JPS5940823Y2 - Self-supporting multi-walled tent with one pillar - Google Patents

Description

[Detailed description of the invention] This invention relates to the improvement of a tent to be carried when climbing, camping, etc. The tent is formed by adding and connecting divided pole pieces that serve as support elements for pitching the tent when setting up the tent. Each pole piece is connected continuously and interconnected to each other using elastic cords such as rubber cords to form a single roof shape, and these roof-shaped skeletons are radially combined to form a large polygonal skeleton. The purpose of the present invention is to provide a multi-walled tent in the form of a polygonal cube, which is easy to handle, such as assembling and folding the support, by hanging and tensioning the multi-walled tent in the form of a polygonal cube, and which has multiple walls and is comfortable to live in. It was devised as

To describe the present invention in detail with reference to one embodiment of the drawings, A and B are plate-shaped skeletons having the same shape and structure, and the roof-shaped skeletons having the same shape and structure are combined in a cross pattern to form a polygonal and polyhedral skeleton. The roof-shaped frames A and B are flexible and have a hollow part 1, and the pole pieces 2, which are pillar elements divided into one fixed length, are shown in FIG. As shown in FIG. 2, they can be connected and connected in a manner that they can be inserted and removed freely by a tapered part 3 for insertion provided at the tip, and are interconnected by an elastic string 4 passed through the hollow part 1. The pole pieces 2 are connected continuously in a tensioned state in the vertical direction.
The pole pieces 2 connected to one leg length connect the top ridges 5 and 10 of the roof-shaped skeletons A and B; 13 and 14.

Further, at both ends of the top edges 5 and 10 of the roof-shaped skeletons A and B, as shown in FIG. 8, 9 and 11, 12, 13,
15, 15' and 16, 1.
6' and a three-pronged join to the top edge 5)
1 s, i s' and the apical edge 10) Each of 16 and 16' has an apical edge 5 in the center.
A top ridge joint hole 17 is provided, into which the tapered portions 3 at both ends of each of the top ridges 6, 7, 8, 9 and 11 are inserted and removably inserted. 12,1
3° 14 are provided with instantaneous joining holes 18 into which the tip tapered portions 3 of 14 can be freely inserted and removed, and the instantaneous joining holes 18 and the top ridge joining hole 1T are in a three-pronged relationship intersecting each other at a constant angle. It is set up in

The three-pronged joints 15 , 15 ′ and 16 , 16 ′ are located at both ends of the top edges 5 and 10 and connect the tip tapered portions 3 of the pillars 6 and 7 and the 10,000 tip tapered portions of the top ridge 5 . Furthermore, the tip tapered portions 3 of each of the three-pronged pillars 8 and 9 and the other tip tapered portion 3 of the top ridge side 5 are opened at a fixed angle so that they can be inserted and removed through the legs. The tip tapered portions 3 of each of the pillars 1112 and the tip tapered portion 3 of one of the top edges 10, and the tip tapered portions 3 of each of the legs 13 and 14 and the other tip tapered portion 3 of the top edge 10. Each leg should be opened at a fixed angle so that it can be inserted and removed freely.

In addition, each of the tapered portions 3 at both ends of the husbands of the top edges 5 and 10 that are inserted through and protrude into the top edge joint holes 17 of the three-pronged joints 15, 15', 16, and 16', include: The canopy poles 19, 20, 21, and 22 for forming the canopy are inserted and removed freely, and the elastic string 4 is inserted into the apex joint hole of the canopy pole 19 and the three-pronged joint 15 as shown in FIG. 17 and top ridge 5 and three-pronged joint 15
1 through the top ridge joint hole 17 and the canopy pole 20.
Also, the instantaneous joint hole 18 of the pedestal 6 and three-prong joint 15 and the pedestal 7 are connected through the elastic string 4, and the instantaneous joint hole 18 of the pedestal 8 and three-prong joint 15' and the pedestal 9 are connected together. The roof-shaped skeleton A is constructed by connecting the elastic strings 4 in a constant tension manner through the elastic strings 4, and the elastic strings 4 are also connected to the top edge joint hole 17 and the top edge side 10 of the canopy pole 21 and the three-pronged joint 16. The three-prong joint 16' is connected through the top ridge joint hole 17 and the canopy pole 22, and the leg pillar 11, the three-prong joint 16O, the leg joint hole 18, and the leg pillar 12 are connected together through the elastic string 4. Also, by connecting the instant joint holes 18 of the pedestal 13 and the three-pronged joint 16' and the pedestal 14 in a constant tension manner through the elastic string 4, a separate roof shape having the same structure and shape as the roof-shaped frame A is created. A floating ring 23 constituting a skeleton B, in which the roof-shaped skeleton B and the roof-shaped skeleton A are combined in a cross shape by intersecting each other at the center of the respective apex edges 5 and 10, and circumferentially diagonal to the intersection point. By attaching it freely, each part of the entire strut is connected as one body, and a polygonal, polyhedral skeleton with polygonal three-dimensional surfaces is constructed.In this example, the bottom surface is A multifaceted three-dimensional space is formed that is octagonal and has a quadrangular upper surface.

Here, the tent body of a similar shape smaller than the shape matching this multi-sided three-dimensional space, that is, the lower surface is an octagon smaller than the bottom surface of the space, and the upper ceiling surface is an octagon smaller than the top surface of the space.
A multi-walled tent C with all 12 sides having a square shape is formed, and it is hung from the intersection of the top ridges 5 and 10 at the center of the ceiling of the multi-walled tent C with a hook 24, and the ceiling surface having a quadrangular shape is suspended. Three-pronged joint 15.15 with each corner hook 24
',16.
, 12, 13, and 14 with hooks 24, and furthermore, the lower ends of the eight pillars are bent inward by utilizing their flexibility, and the bottom ends of the multi-walled tent C are hooked at eight locations. When inserted into the insertion pins 25 provided at the corners, the eight pillars are fixed to the bottom corners of the multi-walled tent C, and at the same time, the repulsive force caused by the pillars being bent inward is applied to the entire polygonal and polyhedral skeleton. Then, as shown in FIG. 8, the top edges 5 and 10 curve upward, and the multi-walled tent C becomes self-supporting with the entire tent being under tension.

In this example, two sets of roof-shaped skeletons A and B are combined in a cross shape, but if three sets of roof-shaped skeletons with the same structure and shape are constructed, a polygonal and polyhedral skeleton with even more wall surfaces can be constructed. I can do it.

The present invention is based on the above, and conventional tents and tent props are often made up of separate pieces of poles that make up the prop, and elastic strings such as rubber cords, which have become popular in recent years, Even if it is a self-supporting tent in which the pole pieces are connected by the pole pieces and there is no need for tensioning, the pole pieces that form the support frame are connected separately with the legs, top ridge support sides, etc. Since the tent is not fully connected with the support joints to form a single unit, when pitching the tent, the pillars and top supports must be assembled using joints, and parts may be lost or lost. When setting up a tent in strong wind, rain, or snow, it is difficult to assemble the tent because the support components are separated, especially when it comes to traditional kamabob-shaped or dome-shaped large tents for several people. This had the disadvantage that it was not easy to set up a tent, especially for people who were inexperienced in setting up a tent.

In this invention, the pole pieces and joints that make up the support of each part are integrally and organically connected by elastic strings such as rubber strings, and the shape of the tent support is changed to the shape of the pole piece by the tensile force of the elastic string. By making it possible to maintain the unfolded state at all times due to the self-cutting action of the pillar, it is possible to assemble the support very easily, and even when folded, each part is connected, so it does not come apart and can be folded into one piece. There is no risk of parts being lost when folded.3 Also, by creating a multi-walled tent with multiple walls, the standing effect of the walls is improved, and the typical large tents such as dome-shaped tents and kamabok-shaped tents can be converted into semicircular tents. Therefore, the corner of the ceiling is reduced to a circular shape, which reduces the pressure of the living space. The sides connecting the corners of the polygons forming the polygonal cube are straight lines as shown in Figure 3, and if the shape of the multi-walled tent is constructed in accordance with the sides of these straight lines, the wall surface will be A polyhedral cube with triangular and modified quadrilateral sides is constructed, and when sewing the tent, the suture line of each side becomes a straight line, making it easier to sew and making it easier to sew than conventional dome-shaped tents, kamabok-shaped tents, and rectangular tents. A multi-walled surface different from the above is obtained, and a large number of entrances and exits can be provided on this multi-walled surface, thereby forming a tent with good ventilation.

[Brief explanation of drawings]

Figure 1 is a perspective view, Figure 2 is a developed view, Figure 3 is a plan view, Figure 4 is a front view, Figure 5 is a perspective view showing how it is used, and Figure 6 is a side view of the pole piece. FIG. 7 is a cross-sectional view of the three-pronged joint, partially cut away to show the inside, and FIG. 8 is a front view showing a change in aspect. A... Roof-shaped affirmative, B... Roof-shaped skeleton, C... Multi-walled tent, 1... Hollow part, 2... Pole piece, 3...
...Tapered portion, 4...Elastic cord, 5...Top ridge, 6
, 7, 8, 9... Pillar, 10... Top ridge, 11.1
2, 13. 14... Pillar, 15, 15', 16
, 16'...Three-prong joint, 17...Top ridge joining hole, 18... Instant joining hole, 19゜20.21.22...
・Hisashi pole, 23... floating ring, 24°°・
Hook, 25...insertion pin.

Claims (1)

[Scope of utility model registration request] Flexible pole pieces 2 are divided into one fixed length and provided with a tapered part 3 for insertion and connection at the tip, and have a hollow part 1 for measuring an elastic string 4. Flexible pole pieces 2 are successively connected at the tapered part 3. The pillars 6°T and 8, 9 have tapered portions 3 at their tips, and the top edge 5 has tapered portions 3 at both ends, and the pillars 6, 7, 8,
9 and the gapper part 3 of the top ridge 5 are penetrated and joined to the top ridge joining hole 1T and the leg joining hole 18 provided in the three-pronged joints 15 and 15, respectively, and further the pillars 6, 7 and the three-pronged joint 15, and the pillars 8, 9 and the three-pronged joint 15' are each connected in a tensioned state through the elastic strings 4 to form one integrally connected roof-shaped skeleton A. In addition, a separate roof-shaped skeleton having the same shape and structure as the roof-shaped skeleton A is constructed, and the apex edge 5 of the roof-shaped frame A is separated from the apex edge of the same roof-shaped frame A. By intersecting radially at the center of the sides and freely fitting the floating ring 23 into the intersection point, a plurality of roof-shaped skeletons are inseparable and form a polygonal polyhedral skeleton. A multi-wall tent C that can be enclosed in an internal space,
Hooks 2 installed on the ceiling and side walls of the multi-wall tens) C
At the same time, the insertion pins 25 provided at the bottom corners of the multi-walled tensile structure forming a polygon are inserted into the lower end of each pillar. A self-supporting multi-walled tent with a one-piece support that can be erected independently by hooking the entire tent to a polygonal frame.