 17 of the intermediate panel 14, to which three dampers 20, 21 are attached. Continuing traction also produces the ascent of the intermediate panel 14. The traction still continuing, as also illustrated in FIG. 5 and then in FIG. 4, tongues 13 forming a stop, provided laterally on the distal side of the distal panel 9, press on the nipples 5 of the multifunctional parts 2, causing the pivoting of the distal branches of the compasses 1 and the release of the compasses 1 and the beginning of folding of the compasses 1. With traction still continuing, the panels leave their vertical position. As the traction continues, as also illustrated in FIG. 3, the locking protrusions 6, driven by the pivoting of the multifunctional pieces 2 (in the clockwise direction in FIG. 3), pass under the stud 11 to prevent the distal panel from being lowered. 9 and as a consequence of the intermediate panel 14. The panels continue to pivot to progressively take a position approximately horizontal to fold into the formwork as shown in Figure 7. Figure 7 also illustrates the possible side mounting of dampers 22 braking the pivoting of the proximal panel 8 relative to an elevator car and in this case with respect to the formwork 7. A sling 23 is attached to a distal end of the compass at the axis of rotation 12 and at the other end to the formwork 7 via an attachment piece 24 of the damping ram 22 to the formwork 7. The sling is returned by a haulage 26 and a pulley In another embodiment, no tensile cable was installed and the folding of the panels was done manually.

Claims (4)

REVENDICATIONS1. A method of deploying an elevator foot hunt comprising two, three or four sliding telescopic panels (8, 9, 14) including a proximal panel (8) and a distal panel (9), the proximal panel (8) being attached pivoting under an elevator car and being integrally provided with a compass (1) limiting the pivoting so that the sliding telescopic panels (8, 9, 14) are approximately vertical when the compass (1) is deployed, the distal panel ( 9) in the extended position being remote from the elevator car, and the panels (8, 9, 14) being initially placed approximately parallel to the floor of the elevator car and locked in this position, in which - the panels are unlocked (8, 9, 14), which causes their pivoting to a vertical position and the opening of the compass (1), - the compass (1) being provided with a multifunctional piece (2) provided towards the distal end of the compass (1), said multifunctional part (2) comp providing two projections, one of folding (5) and the other of locking (6), directed towards the inside of the plates, the locking projection (6) initially blocking the deployment of the distal panel (9), - opening of the compass (1) producing the rotation of the multifunctional part (2) and the locking projection (6) and consequently the unlocking of an element of the distal panel (9), thereby permitting the vertical deployment of said panel distal (9) and accordingly the optional intermediate panel (s) (14), and wherein the distal panel (9) drives down the optional intermediate panel (s) (14). 2. A method according to claim 1, characterized in that the projections (5,6) are longitudinally offset relative to each other vis-à-vis the compass (1). 3. A method according to claim 1 or 2, characterized in that the flush comprises three sliding telescopic panels (8, 9, 14). 4. A method according to one of claims 1 to 3, characterized in that in addition is folding the hunt feet for elevator. . A method according to one of claims 1 to 4, characterized in that the distal panel (9) or an intermediate panel (14) presses on the locking projection of the compass to lock it in the open position. 6. A method according to claim 4 or 5, characterized in that 5 to fold the hunt feet - it causes the raising of the distal panel (9) - a portion of the distal panel (9) then pressing on the folding projection (5) of the multifunctional part which causes its pivoting and consequently the beginning of closure of the compass (1), which allows the vertical pivoting of the panels (8, 9, 14), - the locking projection (6) of the multifunctional part pivoting as well and coming to block the distal panel (9) in the closed position. the panels (8, 9, 14) are pivoted in order to fold them in approximately horizontal position. 7. A method according to one of claims 1 to 6, characterized in that one slows down a tilting opening of the panels by providing a damper (22) cooperating with a sling (23) integral with the traction of the proximal panel (8). ). 8. A hunt comprising two, three or four sliding telescopic panels (8, 9, 14) including a proximal panel (8) and a distal panel (9), the proximal panel (8) being in the deployed position, which is the closer to the elevator landing and being provided to pivot under an elevator car and also being integrally provided with a compass (1) limiting the pivoting of the sliding telescopic panels so that said sliding telescopic panels (8, 9, 14) are about vertical in the deployed position, the distal panel (9) being in the deployed position the one furthest from the elevator landing, and the panels being initially placed approximately parallel to the floor of the elevator car and locked in this position, characterized in that the compass (1) is provided with a multifunctional part (2) integrally provided towards the distal end of the compass (1), said multifunctional part (2) comprising two projections (5, 6) directed towards the inside of the plates, the projections (5, 6) being longitudinally offset with respect to the compass (1), the distal panel (9) comprising a member (11) cooperating with the locking projection (6) blocking the distal panel (9) before deployment and afterrepliement when the distal panel (9) comes into abutment, the distal panel (9) also comprising a tongue (13) forming a stop cooperating with the folding projection (5) of the multifunctional part (2) to push it at the end of the folding stroke of said distal panel (9) and cause the release of the compass (1) and its beginning of closure. 9. A flush according to claim 8, characterized in that it comprises a formwork (7) for storing sliding telescopic panels (8, 9, 14) and in that each of the ends of the compass (1) is mounted on a pivot (12), distal to the proximal panel (8), proximal to an elevator car or to a formwork (7) for storing the sliding telescopic panels (8, 9, 14). 10. A flush according to claim 8 or 9, characterized in that it comprises a damper (22) cooperating with a sling (23) integral with the traction of the proximal panel (8) to slow the tilting opening of the telescopic panels sliding (8, 9, 14). 11. A flush according to one of claims 8 to 10, characterized in that it comprises a locking system in the folded position associated with an electrical contact signaling said folded position. 12. A flush according to one of claims 8 to 11, characterized in that it comprises an articulated arm associated with one or more contacts signaling the extended position of said flush, said one articulated arm being on one side integral with the proximal panel (8) and the other of the distal panel (9). 13. A compass (1) comprising two branches and two ends, comprising integrally at one of its ends a multifunctional piece (2) installed on the inner side of the compass (1), said piece comprising two projections (5, 6). ) preferably installed consecutively in the longitudinal direction of the compass (1), the ends of the compass (1) being arranged to pivot.