RU2165506C2 - Collapsible awning cover (alternatives) - Google Patents

Abstract

FIELD: construction engineering; miscellaneous light-weight mobile easily assembled and disassembled structures compact when in packed state. SUBSTANCE: awning cover has top force assembly, beams hinged to the latter through their ends for easy turning in vertical plane and resting in extreme upper position of force assembly, posts whose upper ends are hinged to other ends of beams and locked in position, and awning arranged over frame; at least one post and/or one beam has at least one respective hinge separating them into at least two parts for folding them; there are also locks installed between posts and beams; awning is secured at least to posts. Proposed structure is easy to assemble and to disassemble and can be mounted on any grounds without fixation due to reduced size and convenient shape; it can be easily modified and takes short time and labor for its mounting and dismounting. EFFECT: improved operating characteristics; simplified handling; enhanced stiffness, mobility; enlarged functional capabilities; extended service life of frame and awning cover. 13 cl, 33 dwg

Description

 The invention relates to construction and can be used as lightweight mobile quickly mounted and dismantled compact in the folded state structures of various types and purposes, in particular used as trade stalls, pavilions, camping tents, for performing various kinds of work, for example, road, etc. d.

 A tent shelter is known that contains corner posts, beam elements pivotally connected by the first ends to the upper ends of the corner posts, the lower ends of which are pointed and have steps, and their upper ends have corner bevels made at an acute angle to the longitudinal axis of the corner posts and complement the corner bevels beam elements made at their first ends, the second ends of which are pivotally connected to the central node, and the hinges are made in the form of loops, one part of each of which is fixed to the upper surface of the prices the sweeping unit, and the other part is on the upper surface of the beam element; the ends of the second ends of the beam elements are adjacent to the perimeter of the Central node with the full extension of the beam elements and are stops in the extreme position of the extension of the beam elements; the hinges between the first ends of the beam elements and corner posts are also made in the form of loops, one part of each of which is fixed on the lower side of the beam element, and the other part on the inside of the corner pillar; folding spacers are located between the first ends of the beam elements and the upper ends of the corner posts, each of which consists of two elements, pivotally connected by one ends to each other, and the other ends - with the beam element and the corner post; an awning located on top of the frame and a stabilizing stand made in the form of a rod with a thread and a tip, moreover, it is screwed into the central hole equipped with the corresponding thread, and the upper end of the stand abuts from the inside to the top of the awning for its tension [1].

 The disadvantages of the known device are low operational and functional capabilities due to the large dimensions when folded, determined by the length of the dimensions of the corner posts, and by the width when folded - the place occupied by the folded struts located inside the “scissors” of corner posts and beam elements and preventing their full closure, which limits the transportability of the device and ease of use. In addition, low functionality is due to the rigid fixation of the device’s shape, which does not allow a wide range of possible modifications, for example, such as asymmetrical design, the combination of several devices in cellular structures, etc. Low functionality is also due to the presence of the pointed lower ends of the corner posts, used due to the low reliability of the system for fixing the frame in the assembled state using spacers and stops using inclined bevels and supplementing them by sticking the sharp lower ends of the corner posts into the ground, which narrows the scope device and does not allow its use on asphalt or concrete, i.e. virtually eliminates the use in urban environments, for example, as trade stalls, pavilions, etc. The disadvantages also include the insufficiently high speed of mounting and dismounting and a low resource due to the awning being completely removable from the frame and the need to tension it by screwing the mast (stabilizing stand) into the central node.

 The closest to the proposed technical essence is the device-tent frame containing the upper power node connected to it articulated by one ends of the beam with the possibility of free rotation in the vertical plane and focusing them in the extreme upper position of the power node, racks, the upper ends of which are articulated with fixing connected to the other ends of the beams, and an awning located on top of the frame. In addition, the beams are made of flexible material so that they are in tension and form a dome in the assembled device, the tent is fixed to the frame using rings on the posts and beams, the lower ends of the posts are pointed, and the device also includes braces and pegs moreover, some ends of the extensions are fixed to the upper ends of the uprights, while the other ends of each extension are attached to the peg [2].

 The disadvantages of the known device are low operational capabilities due to the large dimensions in length when folded, determined by the length of the racks, as well as due to the instability of the structure in assembled form and the high complexity of installation. The instability of the structure is due to the use of flexible spring beams, which reduce the rigidity of the entire structure when assembled. This is compensated by the fact that the upper perimeter of the tent is fixed by the fact that the upper perimeter of the device is fixed by braces with pegs driven into the ground, and the lower perimeter by sticking the sharp lower ends of the racks into the ground. This, in turn, complicates and increases the time of installation and dismantling of the device and increases its complexity. In addition, this leads to low functionality of the device, which does not allow its use in urban conditions on asphalt, concrete, pavement, etc., as well as due to the low mobility of the device when assembled, because the applied frame fixing system with stretch marks, pegs and sharp racks does not allow lifting it in the assembled state, moving it from place to place, turning, etc. The low functionality of the device is also due to the limited size of it both in height and in area. The height limit of the known device is determined by the need for a person standing inside the device to be able to reach the upper power unit in the assembled device by hand, because lowering it down during dismantling requires considerable effort to overcome the resistance of stressed spring beams. The area limitation is determined by the design flexibility, which leads to a sharp increase in the cross section of spring beams, which is unjustified, because makes manual installation and disassembly impossible. The disadvantages of the device also include the long duration of installation-dismantling due to the complexity and complexity of marking and driving in racks, pegs, fixing stretch marks, and also because the high complexity and complexity of mounting a known device is also determined by the impossibility of assembly by one person, because racks compared to spring beams are much lighter, and the upper power unit when lifting it up requires considerable effort, and therefore it is necessary to hold the device by the racks. In this case, 2-3 people are needed, because diametrically located racks need to be pulled down, and the upper power unit should be squeezed up, it is advisable to pull all racks down simultaneously so as not to strain the tent fabric. The disadvantages also include low resource and low manufacturability. The low resource is due to the fact that the spring beams are in a stressed state for a long time - throughout the entire time of the assembled position of the device, as well as their constant bending during installation and dismantling. In addition, a sharp tension of the fabric (cotton) when extruding the upper power unit up during installation or when lowering it down during dismantling when moving curved beams from one position to another sharply increases the wear of the tent fabric. Unreliable are also pegs, extensions and holes in the tent in the places of their attachment to the frame. Low manufacturability of the device is determined by the complexity of the cut of the spherical dome of the roof and the difficulty of manufacturing and the high cost of spring beams.

 The aim of the invention is to improve performance by reducing dimensions when folded, simplifying installation and dismantling and increasing rigidity, stability and mobility of the structure when assembled; expansion of functionality due to the implementation of the possibility of using the device on any gunts without fixing, as well as due to a significant expansion of restrictions on the size and shape of the device and facilitating its modifiability; reducing time and reducing the complexity of installation-dismantling and increasing the resource of the frame and awning.

 To achieve this goal in a known device - an awning frame containing an upper power unit, pivotally connected to it by one ends of the beam with the possibility of their free rotation in the vertical plane and focusing them in the extreme upper position of the power unit, racks, the upper ends of which are pivotally connected with fixation with other ends of the beams and the awning located on top of the frame, at least one rack and / or one beam each contain at least one hinge separating them at least into two parts with the possibility of folding parts, and also introduced latches located between the uprights and beams, and the tent is mounted at least on the uprights. In addition, each of the beams and / or racks contains at least one hinge, and all hinges are made with the possibility of folding in one direction, coinciding with the direction of folding of the beams in the upper power node, and focusing in the extreme position of the coincidence of the directions of the parts of each of them. In addition, the upper power unit is located asymmetrically with respect to the uprights, and the elongated beams contain at least one hinge that divides it into parts with the possibility of folding and focusing in the extreme position of coincidence of the directions of the parts of the beams containing the hinge. In addition, the upper power unit is made in the form of a base and hinges for attaching the beams located on its lower surface, each beam is fixed in the hinge so that its end protrudes toward the center of the node on the hinge axis. In addition, at least one second link is introduced into it, containing a second upper power unit, second beams connected with it at one end pivotally with the possibility of their free rotation in the vertical plane and abutting in the extreme upper position of the power unit, second struts, upper the ends of which are pivotally fixed to the other ends of the beams, and the second tent, located on top of the second frame, at least one second post and / or one second beam each contain at least one hinge that separates and x, at least in two parts with the possibility of folding the parts, and also introduced the latches located between the second racks and second beams, and the tent is mounted at least on the second racks. In addition, the length of all the second pillars and beams exceeds the length of all the first pillars and beams and the dimensions of the second tent exceed the dimensions of the first so that the second link allows you to accommodate the first beams, pillars with the upper power unit and the tent with the upper position vertical power unit. In addition, the links are connected in series, and each pair of adjacent links has two common racks, each of which contains two hinges with the corresponding beams of this pair of links, and the awnings of all links are connected so that they form one common coating for all links. In addition, additional serial connections of links, at least one, connected parallel to each other along long edges closely adjacent to each other in rows are introduced into it, and each rack at the points of their connection is common to each pair of serial links of links and contains the corresponding number of hinges with beams adjacent links. In addition, the hinges of the beams and / or racks are made in the form of loops, and the emphasis is formed by the ends of the parts of the beams and / or racks joined in the hinges. In addition, each hinge of beams and / or racks with emphasis is made in the form of a U-shaped channel, along the groove of which are located on both sides towards each other the ends of adjacent parts of the beam and / or rack, and on each half of the side surfaces of the channel and its corresponding end parts of the beam and / or rack are made through holes through which the axis passes with the possibility of free rotation around it of this part of the beam and / or rack. In addition, each hinge of beams and / or racks with an emphasis is made in the form of loops and a U-shaped channel, with one movable part of the loops connected to the end of the channel, in part of the length of the groove of which from the other end one of the adjacent parts of the beam and / or racks, and the other movable part of the hinges is fixed on the other part so that the end of the latter freely enters the channel of the channel from its other end on the side of the hinges attached to it. In addition, each hinge of beams and / or racks is made in the form of two plates located on both sides of the beam and / or racks in parallel planes so that one ends of the plates are located on one part of the beam and / or racks, and the other ends on the other parts, at each end of the plate and the corresponding part of the beam and / or rack, through holes are made through which the axis passes with the possibility of free rotation of this part relative to the plates. In addition, the emphasis is made in the form of two second plates, each of which is fixed at the end of each part in the interval between the axis and the end of the beam and / or strut and is located on one side of these parts in a plane perpendicular to the plane of the first plates. In addition, the emphasis is made in the form of a fixed pin passing through the holes in the first plates so that the ends of the two parts of the beam and / or strut abut against it from the opposite sides with cuts made across the ends parallel to the hinge axes, the shape of the cuts corresponds to half of the cross section of the pin, the hinge axes are each rigidly fixed in the corresponding part of the beam and / or strut, and the holes at the ends of the plates are oblong.

 In FIG. 1-7 shows the sequence of installation of the shelter.

 In FIG. 8 shows a diagram of a mounted shelter, side view.

 In FIG. 9 shows a diagram of a mounted shelter with another folding option, side view.

 In FIG. 10-13 show the installation sequence of the shelter according to the second folding variant of FIG. 9.

 In FIG. 14 is a diagram of an example of an assembled asymmetric trihedral shelter with one folding beam.

 In FIG. 15 is a diagram of an example of an assembled asymmetric tetrahedral shelter with two folding beams.

 In FIG. 16 shows a diagram of a winter embodiment of a shelter consisting of two links.

 In FIG. 17 shows a diagram of a multi-link shelter embodiment in the form of a series connection of links in a line.

 In FIG. 18 shows a diagram of a multi-link shelter embodiment in the form of a parallel connection of several link lines.

 In FIG. 19 shows a diagram of the principle of folding a multi-link version of the device.

 In FIG. 20 shows a folded device.

 In FIG. 21 shows an embodiment of an upper power unit with hinges on the upper surface of the unit.

 In FIG. 22 shows an embodiment of a power unit (upper) with hinges on the lower side of the upper power unit.

 In FIG. 23-29 illustrate embodiments of hinges for connecting parts of struts and beams.

 In FIG. 30 - 33 illustrate embodiments of examples of latches.

 Folding tent shelter (Fig. 8, 9) contains a removable cover 1 with a longitudinally or transversely located zipper, racks 3, forming the corners of the assembled structure, beams 4, forming the cover, the upper power unit 5, connected by hinges 6, located on it, with one ends of the beams 4, an awning cover 7 located on top of the frame and mounted on the uprights 3 and / or beams 4 using belts or pockets; the beam 4 consists of two parts of equal length 8 and 9 (possibly a larger number), connected to each other in the middle of the beam 4 by a hinge 10; the other ends of the beams 4 are connected to the upper ends of the uprights 3 with the help of angular hinges 11 (Fig. 8, 9), the racks 3 consist of two parts 12 and 13 of approximately equal length with the similar parts 8 and 9 of the beam 4 and are interconnected by hinges 14 , similar in design to the hinges 10, each of which (10 and 14) contains a stop located inside the assembled structure; the latches 15, rigidly connecting the upper ends of the uprights 3 with the ends of the beams 4 connected to them.

 The shelter may contain an arbitrary number of racks 3 and beams 4, which determines the number of faces of the assembled shelter (for example, four racks and four beams - tetrahedral). In particular, it can contain three pillars 3 and three beams 4 (Fig. 14) for a trihedral shelter and can be asymmetric, i.e., for example, one beam 4 - of double length, consisting of two parts 8 and 9 connected by a hinge 10 An example in FIG. 15 contains two folding beams 3, due to which an asymmetric shape of the tetrahedral type is formed.

 The winter version of the shelter (Fig. 16) contains two identical links 16 and 17, each of which is a separate shelter according to any of the options described above, and the linear dimensions of one of them 16 exceed the corresponding linear dimensions of the other 17. In the summer, each of the links 16 and 17 can be used independently.

 A multi-link shelter option may contain several series-connected links in a line (Fig. 17), with each rack 3 with the exception of the external posts 3 at the ends of the line connected simultaneously with the ends of two beams 4 using hinges 11. Another multi-link option (Fig. 18) contains a parallel connection of several lines of series-connected shelters, with each inner post 3 (except for those located along the perimeter) connected simultaneously with four beams 4 in the case of using tetrahedral . In both versions, the awning 7 is located on top of the entire structure and is mounted on racks 3 and / or beams 4.

 The upper power unit 5 (Fig. 21) contains a base 18, the shape of which in plan is a regular polygon depending on the number of faces of the shelter or a circle over which hinges 6 for attaching beams 4 are located at a distance from the edge, while the part protruding beyond the hinges 6 19 of the base is an emphasis, and the upper surface of the base 18 is made beveled at a small angle to the outside, equal to the angle of the roof slope. The hinges 6 of the node 5 can also be located from the lower surface of the base 18 (Fig. 22) directly along its edge, while the lower surface of the base 18 is made beveled to the center at an angle of the roof slope.

 The hinges 10 and 14 of the uprights 3 and beams 4, respectively, are made the same and can contain a channel 20 (Fig. 23) with two axles 21 passing through its walls 22 and fixed in them, around which the ends of the parts of the uprights 3 and beams 4 are freely rotated, through which axis 21 pass, and the bottom 23 of the channel groove 20 serves as a stop.

 The hinges 10 and 14 can each be made in the form of two channels 24 and 25 (Fig. 25), one of which (25) is fixed rigidly completely on one part 27 of the rack 3 or beam 4, and the other 24 so that part of it protrudes for the end of part 28 of the rack 3 or beam 4, both channels 24 and 25 are connected using loops 26.

 The hinges 10 and 14 (Fig. 26) can be made in the form of two plates 29 located parallel to each other on both parts of the rack 3 or beam 4 and connected by two axles 30, one of which passes through one part 27 and the other through the other 28 part of the rack 3 or the beam 4, which can freely rotate around these axes 30, on the ends of the parts 27 and 28 on one side are fixed plates 31, which are stops, oriented perpendicular to the plates 29.

 The hinges 10 and 14 (Fig. 27-29) can also be made of two parallel plates 33, fastened by a pin 32 passing through the middle of the plates 33, at the ends of which are elongated holes 35 through which the ends of the axles 34 are rigidly fixed in the corresponding the ends of parts 27 and 28 of the beams 4 and struts 3, at the ends of which are made diametrical semicircular grooves in the profile 36, corresponding in size to the pin 32.

 Folding tent shelter (Fig. 1-3) works as follows.

When mounting the shelter on its cover 1, undo the lock 2 and remove the cover 1 from the folded shelter. After that, it is positioned so that the posts 3 and the beams 4 are installed vertically, and the upper power unit 5 is located below (Fig. 1). Then, the upper ends of the folded package are pushed apart by rotating the lower ends of the beams 5 in the hinges 6 of the upper power unit 5 and the parts of the uprights 3 and the beams 4 are turned out together with the awning 7. For this, the beams 4 are first straightened out due to the fact that their parts are unbent 8 and 9 to the stop in the hinge assemblies 10 so that the parts of the beams 8 and 9 are on the same line (Fig. 2). Then, the upper ones in FIG. 2 the ends of the straightened beams 4 and turn the folded uprights 3 out by turning them 180 ^° in the upper corner hinges 11 (Figs. 3, 4), after which the parts 12 and 13 of the uprights 3 in the hinged nodes 14 are straightened so that they stop they were on the same line and occupied a position approximately parallel to the reduced beams 4 (Fig. 5). After that, the upper ends of the beams 4 (Fig. 7) begin to be pushed apart to the side and the upper power unit 5 is lifted up to the stop and the tent 7 is tensioned so that the unit 5 occupies the upper position (Fig. 8). With this structure turned outward, the lower ends of the uprights in all positions are moved apart by a distance less than the lower perimeter of the tent covering 7, i.e. the latter does not prevent the folding of the frame. All parts of the uprights 3 and beams 4 are deployed in one direction - as if they are rolled out from a rolled up position, which gives the movements the same type, which, in turn, facilitate the installation and dismantling of the device. Next, the pivotally connected ends of the uprights 3 are fixed with the beams 4 by installing the latches 15 in the corners of the assembled structure (Fig. 8). Thus, the device in the assembled state is held by the stops of the upper power unit 5, the stops of the hinge nodes 10 and 14 of the connection of the parts of the beams 4 and racks 3, the clips 15 and the tension of the awning 7.

In the embodiment with rotation in the corner joints 11 connecting the upper ends of the uprights 3 with the outer ends of the beams 4, against the direction of rotation of the beams 4 in the upper power unit 5 (Fig. 9), the device is dismantled as follows. Loosen the clamps 15, creating the tension of the tent 7 and holding the racks 3 and the beams 4 relative to each other, and lower the upper power unit 5 (Fig. 10) and move all the racks 3 closer to the center so that the outer parts 9 of the beams 4 are rotated in hinges 10 in the folding direction, which coincides with the direction of rotation when folding the parts 8 of the beams 4 in the upper power unit 5. In this case, the other ends of the parts 9 of the beams 4 are rotated in the corner hinges 11 in the direction opposite to the rotation of the parts 8 of the beams 4 in the hinges 6 of the upper power unit 5 up before closing with the upper parts 12 of the uprights 3. After that, since the distance between the lower ends of the uprights 3 along the lower perimeter of the awning 7 has decreased by a distance greater than the length of the two parts of the beams 4, the lower parts 13 of the uprights in the hinges 14 are rotated in the direction that coincides with the rotation of the parts 8 beams 4 in the hinges 6 of the upper power unit 5, at an angle of 180 ^o so that they fit into the upper parts 12 of the uprights 3 (Fig. 11). Then the folded parts 9 of the beams 4 and the parts 12 and 13 of the uprights 3 are rotated in a horizontal position in the hinges 10 so that all these folded parts are joined with the parts 8 of the beams 4, and all the folded parts 8, 9, 12, 13, of the beams 4 are rotated. and racks 3 in the hinges 6 of the upper power unit 5 to their vertical position. The upper power unit 5 is then standing on the ground. After that, put on a folded bag cover 1 and fasten the lock 2, after which the device is ready for transportation and storage. The device is installed in the reverse order. In the case of the number of parts, more than two, constituting the rack 3 and the beam 4, the installation-dismantling of the device is carried out in a similar manner. In this case, either the first folding option is used completely, when the upper parts of the uprights 3 are turned in corner hinges 11 in the direction of rotation of all the other parts of the uprights 3 and beams 4 (rolling), which coincides with the direction of rotation of the parts of the beams 4 and in the hinges 6 of the upper power unit 5, or the second folding option with the elements of the first (rolling the lower parts of the uprights 3 and parts of the beams 4 in the case of their number greater than two).

 In the case of asymmetry of the frame, when not every beam 4 contains hinges 10 separating it into parts, but only beams 4, made elongated and creating asymmetry (Fig. 14, 15), dismantling is carried out in the same way with the rotation of parts of these beams 4 according to the described above any of the two options.

 In the winter version, when the device for the purpose of insulation consists of two structurally identical links 16 and 17 (Fig. 16), the linear dimensions of one of which 16 exceed the linear dimensions of the second 17, the installation and dismantling of the device also includes the installation and placement of pre-assembled , as described above, the links 16 and 17 of one (16) on top of the other (17) of the type of "nesting doll" or removing the assembled link 16 of a larger size, followed by dismantling both links 16 and 17 in the manner described above.

In the multi-link version with a series connection of the links in a line (Fig. 17) or with a parallel connection of several lines (Fig. 18) when dismantling the device, it is unlocked along all the latches 15, then the beams 4 are folded "accordion" (Fig. 19) and with the further approach of the racks 3 to each other around the nodes 5, the parts of the beams 4 are folded and occupy a position in which they are parallel to each other and the racks 3. After that, the lower parts of the racks 3 are folded, turning them 180 ^° in the hinges 14 to a position parallel to each other friend y (Fig. 20), put on the whole package cover 1 and fasten the lock 2.

 When performing the upper power unit 5 in the form of a base 18 with hinges 6 for fastening the beams 4 located on top of it (Fig. 21), the rotation of the beams 4 during installation of the device occurs until the beams 4 lie on the part 19 of the base that protrudes beyond the hinges 6 , which is their focus. Moreover, the profile of the base 18 in its transverse section determines the angle between the beams in the assembled device, which is the value of the angle of the roof slope.

 When the hinges 6 of the upper power unit 5 are located under the base of the upper power unit 5 along its edges (Fig. 22), the beams 4 are rotated during installation until the ends of the beams 4, protruding beyond the hinges to the center of the unit 5, abut against the base surface 18, the profile of which also determines the angle between the beams 4 in the assembled shelter, and therefore the angle of the roof slope. When performing all the hinges 10 of the beams 4 and the hinges 14 of the uprights 3 in the form of a simple channel 20 (Fig. 23, 24), the parts of the uprights 3 and beams 4 rotate around the axes 21 passing through the side walls 22 of the channel 20, and the stop is its groove 23, when part of the racks 3 or beams 4 are located parallel to its surface on the same line.

 In the case when the hinge contains two channels 24 and 25 (Fig. 25), interconnected by means of loops 26, that part 27 of the beam 4 or rack 3, on which loops 26 are fixed, rotates around them and freely fits into the groove during installation the first channel 24 all the way to its bottom. In this case, both parts 27 and 28 are located on the same line.

In the case of the hinge in the form of two plates 29 located on both sides of the parts 27 and 28 of the beam 4 or rack 3, the latter freely rotate on the axles 30 (or together with the axes relative to the plates 29) passing through the ends of the parts 27 and 28 and the plate 29 The emphasis in this case are the plates 31, rigidly connected to the ends of the parts perpendicular to the plates 29 (Fig. 26). When the arrangement of parts 27 and 28 during installation of the device, the plates 31 come into contact with the plates 29, which is the emphasis that does not allow the parts 27 and 28 to rotate through an angle greater than 180 ^o . This design of the hinge can reduce metal consumption and reduce weight.

In the embodiment of the hinges with a pin 32 passing through the middle part of the plate 33 (Fig. 27-29) for folding the rack 3 or beam 4, it is necessary to pull the parts 27 and 28 apart from each other by the voltage of the common longitudinal axis. In this case, the axles 34 are rigidly fixed in parts 27 and 28 in the oblong holes 35 from one edge of each hole to the other, which allows you to undock the parts and raise their end grooves 36 above the locking pin 32, which allows, in turn, to rotate each part 27 and 28 to 90 ^o to a position parallel to each other, i.e. to a folded state. Installation of the device with such hinges is carried out automatically, i.e. by simply turning the folded parts 27 and 28 until their longitudinal axes coincide. In this case, the axes 34 move in the oblong holes 35 and the grooves 36 are closed around the pin 32 under the action of gravity and tension of the awning 7 (Fig. 27, 28).

 In FIG. 30 depicts an example implementation of the latch 15, consisting of two strips 37 and 38, one end of which is pivotally connected to the post 3 and the beam 4 using hinges 39 and 40, and the other ends are pivotally connected to each other by a hinge 41, while on one of the strips there is a stop 42 in the form of a plate located at the end of one of the strips, for example, 37 perpendicular to the plane of the strips 37 and 38, while the hinge 41 is located outside the line connecting the hinges 39, 40, namely it is shifted towards the location of the stop 42. In the folded state beams 4 and racks 3, the latch 15 is located in when folded, so that the strips 37 and 38 form an acute angle between themselves away from the hinge 11. When fixing the frame, the racks 3 are extended and the beams 4 straighten the strips 37 and 38, while the hinge of the latches 15 intersects the line connecting the hinges 39, 40, and they are located behind it in the direction of the hinge 11. In this case, the tent tension tends to fold the strips 39 and 40 in the opposite direction by the hinge 41 towards the hinge 11, which is prevented by the stop 42, thus, the latch 15 is in a fixed state.

 In FIG. 31 depicts an example implementation of a latch 15 in the form of a single bar fixed at one end to a post 3 (or beam 4) by means of a hinge 43, the other end of which is equipped with a hook 44 that engages with a protrusion 45 on the beam 4 (or rack 3).

 In FIG. 32 shows an example of the implementation of the latch 15 in the form of a pin inserted into the hole passing in the hinge 11 both in its part belonging to the rack 3 and in its part belonging to the beam 4.

 In FIG. 33 depicts an example implementation of the latch 15, made in the form of an angular plate 46 and a removable pin 47. In this case, the angular plate 46 is rigidly fixed to the post 3 by a connection 48, 49, and the beam 4 is rotated in the hinge 11 when the pin 47 is removed.

The proposed device is a folding tent shelter in comparison with the known, including the prototype, has the following technical advantages:
- improved performance due to the use of additionally introduced elements connected and interacting with the proposed method, due to which the device has significantly smaller dimensions when folded;
- simple and low laborious installation-dismantling carried out by one person;
- short installation-dismantling time, not exceeding 1 min with an average size of the device;
- wide functionality that allows you to use the device on various soils, asphalt, concrete, etc., wide modifiability that allows you to perform the device of various shapes - with a different number of faces, round, symmetrical, asymmetric, as well as multi-link, installed one on top of the other, connected in a line such as honeycomb structures, etc .;
- high manufacturability and ease of execution, lack of expensive parts and materials;
- greater durability due to the lack of detachable connections and detachable parts, as well as due to the fixed tent.

Sources of information
1. US patent N 1772646, 1930.

2. UK application N 753183, IPC ⁶ A 45 F 1/16, 1954.

Claims (13)

 1. Foldable tent shelter containing the upper power unit, articulated with one of the ends of the beam with the possibility of free rotation in the vertical plane and focusing them in the extreme upper position of the power unit, racks, the upper ends of which are pivotally connected to other ends of the beams and the tent, located on top of the frame, mounted on racks, characterized in that at least one rack and / or one beam each contains at least one hinge that divides them into at least two parts with the possibility of sk of the fitting of the parts, and also latches are introduced, located between the uprights and beams, and all the hinges are made with the possibility of folding in one direction, coinciding with the direction of folding of the beams in the upper power unit, and focusing in the extreme position of the coincidence of the directions of the parts of each of them.  2. Shelter according to claim 1, characterized in that the upper power unit is located asymmetrically with respect to the uprights, and the elongated beams contain at least one hinge that divides it into parts with the possibility of folding and focusing in the extreme position of coincidence of the directions of the parts of the beams containing hinge.  3. Shelter according to any one of claims 1 and 2, characterized in that the upper power unit is made in the form of a base and hinges for attaching the beams located on its lower surface, each beam is fixed in the hinge so that its end protrudes toward the center of the node behind the hinge axis .  4. Shelter according to any one of paragraphs.1 to 3, characterized in that at least one second link is inserted into it, comprising a second upper power unit, second beams connected to it at one end with the possibility of pivoting them in a vertical plane and abutting in the highest position of the power unit, the second struts, the upper ends of which are pivotally connected to the other ends of the beams and the second tent, located on top of the second frame, mounted on the racks, at least one second rack and / or one second beam contains each at least one hinge dividing them into at least two parts with the possibility of folding parts, and also introduced latches located between the second pillars and second beams, and all hinges are made with the possibility of folding in one direction, coinciding with the direction of folding of the beams in the upper power node, and focusing in the extreme position of the coincidence of the directions of the parts of each of them.  5. Shelter according to claim 4, characterized in that the length of all the second pillars and beams exceeds the length of all the first pillars and beams and the dimensions of the second tent exceed the dimensions of the first so that the second link allows the first beams, pillars to fit in like a nesting doll with the upper power unit and the tent with the upper position of the vertical power unit.  6. Shelter according to claim 1 or 2, characterized in that the hinges of the beams and / or racks are made in the form of loops, and the emphasis is formed by the ends of the parts of the beams and / or racks joined in hinges.  7. Shelter according to claim 1 or 2, characterized in that each hinge of the beams and / or racks with emphasis is made in the form of a channel, along the groove of which are located on both sides towards each other the ends of the adjacent parts of the beam and / or rack, and on each Through holes are made through half of the side surfaces of the channel and the corresponding end of the beam and / or rack part through which the axis passes with the possibility of free rotation of this part of the beam and / or strut around it.  8. Shelter according to claim 1 or 2, characterized in that each hinge of beams and / or racks with emphasis is made in the form of loops and a channel, moreover, one movable part of the loops is connected to the end of the channel, in part of the groove length of which from the other end is rigidly fixed one of the adjacent parts of the beam and / or rack, and the other movable part of the hinges is fixed on the other part so that the end of the latter freely enters the channel of the channel from its other end from the side of the hinges attached to it.  9. Shelter according to claim 1 or 2, characterized in that each hinge of the beams and / or racks is made in the form of two plates located on both sides of the beam and / or racks in parallel planes so that one ends of the plates are located on one part of the beam and / or racks, and the other ends on the other part, at each end of the plates and the corresponding part of the beam and / or rack, through holes are made through which the axis passes with the possibility of free rotation of this part relative to the plates.  10. Shelter under item 11, characterized in that the emphasis is made in the form of two second plates, each of which is fixed at the end of each part in the gap between the axis and the end of the beam and / or rack, and are located on one side of these parts in the plane perpendicular to the planes of the first plates.  11. Shelter according to claim 11, characterized in that the emphasis is made in the form of a fixed pin passing through the holes in the first plates so that the ends of the two parts of the beam and / or rack cut into it from opposite sides by cuts made across the ends parallel to the hinge axes , the shape of the cutouts corresponds to half the cross section of the pin, the axis of the hinges are each rigidly fixed in the corresponding part of the beam and / or rack, and the holes at the ends of the plates are oblong.  12. A folding tent shelter containing links, an upper power unit, pivotally connected to it by one of the ends of the beam with the possibility of free rotation in the vertical plane and focusing them in the extreme upper position of the power unit, racks, the upper ends of which are pivotally connected to other ends of the beams and tent, located on top of the frame, mounted on racks, characterized in that the links are connected in series, each pair of adjacent links having two common racks, each of which contains two hinges with the corresponding beams of this pair of links, and the awnings of all links are connected so that they form one common coating for all links.  13. Shelter according to claim 12, characterized in that at least one additional serial connection of links is introduced into it, connected parallel to each other along long edges closely in rows, and each rack at the junction points is common to each pair of serial links of links and contains the corresponding number of articulated joints with beams of adjacent links.

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