FR2932512A1 - Form panel support platform's articulated foldable spacer for use during construction of building, has joint placed between one of branches and leg, and return spring to maintain branch in non-alignment position with other branch - Google Patents

Abstract

The spacer has branches (15a, 15b) articulated on a chassis (7), and placed on a support leg (13). A joint (18) between the branch (15b) and the support leg includes a return spring to permanently maintain the branch (15b) in a non-alignment position with the branch (15a). The spring is constituted of an elastically deformable metallic blade (30) whose end is slidingly mounted and supported against the leg. Another end of the blade is connected to the branch (15b). The spring is associated to a blocking unit i.e. sliding bolt (31), of the joint between the branches.

Description

The invention relates to an articulated spacer for platform support sleeve. In the construction of various cast concrete buildings, it is known, as shown in Figure 1, to fix cantilever against the outer walls 2, previously cast and removed, structures 3 in the form of a console. Each of them comprises an upper platform 4 projecting outwards in the extension of the top of the wall 2 and, optionally, the level of the slab 5 placed inside the building. The various structures form, around the construction, a footbridge bordered by guard rails 6 allowing the staff to circulate without risk of falling. These structures also act as a support surface for the panels 11 and other elements used for formwork of the next upper wall. In each structure 3, the frame 7 of the platform comprises vertical uprights 8 connected by horizontal crosspieces 9. During the installation of each platform the cross members 9 cooperate with hooks 10, previously fixed against the wall wall 2 previously cast. Each of the uprights 8 is linked by a hinge 12 to the two legs 13 of a support frame against the vertical wall 2. Finally, each of the legs 13 is connected to the free end of the frame 7 by a folding strut 15, but lockable and unlockable manually. This spacer comprises a branch 15a hinged at 16 on a lug 17 projecting downwards from the frame 7, and a branch 15b articulated at 18 on a lug 19 projecting horizontally from the leg 13. The two branches 15a and 15b are hinged to one another by a hinge axis 20 to form a compass folding in the angle formed between the frame 7 and legs 13, as shown in Figures 7 and 8. When the two branches 15a-15b are aligned and form a support spacer of the end of the frame, they are locked by a manually operated means, for example, by a ring 22 slidably mounted on the branch 15a. This ring has on one side a latch 23 which, when it is on the joint, opposes the folding of the branch 15b. The ring is also provided with a locking screw 24 on the leg 15a. At the end of the casting operation of the outer walls of the upper level of the construction, each platform structure 3 is extracted from its hooks 10 and is brought to the upper level by a lifting means, such as a crane. At the end of the construction of the building, each platform is brought to the ground to be folded and stacked, before its reuse to build another building or before being loaded onto a vehicle to be brought to a storage location. It is in this phase of folding displacements that this type of platform has disadvantages. Indeed, to close the compass of each of the two spacers of each platform, it is necessary that, as soon as the legs 13 bear against the ground, the locking ring 22 of each compass 15 is manually removed from the hinge area to allow the folding of the compass as the lowering of the structure to the ground. As soon as the leg lock is unlocked, the operator must move away to allow the folding to finish, and then check the lock of the folded leg on the frame orps. This imposes the presence of a person on each leg for a very punctual operation. Furthermore, during the vertical movements of the structure, if a leg is not perfectly locked on the frame, it can open and even self-lock in the position of separation, thus increasing the vertical space in 20 an area hardly visible by the crane operator. When the structure is laid on a stack of structures, this abnormal size hinders piling, can cause an accident and, as a precaution, requires a human presence to control the smooth running of this phase. It is an object of the present invention to overcome these disadvantages by providing a collapsible spacer which folds up just as easily but whose limbs do not return to the alignment and locking position in the absence of manual human intervention and including unlocking. According to the invention, at least the articulation between one of the branches of the spacer and an element of the structure of the platform, such as chassis or support leg, contains a spring means tending continuously to bring the branch in a position of non-alignment with the other branch. With this arrangement, as soon as the structure is brought close to the ground and the legs are unlocked spring means tend to misalign and prevent a new block. This facilitates the stacking of the platform and its deposit on the ground, but also reduces the risk of accident during his travels. In one embodiment of the invention, each of the spacers is associated with means automatically locking between them the 5 elements on which its branches are hinged. These means, which automatically come into action as soon as the structure is placed, prevent the legs and the support frame from disengaging the chassis and unfold during the vertical and horizontal movements of the structure. This arrangement simplifies the task of the staff, since it no longer has to participate in this locking, and reduces the time of activity and labor costs, while improving the safety of the site. Other features and advantages will become apparent from the description which follows with reference to the schematic drawing annxxed showing two embodiments of this platform. Figure 1 is a side elevational view of a platform according to the state of the art; Figure 2 is an elevational side view of a platform according to the invention; Figures 3 and 4 are partial side views in section and on an enlarged scale showing two embodiments of the spring means; Figures 5 and 6 are partial views in section and on an enlarged scale showing an embodiment of the means for locking the articulation of the compass when they are, respectively, in the locking position and in the unlocking position. Figures 7 and 8 are elevational side views showing a platform, respectively, in the folding phase and in the folded state. In the description which follows, the elements identical to those of the state of the art will bear the same references, the new ones will be referenced starting from 30. The embodiment of the spacer shown in FIG. 2 differs from that of FIG. of Figure 1: - by the presence of spring return means 30, arranged in the hinge 18, between the leg 13 and the branch 15b of the compass, - by a new embodiment of the means 31 for locking the joint 20 of this compass, - and by the arrangement, at the free end of the frame 7, 32 automatic locking means legs 13 against this frame, and, consequently, the compass in the closed position, arranged between these two elements . In the embodiment shown, the support leg 13 is constituted by a metal section of rectangular section, while the branch 15b of the compass forming the spacer is constituted by a metal section U section, having a core 33 and two wings 34. The branch 15a of this spacer is constituted by a metal section of square section having smaller dimensions to be housed inside the U-shaped section of the other branch 15b. In the embodiment shown in FIG. 3, the spring means associated with each of the hinges 18 of a platform 4 consists of a metal blade 30, elastically deformable, disposed in the profile 15b, resting against the leg 13 and attached to one of the elements of the joint by one of its ends. It is inserted between the axis 18 of the branch 15b and the inner face of the core 33 of the U-shaped section constituting this branch. More particularly, one of its ends is provided with a bend 30a with two lugs 30b projecting laterally and able to penetrate into notches 37 formed in the wings 34 of the branch 15b. Thus, the blade 30 may, while remaining connected to the branch 15b, bend and move relative to the elements against which it relies. In Figure 3, corresponding to the position taken by the blade when the two branches 15a and 15b are in alignment and blocked, the ends of this blade form between them an angle of the order of 120 degrees. With this angulation, the blade 30 exerts, on the branch 15b, around the hinge 18 and in the direction of the arrow 38 of FIG. 3, a return torque tending to bring this branch against the leg 13, but also to the misalign with branch 15b. This results in two consequences: - the first is that the means 31 for wedging the joint 20 between the two branches 15a and 15b can not operate automatically under the effect of gravity, but only by manual intervention bringing the two branches in alignment, - the second is the consequence of the first since, as soon as one of the support legs meets the ground, it is subjected to a force ensuring its folding against the frame, until it locks in position totally folded.

In the embodiment shown in Figure 4, the spring biasing means are constituted by a helical torsion spring 130 disposed around the hinge axis 18 and inside the branch 15b. The protruding end 130a of the wire constituting the spring bears against the web 33 of the branch 15b, while the other protruding end 130b is in sliding abutment against the profile constituting the support leg 13. These means provide the same In an alternative embodiment not shown, each of the hinges 16 and 18 of each spacer 15a-15b is provided with spring return means, 30 or 130. As shown in FIGS. 5 and 6, the means locking 31 of the hinge 20 between the two branches 15a and 15b of the compass comprises a plate 40 which is slidably mounted on the wall 35 of the branch 15a. This plate carries at one end a plane lock 41 adapted to come above the web 33 of the branch 15b. The plate 40 and the latch 41 are traversed by a bolt 42, also passing through an oblong slot 43 formed in the wall 35 and an inner plate 38. The bolt 42 holds the latch 41 on the branch 15a of the compass, while its rod, abutting against the ends of the light 43, 20 limits the stroke of the lock, and that its nut 42a forms, by its protrusion, means for actuating the lock. Guiding in longitudinal translation of the wafer is completed by two tabs 40a which, laterally projecting, are bent so as to slide against the outer faces of the side walls 36 of the branch 15a. Each locking means 31 can occupy a locking position, in which, as shown in FIG. 5, the lock 41 is above the core 33, and an unlocking position, shown in FIG. 6, in which this The lock is set back from the end of the branch 15b, which can thus pivot freely around the hinge 20. The unlocking position is temporary, since, as soon as the operator stops pushing back the wafer and latch assembly, the gravity slides them downwards and brings the latch 41 under the web 33. In this position, the latch 41 prevents the alignment of the two branches 15a and 15b, and thus the locking of the articulation, until that a manual action back the lock 41 to allow the alignment of the branches, then the blocking of the joint, after sliding of the lock 41 above the core 33. The inner plate 38, which slides with the plate 40 and the latch 41, is asymmetrical around the bolt because it is longer than the lock 41.

It constitutes a means opposing the tilting of this lock against the wall 35, when the soul 33 is not between them. Thanks to this, the lock remains parallel to the core 33 and, when the operator controls the lock, this lock encounters no obstacle and can come over the core 33. Finally, and as shown in FIG. the means 32 for locking the platform in the folded position comprises a hook 46 articulated at 47 on a tab 48 disposed laterally to the frame and projecting downwards. At its free end and below its notch 49, the hook has a slope face 50. At the hook 46 is associated a finger 51 which protrudes laterally from the support leg 13, is positioned to snap into the notch 49 of the hook. Indeed, when the support leg 13 is folded towards the platform 3, as shown in Figure 7, the finger 51 approaches the hook 46, then comes into contact with its sloping face 50. Under this support effort, the hook pivots in the direction of the arrow 52, until the finger 51 loses contact with the ramp 50, releases the hook and allows it to pivot in the inverting direction to engage its notch 49 on the finger 51. Thus locked in the folded position, the platform structure can be moved without risk of unfolding. Unfolding is easily done by gravity and with the help of springs 30 or 130, as soon as a manual intervention tilt each of the hooks 49 to release the finger 51 corresponding. It follows from the above that, thanks to the springs that prevent the automatic locking of the compass, folding and folding movements of the platform require only one person and are safer, so without the risk of generating bad storage and piling and incidents that could injure staff.

Claims (8)

CLAIMS1.) Articulated spacer platform platform support, said spacer (15) being: - on the one hand, interposed between one end of the frame (7) of the platform and 5 a leg (13) against the wall leg itself articulated by a hinge (12) on the other end of the frame and - on the other hand, consisting of two branches (15a, 15b) hinged, one on the frame (7), the another on the supporting leg (13), and one on the other in the manner of a compass (15a-15b) folding in the angle formed between frame (7) and leg 10 (13), characterized in that at least the hinge (18, 16) between one (15a, 15b) of its branches and a platform member, such as frame (7) or support leg (13), comprises spring biasing means (30, 130) continuously tending to bias the biased limb (15a or 15b) to a position of non-alignment with the other limb. 2.) Articulated spacer for platform support tray according to claim 1 characterized in that the spring biasing means is constituted by an elastically deformable blade (30), one end is slidably mounted and resilient support against the support leg (13) and 20 the other end is connected to the leg (15b) of the compass (15a-15b) against which it is supported. 3.) Articulated spacer for platform support tray according to claims 1 and 2 taken together characterized in that the elastically deformable blade (30) is inserted between the hinge axis (18) of the branch (15b) and the inner face of the core (33) of the U-shaped section constituting this branch. 4.) Articulated spacer for platform support tray according to claim 1 characterized in that the spring biasing means is constituted by a helicidal torsion spring (130) disposed about the hinge axis (18) and to the interior of the branch (15b), the spring whose protruding ends (130a and 130b) are respectively supported against the soul (33) of the branch (15b) and against the support leg (13). 5.) Spacer articulated platform support tray according to claim 1 characterized in that the articulation (20) between its two branches (15a, 15b) is associated with a latch (31) slidably mounted on the upper branch (15a) with possibility to come, under the sole action of gravity, in the locking position of the articulation (20) between branches, and come into unlocking position only by manual human intervention. 6.) Articulated spacer for platform support tray according to claims 1 and 5 taken together, characterized in that the latch (31) is constituted by a plate (40) slidably mounted on the outer face (35) of the upper branch ( 15a) of the compass (15a-15b), this plate being secured: - on the one hand, a bolt (42) slidably mounted in a slot (43) of the branch (15a), said bolt (42) constituting means of limitation of the possible stroke, means of maneuvering and retaining means on the branch, - and, secondly, of a plane lock (41) carried by the plate (40) and adapted, in the locking position of the articulation, coming over the soul (33) of the other branch (15b). 7.) Articulated spacer for platform support tray according to claim 1 characterized in that each of the spacers is associated with means (32) automatically locking between them the two elements (13 and 7) on which its branches (15a, 15b). are articulated 8.) Articulated spacer for platform support tray according to claims 1 and 7 taken together, characterized in that the locking means in the folded position comprise an articulated hook (46) and a finger (51), protruding laterally from the leg d support (13) and adapted to be crooked by the hook. .