RU2090713C1 - Vertically folding wall partition - Google Patents

Abstract

A rigid wall partition system (2) which is vertically upwardly movable into storage position and vertically downwardly movable to form a continuous wall. The system comprises a plurality of panels (8) secured to members which in turn are pivotally secured to spaced trains (20) of single pantographs, contraction of the pantograph causing the panels to fold, in accordion fashion and expansion of the pantographs causing the panels to move to vertical, wallforming position.

Description

 The invention relates to a system of wall partitions, and more particularly, to a system of wall partitions that rise vertically up to the place of installation and storage or fall vertically down to form a wall.

 Known systems of movable wall partitions are used in large buildings for dividing rooms having a large area into rooms having a smaller area. Conference halls and production facilities in factories are the type of indoor space that is most often used to divide it into smaller rooms using movable wall partitions.

 Such wall partitions can be made of canvas or other similar materials in the form of curtains that can be pulled up or down. Other, more durable types of movable wall partitions, extending from floor to ceiling and made of rigid material with a layer of heat insulating and / or sound insulating materials, placed between the outer wall-forming panels. The systems of mobile partitions, currently known, move by known methods on a horizontal surface. Movable partitions of these types require the allocation of a significant area (in plan) for the installation and storage of wall panels. Wall panels can have a very large weight and therefore the loads acting on the supporting structures (room ceiling, building roof, etc.) are variables that increase during the movement of wall panels to the place of storage and storage.

Currently, there are three main types of rigid movable panels designed to move on a horizontal surface:
(1) separate panels;
(2) paired panels (two articulated panels) and
(3) one-piece articulated panels (all panels are connected in series with one another).

 Individual panels can be installed one after the other using a manual or mechanical method of movement. Paired panels are manually installed. One-piece pivotally connected panels can be installed in place manually or by mechanical means. Individual panels do not have hinges, since they are not interconnected and therefore each panel moves individually along rails embedded in the ceiling or ceiling of the room. Paired panels and one-piece articulated panels have open hinges that give the wall partitions a very unattractive appearance, which limits the widespread use of this type of panel.

 Other disadvantages related to the use of movable wall partitions designed to be moved along ruts or rails embedded internally in ceiling ceilings or load-bearing roof structures of a building are as follows: the size of the installed and finished walls is limited by the weight and dimensions of the panels from which the wall partition is assembled , most of the largest wall partitions are moved and installed only manually, since considerable weight and friction practically eliminate Menen automation; mobile wall partitions require a significant area for laying and storing panels, thereby increasing the cost of construction work; cases of jamming of wall partition panels between the ceiling and the floor due to deflections of the roof supporting structures caused by additional loads from snow or rain are possible; wall partition panels cannot be quickly modified to meet customer specific technical requirements (for example, arrangement of voids, openings, etc.).

 One of the known systems of wall partitions, horizontally moved along rail guides and of interest for the present invention from the point of view of the prior art, proposed by Moderco Partitions Jnc. in the form of a folding (accordion) door, in which a well-known pantograph is suspended on rollers to rail guides embedded in the ceiling, and vertically oriented panels of flexible material are attached to spatially spaced elements of the well-known pantograph design in such a way that when When the pantograph is moved in the transverse direction, the partition (door) is folded, forming a corrugated surface.

 The known pantograph design used to form a folding door is similar to the same design used, for example, in the arrangement of playpens, in which a number of elements are pivotally coupled with the ability to form a series of such diamond-shaped structures along the entire length of the frame of the playpen. In a separate pantograph (in contrast to the design of a multi-link pantograph), one pair of structural elements of the same size are articulated at points located in the middle between the ends of the structural elements. On the one hand, the ends of these elements are pivotally connected to the ends of the corresponding next pair of elements having a length equal to the length of the elements of the previous pair, and similarly pivotally connected at their midpoints, etc. The midpoints of the pantographs structural elements are located on the same axis and form opposite corners in diamond-shaped structures, and other opposing corners are formed by the articulated ends of adjacent pairs of intersecting pantograph construction elements. Pantograph designs are stretched longitudinally, in a direction parallel to the axis formed by the intersection points of the structural elements, and are folded in the same way. The design of the pantograph is widely and successfully used in industry, since the forces applied to the pantograph longitudinally in the direction of extension (unfolding) or folding are uniformly transmitted through all structural elements.

 From the point of view of the prior art, it is of interest [1] which describes and presents a wall in which, as a basis, a pantograph in the form of scissors is used, to which another pantograph in the form of scissors is attached from above, and this design in the form of two paired pantographs is covered with two sides woven or other flexible material.

 The closest analogue of the claimed invention can be recognized [2] characterizing the design of the sliding walls suspended from the ceiling. The design contains rigid panels in the form of a series of equally extended elements pivotally connected to each other with the possibility of vertical lifting and lowering, mechanical means for lifting the lower horizontally oriented support beam and the upper horizontally oriented support beam. A disadvantage of the known design should be recognized as its bulkiness when folded, as well as the rigidity of the structure, limiting possible applications.

 The technical problem solved by the present invention is to design a universally folding partition.

 The technical result obtained as a result of the implementation of the invention is to expand the scope of the design, as well as to increase the usability.

 The invention relates to the improvement of the design of the wall partition, which will rise vertically up to the position of laying and storage and fall vertically down to the position of formation of the wall partition (hereinafter referred to as the wall formation position). The partition contains a support frame consisting of rows of elongated elements installed in the vertical direction and having the same design. The rows of said elements are spaced horizontally at a predetermined distance. The elongated elements of each row make up a single pantograph design, from which one row of vertically placed rhomboid structures of the same size is formed and which are aligned parallel to the line for installing the wall partition. The rows of pantographs, moving apart, go down to the wall formation position, and rise up to the stacking and storage position. The rows of rhomboid structures form horizontal rows in which the rhomboid structures of each row have the same size and shape. In each row, identical pairs of intersecting elements of the diamond-shaped structure are articulated at their midpoints located in the middle between the ends of the said element and form adjacent vertically located vertices of the diamond-shaped structures. The corresponding ends of these pairs of intersecting structural elements are pivotally connected to the ends of other pairs of intersecting elements to create vertices of rhomboid structures located at the ends of these elements so that when laying all rows of pantographs, the vertical vertices of the rhomboid structures are stacked and the rhomboid structures themselves are folded around their transverse vertices.

 A pair of elongated load-bearing elements of a wall partition panel having the same length is connected to each diamond-shaped structure. The supporting elements of the panels are pivotally connected on one side to each other by their ends, and their other ends are connected to the element on one side of the pantograph opposite the corresponding vertically arranged vertices of the diamond-shaped structure. The same panels are used in a wall partition and each of them is attached to the panel supporting element in each row at the corresponding height in the horizontal row, and the other panels are attached at different heights so that the panels are moved apart in the horizontal lateral direction by a predetermined distance. The first horizontally oriented support beam serves to connect the lower rows of pantographs, and the second horizontally oriented support beam serves to connect the upper ends of the rows of pantographs. Mechanical means are provided that are connected to the first horizontally oriented support beam, and which, after switching on, starts lifting the first support beam, supporting it in a horizontal position during the lifting, while the diamond-shaped structures are folded at the same speed as during the lifting the first support beam in the position of laying and storing the wall partition. The panels have a rigid structure and a certain length, due to which, when the rows of pantographs are extended to a certain limit, the said panels are brought into a vertical position and come into mutual contact, thus forming a continuous wall surface. For a pair of defined panel supporting elements having the same length and connected to each diamond-shaped structure, the axes located at each end of the said elements are designed and mounted so as to allow unimpeded movement of the said elements and panels. It is possible that the same load-bearing elements of the panels and the panels themselves are attached in the same way to both sides of the pantographs connected in the said rows to form a continuous wall surface on both sides of the pantographs when the load-bearing elements of the panels are moved to the vertical position.

 During operation, the system of vertically movable wall partitions, in accordance with the present invention, is made mainly of parallel rigid panels mechanically connected in the form of a pantograph. Since the rows of pantographs are folded when moving up, the wall partition rises up and folds in the form of an "accordion". Since the rigid panels are connected to one another, the installation control and removal of the partition wall can be fully automated. Further, due to the structures used in the invention, the joints and hinges are made invisible from the side of the wall panel or from both sides.

 Due to the fact that the rigid panels of the wall partitions move in the vertical plane, and not on the horizontal surface of the room, the need for space for installation and storage is eliminated, since the wall partition is folded and stored raised to the ceiling above its installation site. In other words, the wall partition does not move in the transverse direction.

 In FIG. 1 and 2 are a schematic perspective view of a system of rigid movable wall partitions in a half-low position and in a wall formation position; FIG. 3 is a schematic perspective view of one row of pantographs of the system shown in FIG. 1, without panels for clarity of drawing, in the position of laying and storage; FIG. 4 is an enlarged perspective view of the lower part of one row of pantographs of the system in the developed position without panels, with the image of parts of the release mechanism; FIG. 5 and 6 are a side view of part of the pantograph and the supporting elements of the panel, respectively, from the position of laying and storage (5) and in the position of wall formation (6); FIG. 7 is a sectional view taken along line VI - VI of FIG. 3, but with a pantograph in the lower position of the wall formation, depicting the articulation of the ends of the pair of supporting elements of the panel; FIG. 8 is a view along line VII VII of FIG. 7 and; FIG. 9 and FIG. 10 is a schematic side view of a series of adjacent panel supporting elements in a vertical wall-forming position depicting the correct and incorrect position of the rotation axes of the panel supporting elements.

 The invention is further explained by the description of a specific example of its implementation, which, of course, in no way limits the scope of the invention to this embodiment, but rather involves making changes, making equivalent decisions and implementing various modifications without departing from the essence and scope of the invention specified in the claims.

 In FIG. 1 and 2 show, according to the invention, a system 2 of vertically movable rigid wall partitions located respectively in a half-low position and in a wall formation position. This system comprises a frame structure made of elongated elements 4 assembled in the form of pantographs, and placed along the midline of the created wall partition, and pantographs are placed with the possibility of expansion in the vertical direction. Using the fastening method, which will be described in more detail below, the supporting structure of the panels 6, the rigid panels 8, the support beam 10 of the lower pantograph, the support beam 12 of the upper pantograph and the mechanical power system 14 for raising and lowering the system 2 are attached to the frame structure of the wall partition the upper pantograph beam 12 is fixed and held in a horizontal position in the upper (ceiling) part of the room where the installation of a wall partition is planned. As shown in the drawings (Figs. 1 and 2), the system 2 can be placed in a niche 10 for laying and storage arranged in the ceiling of the building in which this system is installed and has such overall dimensions that when lowering the said system to the lower wall formation position, the formation of a solid wall partition across the area intended for partitioning.

 As shown in FIG. 2 and 3, the elongated elements 4 form rows 20 of vertically mounted pantographs and said rows of 20 pantographs are spaced horizontally at predetermined distances. Elements 4 that make up each row of pantographs form one vertically expanding and folding pantograph, in which elements 4 are pivotally connected at their midpoints and form vertically located vertices 22 of adjacent diamond-shaped structures 24, and the ends of elements 4 are pivotally attached to the ends of similar pairs of elements and form transverse vertices 26 of rhomboid structures 24. Pantographs forming rows of pantographs 20 are arranged so that the planes of rhomboid structures 24 lie along the middle the line created by the wall partition. All elements 4, with the exception of the two most extreme elements of the final diamond-shaped structures of each row of pantographs 20, have the same length. This ensures the horizontal position of the support beams 10 and 12 of the upper and lower pantographs and creates horizontal rows of diamond-shaped structures 24 in the direction from one row of pantographs 20 to the next row. The supporting beams 10 and 12 of the lower and upper pantographs are attached to the corresponding rhomboid structures 24, respectively, to their lower peak 28 and upper peak 30 so that the corresponding elements of the said diamond-shaped structures could freely rotate relative to the mentioned vertices 28 and 30.

 When lifting the support beam 10 of the lower pantograph from the position indicated in FIG. 3, all vertically located peaks 22 will simultaneously occupy the upper position, and the wall partition will be completely removed up. As a result of this movement, the diamond-shaped structures 24 begin to fold basically at the same speed as the lower vertically located vertex 22 of each diamond-shaped structure 24 will move to its upper peak 22.

 As shown in FIG. 3 and 4, on each side of the rows of pantographs 20 formed by the elements 4, the supporting elements 6 of the wall partition panels are pivotally fixed.

 More specifically, the upper panel support member 32 and the lower panel support element 34 are mounted on one side of a diamond-shaped structure 24 formed from the elements 4. The support elements 32 and 34 are pivotally connected by hinges 36 when the panels 8 are installed on the supporting elements. Others the ends of the supporting elements 32 and 34 are pivotally attached by means of hinges 38 to the elements 4 adjacent to the corresponding vertices 22, as shown in the figures. To facilitate further description of the invention, hinges 38 will be referred to as hinges "A", and hinges 36 will be referred to as hinges "B". The hinges "A" are attached to the pantograph structure formed by the elements 4 of this row of pantographs, and the hinges "B" are moved, moved apart or are in a "floating" position relative to the plane of the rhomboid structures of the 24 rows of pantographs 20 during the expansion and folding of the said rows of pantographs. In the system of double-sided wall panel partitions shown in the drawings, each of the diamond-shaped structures 24 on each side of a row of pantographs 20 has a pair of interacting supporting elements 32 and 34 of the panels articulated by hinges 36 and 38.

 The load-bearing elements 32 and 34 of the panels have the same length, which is selected so as to ensure that the load-bearing elements 32 and 34 of the panels are installed in a vertical position after the rows of pantographs 20 are completely apart and installed in the wall formation position (see Fig. 2) . Thus, the panel 8 attached to the supporting member 32 and the other panel 8 attached to the supporting member 34 have a vertical width corresponding to the length of their supporting members, thereby creating a wall partition having a continuous surface after the installation of the supporting members 32 and 34 panels in vertical position. It is desirable that the panels 8 have a rectangular structure elongated in the horizontal direction, and one panel or a set of panels is attached to all the supporting elements 32 (or 34) of the rows of pantographs 20 so that they lie in a horizontal position at the same level. Preferably, a small pad 40 made of resilient material is attached to the opposite sides 42 of the panels 8 in the horizontal and vertical directions to provide sound insulation between adjacent panels.

 To make the hinges "B" connecting the pairs of supporting elements 32 and 34 of the panels invisible to the eye after installing the panels 8 in a vertical wall-forming position, the end hinges of the usual type were unsuitable for this purpose. Instead, as shown in FIG. 6 and 7, a pair of hinge plates 44 is used, which are attached to each supporting element 32 and 34 of the panels with the possibility of rotation around the rotation axes 46 spaced apart by a certain distance and placed inside the wall partition at a certain distance from the outer surface of these supporting elements of the panels (Fig. 6 ) so that the joints of the panels become invisible from the outside. With this design, in order to provide the required relative position of the supporting elements 32 and 34 of the panels, the opposite ends 50 of which move outward or inward during the expansion of the rows of pantographs 20, an earring and interacting curved spur gear segments 52 of the supporting elements 32 and 34 of the panels are used. Spur gear segments 52 are made and placed at the ends 50 of the supporting elements 32 and 34 of the panels so that the teeth of the said segments mesh to ensure that the supporting elements 32 and 34 of the panels are fixed in the required position and that one of the said supporting elements is folded in or out of the rows of pantographs 20 panels would move out or in only at the same speed as other load-bearing elements.

 The hinges "A" of the supporting elements 32 and 34 of the panels may have any known design that provides the necessary movement of the supporting elements of the panels. The hinges "A" should be attached to the elements of a number of pantographs 20 near the vertically located peaks 22 so as not to impede the movement of the elements 4.

 The optimal placement of the hinge 38 is shown in FIG. 5 and 6 in the form of a series of consecutive positions of its components on one side of the elements 4. Each of the ends of the interacting supporting elements 32 and 34 is pivotally attached using a four-axis hinge 54 to one of the elements 4 near the corresponding vertex 22, in which the elements are pivotally connected to each other , as shown in the drawing, so that when the elements 4 move from the folded position of FIG. 5 to the wall formation position with the pantographs fully extended and again to the folded position, the opposite ends of the interacting supporting elements 32 and 34, and the panels mounted on the said elements would not impede movements relative to each other. The hinge 54 is movably fixed on the interacting supporting elements 32 and 34, and the panels mounted on the said supporting elements are fixed on the axles 56. One end of the plate 57 is pivotally attached by an axis 58 to the base 59 of the hinge 54 and the mentioned base is attached to the corresponding element 4. A sleeve 60 is welded to the other end of the plate 57, inside of which an axis 61 is pivotally attached to the main body of the hinge 54, as shown in the drawing. Thus, the four axis of rotation of the hinge provide the necessary movement of the supporting elements 32 and 34 of the panels.

 As shown in FIG. 10, if necessary, raise the rows of pantographs 20 from a fully extended position, i.e. to enter the said pantographs from the position of wall formation and at the same time completely exclude the possibility of jamming of the supporting elements 32 and 34 of the interacting panels in a vertical position along the entire length of the rows of pantographs 20, it is very important that the hinges "B" were placed on the outside with respect to the hinges "A" upright.

 Thus, when the forces acting in the upper direction are applied with the support beam 10 of the lower pantograph to the lower peak 28, then the floating "B" hinges 36 are set in a position convenient for starting outward rotation around the corresponding hinges "A" at the other ends of the corresponding load-bearing elements 32 and 34 panels.

 Therefore, the placement of the hinges "A" and "B" on the supporting elements 32 and 34 of the panels, shown schematically in FIG. 10 is correct. The misplaced hinges shown in FIG. 9 leads to the fact that when the forces acting upward on the supporting elements 32 and 34 of the panels, these forces force the hinge "B" to make an inward rotation with respect to the number of pantographs 22 or under the influence of the aforementioned forces, the supporting elements 32 and 34 of the panels remain locked in former position. Therefore, the relative arrangement of the hinges “A” and “B” shown in FIG. 9 leads to the formation of an inoperative structure.

 For lifting the rows of pantographs 2 to the position for laying and storing the wall partition and to the wall formation position, a mechanical wall system 14 is provided, schematically shown in FIG. 1 and 2. The power system 14 comprises a linear shaft 64 rotatable by the motor 66. Preferably, the linear shaft 64 would be mounted on the ceiling above the rows of pantographs 20 and extend along the entire length of the panels 8, as shown in FIG. 1 and 2. Each row of pantographs 20 is equipped with a cable 68, one end of which is wound on a corresponding drum 70. In the preferred embodiment of the invention shown in FIG. 3 and 4, the cable 68 is lowered down, passed through a pair of pulleys 72, mounted on the support beam 10 of the lower pantograph on both sides of the lower peak 28 and then attached to the corresponding control device 74 (Fig. 3), by which the length could be adjusted a cable 68 unwound from the drum 70. This adjustment is important to maintain all the cables 68 in tension, which is necessary for the normal operation of the system 2 and to keep the support beam 10 of the lower pantograph in a horizontal position.

 If during operation the system 2 is in the wall formation position shown in FIG. 2, in which the panels 8 are in a horizontal position, forming a wall partition, it became necessary to raise the panel 8 to a position for laying and storage, then turn on the motor 64, and the lifting cables 68 will be simultaneously and evenly wound on the corresponding drums 70. As a result, the support beam the lower pantograph will start to rise in horizontal position with the help of the mentioned cables and will cause folding of the rows of pantographs 20. Folding these pantographs causes the hinges "B" of the supporting elements of the 6 panels outward to thoron plane of rhomboid structures 24 rows trains 20, whereby the panel 8 are formed in the form of a "concertina" and crosslinks rows 20 extend in the niche 16 for stacking and storage.

 The rotation of the linear shaft 64 in the opposite direction will lead to the unwinding of the cables 68 from their respective reels 70, which will cause the lowering of the support beam 10 of the lower pantograph and the gradual installation of the panels 8 in the vertical position of the wall formation.

Claims (7)

 1. A vertically folding wall partition, comprising rigid panels in the form of a series of extended elements of the same design, articulated to each other with the possibility of vertical lifting and lowering, mechanical means for lifting the lower horizontally oriented support beam and the upper horizontally oriented beam, characterized in that the wall partition equipped with rows of identical rhomboid pantographs connected by their upper ends to the upper horizontally oriented beam, lower ends with a lower horizontally oriented support beam with the formation of a support frame, while the rows of pantographs are mounted parallel to each other in the vertical direction and spaced in the horizontal direction, and in each vertical row, the diamond-shaped structures of the pantographs are formed by identical pairs of intersecting elements pivotally connected in the middle between their ends with the formation of vertically spaced vertices of adjacent rhomboid structures, and the ends of these pairs of intersecting hinge elements connected to the ends of adjacent pairs of intersecting elements, forming transverse vertices, while opposite the corresponding vertically arranged vertices of the rhomboid design, pairs of elongated supporting elements of panels made of the same length are pivotally connected with each other pivotally with each other, with the hinge axes at each end the elongated load-bearing elements of the panels are arranged with the possibility of unhindered movement up and down of the elongated load-bearing elements of the panels, and the panels are closed epleny on elongate carrying elements to form horizontal rows of panels, wherein the length of the carrier members equal to the width of the panels.  2. The partition according to claim 1, characterized in that the mechanical means is made in the form of a linear shaft located above the rows of pantographs in the center of the partition wall with drums and ropes mounted on it located above each row of pantographs, the cables of each drum being connected to the lower horizontally oriented support beam in the zone of attachment to it of the lower ends of the corresponding series of pantographs.  3. The partition according to claim 2, characterized in that the free end of each cable is fixed above the corresponding row of each pantograph using a fastening device that regulates the cable tension, and each cable is pulled through pulleys fixed in the lower horizontally oriented support beam.  4. The partition according to claim 1, characterized in that the elongated load-bearing elements of the panels and the panels fixed to them are located on both sides of the rows of pantographs.  5. The partition according to claim 4, characterized in that the adjacent to one another surface of the panels have elastic gaskets.  6. The partition according to claim 1, characterized in that the articulation of the elongated load-bearing elements of the panels at vertically arranged vertices of the diamond-shaped structure is made using an earring having two axes of rotation spaced apart by a distance, while one axis of rotation is located on one elongated bearing element, and the other is adjacent to it, and at the other ends of the elongated supporting elements of the panels there are toothed segments meshed with each other.  7. The partition according to claim 1, characterized in that the axis of the hinges of the connected pairs of elongated supporting elements of the panels are placed on the outside with respect to the axes of the hinges of the connection of the elongated bearing elements with vertically located vertices of the diamond-shaped structure.

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