JP6966139B1 - A skeleton structure in which multiple space-forming skeletons are spaced apart - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a skeleton structure capable of collectively connecting skeletons for forming a space capable of forming a divided space while ensuring a distance between adjacent spaces. SOLUTION: Four sets of space-forming skeletons are arranged apart from each other in the shape of a "field", and two adjacent sets of space-forming skeletons are separated from each other in a plan view 4. Arranged so as to form a square space, one of the two sets of space-forming skeletons located at the four corners of the plan-viewing quadrangle of the space formed by the space is the space-forming skeleton. Two pipes between the two struts of the struts and the two struts of the other set of space-forming skeletons, via joints in the space-forming skeleton attached to the upper ends of the struts. A skeleton structure in which a connecting tube, which is a material, is erected so as to form two sides of the square in a plan view, and two adjacent sets of skeletons for forming a space are connected to each other. [Selection diagram] FIG. 13

Description

The present invention relates to a skeleton structure in which a plurality of space-forming skeletons can be arranged apart from each other.

With the spread of the new coronavirus infection (COVID-19), it is being called for to secure a physical distance (social distance). This is because this infectious disease is mainly transmitted by droplet infection, and an attempt is made to secure a predetermined distance between people to reduce the risk of droplet infection.

By the way, the inventors have presented an invention of a skeleton structure in which a plurality of skeletons for forming a space are arranged adjacent to each other and arranged vertically and horizontally (see Patent Document 1). The skeleton for forming each space in this skeleton structure can be surrounded by cloth or vinyl, and a curtain is provided at the part corresponding to the entrance / exit to form a building in which the space separating from the outside is collectively formed.

Buildings that form such a collective space can be temporary examination facilities such as gymnasiums that are temporarily set up indoors or outdoors, or telework rooms that are specially set up on the large floors of buildings, but a relatively large number of people In such a place where it is easy to be crowded, if adjacent spaces are in contact with each other without securing a distance and the entrances and exits are relatively close to each other, it is not preferable for people entering and exiting each space to secure a physical distance. In addition, when a person infected with an infectious disease is in one of the separated spaces, for example, when examining a new corona-infected person, there is no space between the separated spaces, so that they are adjacent to each other. There is a risk that the new coronavirus will be scattered in the space.

Patent Document 1: Japanese Patent No. 6832035

As described above, the conventional skeleton structure capable of collectively forming the divided spaces is not designed to secure a space between the adjacent spaces.
The present invention has been made to solve such a problem, and a framework capable of forming a plurality of spaces separated from the outside is assembled while ensuring a distance between adjacent spaces. A skeleton structure that can be connected in a targeted manner, is easy to connect and separate, uses fewer parts, can be stored compactly even after disassembly, and does not require a large storage space. The challenge is to provide.

In order to solve the above problems, the present invention employs the following means.
[1] Four sets of space-forming skeletons in which the following columns and horizontal beams are connected via joints are arranged in a "field" shape at intervals, and all two adjacent sets of space are formed. The skeletons are arranged so that the distance between the skeletons forms a space of a square in a plan view, and two sets of spaces located at the four corners of the quadrilateral in a plan view of the space formed by the space. Between the two struts of one set of space-forming skeletons of the forming skeletons and the two struts of the other set of space-forming skeletons facing each of the two struts. In the space forming frame attached to the upper ends of the columns, connecting pipes, which are two pipe materials, are erected so as to form two sides of the square in plan view. A skeleton structure in which all two adjacent sets of space-forming skeletons are connected to each other, and four sets of space-forming skeletons are separated and arranged in a "field" shape.
(Record)
A strut made of a pipe material is arranged at a square corner of a square in a plan view, and at the upper end of the strut, a horizontal beam made of a pipe material is erected between the strut and the strut, and the four sides of the square shape are erected. At the lower end of the strut, a horizontal beam made of a pipe material is erected between the strut and the strut to form the three sides of the square, and the strut and the horizontal beam are connected via a joint. The joint is a frame for forming a space, and the joint consists of a joint body and a sub-joint. The joint body has a regular hexahedron block and five legs protruding at right angles from the five surfaces of the block, and the sub-joint Holes are formed at both ends of the pipe material that is a member having pins and constitutes the strut and the cross beam and the legs of the joint body through which the pins of the sub-joint can pass, and at the end of the pipe material of the strut. Of the above five legs of the joint body, the leg protruding in the direction perpendicular to the other four legs is inserted, and the other is inserted at the end of the pipe material of the horizontal beam. One of the four legs is inserted, and the legs and columns of the joint body and the legs and cross beams of the joint body are connected by inserting the pins of the sub-joints into the above holes. The skeleton for forming the space.
[2] Further, among all the two adjacent sets of space-forming skeletons, among the two columns of one set of space-forming skeletons located at the four corners of the square view in a plan view. Between the column located on the central side of the skeleton structure and the column located on the central side of the skeleton structure among the two columns of the other set of space-forming skeletons, the lower ends of the columns. A connecting pipe is erected so as to form one side of the square in a plan view via a joint in the space forming frame attached to the portion, and all two adjacent space forming frames are connected to each other. A skeleton structure in which the four sets of space-forming skeletons according to [1] are separated and arranged in a "field" shape, which is characterized by being connected.
[3] Any of the four sets of space-forming skeletons having a skeleton structure in which the four sets of space-forming skeletons described in [1] or [2] are spaced apart and arranged in a "rice field" shape. With respect to the two adjacent skeletons, two skeletons for forming a space in which the columns and the cross beams are connected via a joint are arranged at intervals, and the former two skeletons and the latter are arranged. The two skeletons of No. 1 formed the same skeleton structure as the skeleton structure in which the four sets of space-forming skeletons described in [1] or [2] were separated and arranged in the shape of a "rice field". A characteristic skeleton structure in which six sets of skeletons for space shaping are arranged at a distance.
[4] Any of the four sets of space-forming skeletons having a skeleton structure in which the four sets of space-forming skeletons described in [1] or [2] are spaced apart and arranged in a "rice field" shape. Four sets having a skeleton structure in which the four sets of space-forming skeletons described in [1] or [2] are further separated from the two adjacent skeletons and arranged in a "rice field" shape. The space-forming skeletons of the above are arranged apart from each other, and two adjacent skeletons of one of the former four space-forming skeletons and one of the latter four skeletons are adjacent to each other. The two sets of skeletons are characterized in that they form the same skeleton structure as the skeleton structure in which the four sets of space-forming skeletons described in [1] or [2] are separated and arranged in the shape of a "rice field". A skeleton structure in which eight sets of spatial forming skeletons are arranged apart from each other.

The skeleton structure of the present invention is attached to a support of a space-forming frame constructed by connecting a support made of a pipe material and a horizontal beam by a joint consisting of a joint body having five legs and a sub-joint. By using one of the five legs of the joint body that is not used to construct the skeleton for space formation, adjacent skeletons for space formation are connected by a connecting pipe. Therefore, it is easy to separate and collectively connect and separate four or more sets of a plurality of space-forming skeletons, and it is used to connect the space-forming skeletons to each other. Since the members are connecting pipes, which are pipe materials that are not bulky, the parts after separation of the skeleton structure can be stored compactly and are wide because only the connecting pipes and sub-joints are added to the parts of the skeleton for space formation. Does not require storage space.

The perspective view of the basic frame in this invention is shown. The plan view of the basic frame of this invention is shown. The pipe material of the support column and the pipe material of the horizontal beam are shown. The perspective view of the joint body is shown. Two embodiments used as subjoints are shown. (A) and (b) are a front view and a side view of a substantially C-shaped clip, respectively, and (c) is a perspective view of a split pin. (A) shows a state in which the pipe material of the horizontal beam is attached to the leg of the joint body. (B) shows a state in which the pipe material of the horizontal beam is connected to the leg portion of the joint body by a substantially C-shaped clip. A perspective view is shown in a state where a support column and a horizontal beam are connected to the legs of the joint body by a sub-joint (substantially C-shaped clip). (A) is the connection state at the upper end of the support, (b) is one of the two types of connection at the lower end of the support, and (c) is the other type of connection at the lower end of the support. One of them is shown respectively. The perspective view of the skeleton structure in which two corner members are attached to the corners formed by the struts and the cross beams at the upper end of the struts of the skeleton structure is shown. (A) shows a perspective view of the entire skeleton structure, and (b) shows an enlarged perspective view of a main part. (A) shows a plan view of a corner material having different lengths at both ends. (B) shows a plan view of a corner material main body member. The gripping member of the corner material is shown. (A) shows a front view. (B) shows a plan view. (A) shows a perspective view of a skeleton structure (framework structure 2D) in which two sets of space-forming skeletons are arranged at intervals and the two skeletons are connected. (B) is a perspective view showing a state in which two sets of space-forming skeletons before the skeleton structure 2D is constructed are separated from each other so that a quadrangular space in a plan view is formed between the two skeletons. Indicated by. In the skeleton structure 2D, three examples (a) to (c) in which the orientation states of the skeleton-shaped skeleton for space formation are different are shown in a perspective view. (A) shows a perspective view of a skeleton structure (framework structure 4D) in which four sets of space-forming skeletons are separated from each other and the intervals are arranged in a "rice field" shape, and the four sets of skeletons are connected. In (b), four sets of space-forming skeletons before the skeleton structure 4D is constructed are separated so that a quadrangular space in a plan view is formed between all adjacent space-forming skeletons. The state of being arranged in is shown in a perspective view. A skeleton structure in which four sets of space-forming skeletons are arranged in the shape of a "field". Similar to the upper end portion thereof, a skeleton structure (framework structure 4D') erected so as to connect connecting pipes to form the four sides of the quadrangle in a plan view is shown in a perspective view. A corner at the lower end of four columns arranged at the corners of a quadrangle in a plan view of the space in the center of the frame structure 4D'in which four sets of space-forming skeletons are arranged in a "field" shape. A perspective view shows a state in which the material is erected between the support column and the horizontal beam. A perspective view shows a skeleton structure in which six sets of skeletons for forming a space, which is one of the embodiments of the present invention, are arranged apart from each other. A perspective view shows a skeleton structure in which six sets of skeletons for forming a space, which is one of the embodiments of the present invention, are arranged apart from each other. A photographic substitute drawing shows a skeleton structure 4D in which a sheet or a curtain is attached to a frame on the side surface of the skeleton for forming four sets of spaces. The curtain is attached to a frame in the shape of a sword.

The skeleton structure of the present invention will be described with reference to the drawings.
The skeleton structure of the present invention has a plurality of sets of skeletons for forming spaces, and as will be described later, there is a space between adjacent skeletons for forming spaces. If a sheet made of cloth or vinyl is attached to the side surface of the space-forming frame or the ceiling frame, the space-forming frame can form a space that separates it from the outside.
Hereinafter, the skeleton for forming this space will be referred to as a "basic skeleton".

First, the basic skeleton will be explained.
As shown in FIG. 1, the basic skeleton 1 is erected between the four columns 2 and the columns 2 and the columns 2 having the same height arranged at the corners of the squares in the plan view. It is provided with seven horizontal beams 3.
The beam usually refers to a material that supports the roof over the pillar, but the horizontal beam refers to a material that is erected between the pillars.

At the upper end of the support column 2 of the basic frame 1, as can be seen from FIG. 2, a horizontal beam 3 is erected between the support column 2 and the support column 2 via a joint 4 described later, and four horizontal beams are installed. 3 forms four sides of a quadrangle in a plan view. In FIG. 2, the support column 2 is hidden under the joint 4. Further, in this figure, the sub-joint is omitted from the joint body and the sub-joint constituting the joint 4.
On the other hand, also at the lower end of the support column 2, a horizontal beam 3 is erected between the support column 2 and the support column 2 via a joint 4, and as can be seen from FIG. 1, the three horizontal beams 3 are quadrangular in a plan view. It forms three sides of.

Therefore, the basic framework 1 is a three rectangular framework formed by two struts and two horizontal beams 3 erected at the upper end and the lower end of the two struts, and two struts. A rectangular frame formed by the above two columns and the horizontal beams 3 erected at the upper ends of the two columns and four horizontal beams 3 erected at the upper ends of the columns 2 are formed. It is possible to form a cubic or rectangular space surrounded by a rectangular frame in a square view.
The above three rectangular frameworks and the ceiling-shaped framework form the side surface of the space formed by the basic framework 1, and the four horizontal beams erected at the upper ends of the above columns 2. The rectangular frame having a four-sided plan view formed by 3 forms the ceiling surface of the space formed by the basic framework 1.

If a sheet made of cloth, vinyl, or the like is attached to the side frame of the space formed by the basic frame 1, a space separating the space from the outside can be formed. Further, if a sheet is attached to the frame of the ceiling surface of the space formed by the basic framework 1, a space with a ceiling that separates the space from the outside can be formed.
This basic skeleton 1 is provided with a frame in the shape of a cloth with two columns 2 and a horizontal beam 3 erected at the upper ends of the two columns 2. If a curtain is attached to the horizontal beam 3 of the) -shaped frame instead of a sheet made of cloth or vinyl, for example, the curtain can be moved closer to one of the columns or spread between the two columns. A (beam) -shaped framework can be used as an entrance / exit to the space formed by the basic framework 1. In addition, when a sheet or curtain is not attached, the doorway can always be open.

The support column 2 and the horizontal beam 3 are made of pipe materials having the same inner diameter and outer diameter. By doing so, the number of types of parts can be reduced.
The columns 2 have the same length, but for the horizontal members 3, at least the horizontal beams erected in parallel with each other must have the same length.
Two holes through which the pins of the sub-joint, which will be described later, can penetrate the pipe material are formed at each end of the pipe material of the support column 2 and the horizontal beam 3. FIG. 3 shows the pipe materials of the support column 2 and the horizontal beam 3. Here, the support column 2 is shown to have the same length as the horizontal beam 3, but the present invention is not limited to this form, and the support column 2 may be longer or shorter than the horizontal beam 3.

The support column 2 and the horizontal beam 3 can be connected by a joint 4, and the horizontal member 3 can be erected between the support column 2 and the support column 2.
The joint 4 is composed of a joint main body 5 and a sub-joint 6, and the joint main body 5 is shown in FIG. 4 and the sub-joint 6 is shown in FIG. 5, respectively.

The joint body 5 includes columnar legs 51 projecting at right angles to each of the six faces of the regular hexahedron block and the regular hexahedron block. The length and outer diameter of these five legs 51 are the same.
In the four leg portions 51 out of the five, the axial center lines of the leg portions 51 are on the same plane, and the axial center lines of the adjacent leg portions form a right angle. The axis center line of the remaining one leg 51 is perpendicular to this plane, and is shown upward in FIG.
Therefore, of the five legs of the joint body 5, one leg (upward leg in FIG. 4) 51 projects in a direction perpendicular to the other four legs 51.
Further, the leg portion 51 is formed with a through hole 52 orthogonal to the axis of the leg portion 51. As will be described later, the pin of the sub joint 6 is inserted into the through hole 52.

The sub-joint 6 is a member provided with a pin 61, and is for preventing the pipe material of the support column 2 and the horizontal beam 3 from coming off from the leg portion 51 of the joint main body 5. 5 (a), (b) and 5 (c) show different embodiments of the subjoint 6.

In the embodiment shown in FIGS. 5 (a) and 5 (b), the substantially C-shaped clip 6 having the grip portion 62 having a substantially C-shaped cross section having the pin 61 grips the pipe material of the support column 2 and the horizontal beam 3. can do. The grip portion 62 has two elastic grip pieces, and after the grip pieces are expanded and attached to the pipe material of the support column 2 or the horizontal beam 3, the two grip pieces are tightened in the closing direction. ing.
Then, the pin 61 protrudes from the central portion of the substantially C-shaped portion to the gripping one side, and the diameter of the pin 61 (the length of the cross section) is the diameter of the through hole 52 formed in the leg portion 51 of the joint body 5 and the support column. It is slightly smaller than the diameter of the through hole formed in the end of the pipe material of 2 and the horizontal beam 3.
The portion of the pin 61 protruding to one side of the grip is slightly longer than the outer diameter of the pipe material of the support column 2 or the horizontal beam 3, and when the substantially C-shaped clip 6 is attached to these pipe materials, the pin 61 is attached. It penetrates the two holes formed in the end of the pipe material, and at the same time penetrates the hole 52 of the joint body 5.

As described above, since the sub-joint 6 is for connecting the leg portion 51 of the joint body 5 so that the pipe material of the support column 2 and the horizontal beam 3 does not come off, the sub-joint 6 is a substantially C type. Instead of the clip, a split pin 6 having a pin 61 as shown in FIG. 5 (c) can also be used.
The split pin 6 is composed of a pin 61 and a head 63, and is composed of two legs on which the pin 61 can be opened. The pins 61, which are the two legs, are passed through the holes of the object, and the legs are fixed so as to open on both sides. The pin 61 of the split pin is inserted so as to penetrate the two holes and the hole 52 formed in the leg portion 51 of the joint body 5, and the two legs of the pin protruding from the pipe material are bent and opened to open the support column 2. The pipe material of the support column 2 and the horizontal beam 3 can be connected to the leg portion 51 of the joint body 5 by following the outer circumference of the pipe material of the horizontal beam 3 and the horizontal beam 3. The length of the pin 61 of the cotter pin must be longer than the outer diameter of the pipe material. Although not shown, a hairpin type split pin can also be used as the sub-joint 6.

Since the sub-joint 6 is a member having a pin 61, the pin can be easily inserted into a hole formed in a support column 2, a horizontal beam 3, or a leg 51 of a joint body 5 without using a tool or easily. The columns 2 and the cross beams 3 can be connected to the legs 51 of the joint body by using various tools, and the basic frame 1 can be easily assembled. On the contrary, when disassembling, it can be easily carried out in the same manner.
In particular, the substantially C-shaped clip 6 pushes the two gripping pieces by hand and inserts the pin 61 into the hole formed in the pipe material of the support column 2 or the horizontal beam 3 and the leg portion 51 of the joint body 5. Therefore, it is possible to connect the pipe material to the joint body 5 without the need for tools.

In the basic skeleton 1, the leg portion 51 is a pipe material of the cross beam 3 on any leg portion of the four columnar leg portions 51 whose axial center lines are on the same plane of the joint main body 5. The cross beam 3 is attached in a state of being inserted into the end portion of the cross beam 3. This state is shown in FIG. 6 (a).
Further, although not shown in FIG. 6, the support column 2 is also not the four leg portions 51 described above, but the remaining one columnar leg portion 51, that is, the shaft of the four leg portions 51 described above. The support column 2 is attached to the leg portion 51 whose axis center line is perpendicular to the plane formed by the center line, with the leg portion 51 inserted into the end of the pipe material of the support column 2. See FIGS. 7 (a) to 7 (c)].
Therefore, the outer diameter of the leg portion 51 of the joint body 5 must be equal to or less than the inner diameter of the pipe material of the support column 2 and the horizontal beam 3. The outer diameter of the leg 51 is made slightly smaller than the inner diameter of the pipe material of the horizontal beam 3 and the support 2 so that the leg 51 can be easily inserted into the end of the pipe material of the horizontal beam 3 and the support 2. It is desirable to have some play so that the leg portion 51 and the pipe material are not in a tight state. In this way, the leg portion 51 of the joint main body 5 and the pipe material of the support column 2 and the horizontal beam 3 can be easily attached or separated.

The sub-joint 6 is attached to the end of the pipe material of the support column 2 or the horizontal beam 3 into which the leg portion 51 of the joint body 5 is inserted, and the leg portion 51 of the joint body 5 is attached to the support column 2 or the horizontal beam 3 from the leg portion 51. There is something to prevent the pipe material from coming off.
In order to attach the pipe material of the support column 2 or the horizontal beam 3 to the leg portion 51 of the joint body 5, first, the leg portion 51 is placed at the end of the pipe material, and the holes (two) and legs formed in the pipe material are formed. The hole 52 formed in the portion 51 is inserted so as to overlap with the hole 52, and then the pin 61 penetrates the two holes formed in the end portion of the pipe material and the hole formed in the leg portion 51 of the joint body 5. Attach and attach as you do.
In this way, the pipe members of the columns 2 and the horizontal beams 3 can be attached so as not to come off from the legs 51 of the joint body 5.
FIG. 6A shows a state in which the joint body 5 is inserted into one of the four leg portions 51 whose axes are on the same plane at the end of the pipe member of the horizontal beam 3. B) shows a state in which a substantially C-shaped clip of the sub-joint 6 is attached to the end of the pipe material of the horizontal beam 3 shown in FIG. 6 (a).

As shown in FIG. 1, a horizontal beam 3 is erected by using four joints 4 at each of the upper end portion and the lower end portion of the support column 2, and a basic frame 1 forming one space is constructed. be able to.
Then, as can be seen from FIGS. 1 and 7A, at the upper end portion of the support column 2, in any of the joint main bodies 5 of the four joints, among the four leg portions 51 whose axis center lines are on the same plane. The horizontal beams 3 are attached to the two legs of the above, and the columns 2 are attached to the legs 51 which are perpendicular to the same plane and project downward.

Further, at the lower end of the support column 2, of the four joint bodies, the two joint bodies 5 have four legs whose axes are coplanar, as shown in FIGS. 1 and 7 (b). The horizontal beams 3 are attached to the two legs 51 of the portions 51, and the columns 2 are attached to the legs 51 which are perpendicular to the same plane and project upward. Then, as shown in FIGS. 1 and 7 (c), in each of the remaining two joint bodies 5, one leg of the four legs 51 whose axis center lines are on the same plane. The horizontal beam 3 is attached to the leg portion 51, and the support column 2 is attached to the leg portion 51 which is perpendicular to the same plane and protrudes upward.
Then, in FIGS. 7 (a) to 7 (c), FIGS. ) Is attached to the sub-joint 6 of the substantially C-shaped clip so that the pipe material of the support column 2 and the horizontal beam 3 does not come off from the joint main body 5. The same applies when the split pin shown in FIG. 5C is used as the sub-joint 6.

In the basic skeleton 1, at the upper part of the support column 2, at any of the four corners of the quadrangle in a plan view, between the support column 2 and the horizontal beam 3 connected by the joint 4, or between the horizontal beam 3 and the horizontal beam 3 By attaching the corner member 7 to the corner portion formed between the beam 3 and the beam 3, the basic frame 1 can be made more solid.
FIG. 8 shows one of the usage examples of the corner material 7 in the basic frame 1. That is, two corner members 7 are attached to one of the corners of the quadrangle in a plan view formed at the upper end of the support 2 of the basic frame 1, and one of the support 2 and the two horizontal beams is attached. A corner member 7 is erected at each corner between the horizontal beam 3a and between the support column 2 and the other horizontal beam 3b.

The corner member 7 is composed of a main body member 71 and a gripping member 72, and gripping members 72 capable of gripping the pipe members of the columns 2 and the horizontal beams 3 are fixedly attached to both tip portions of the main body member 71. The main body member 71 can be manufactured by bending both ends from a pipe material or the like.
At both ends of the main body member 71, the extensions of the axis center lines at both ends must intersect at right angles.
FIG. 9A shows an embodiment of the corner member 7, and FIG. 9B shows an embodiment of the main body member 71 in which the gripping member 72 is removed from the corner member 7 shown in FIG. 9A. Indicated. As the gripping members 72 attached to both ends of the main body member 71, those having the same shape can be used.

FIG. 10 shows an embodiment of the gripping member 72 of the corner member 7. As can be seen from this figure, the gripping member 72 has a substantially C-shaped gripping portion 721 capable of gripping the pipe material of the support column 2 and the horizontal beam 3, and a socket portion 722 into which the end portion of the main body member 71 is inserted. doing. A female screw hole (without a drawing number) into which a screw can be inserted is formed in each of the end portion of the main body member 71 and the socket portion 722, and the gripping member 72 is screwed into the hole. It can be fixed to the main body member 71.

The substantially C-shaped grip portion 721 is made of an elastic material, and the corner member 7 is attached to the pipe material of the support column 2 or the horizontal beam 3 by widening the distance between the grip pieces of the grip portion 721 and pushing it in. be able to. It is desirable that the orientation of the opening of the grip piece of the grip portion 721 is the same at both ends of the corner member 7 [see FIGS. 9 (b) and 10 (a)].

The main body member 71 shown in FIG. 9B has a central portion continuous with both ends and both ends, both ends having a predetermined length, and the extensions of the axis center lines intersect at right angles. , The lengths of both ends are different. By doing so, as shown in FIG. 8, two corner members having the same shape can be simultaneously used for one corner portion of the plan-view quadrangle formed at the upper end portion of the support column 2 of the frame structure 1.
That is, in FIG. 8, in one corner of the quadrangle in the plan view of the basic skeleton 1, two corner members 7 having the same shape but different lengths at both ends are used at the upper ends of the columns 2. There is.

Next, before explaining the embodiment of the present invention, the skeleton structure in which the two basic skeletons are arranged at a distance from each other and the two basic skeletons are connected will be described. Hereinafter, this skeleton structure is referred to as "framework structure 2D".
FIG. 11A shows the skeleton structure 2D. In this figure, the basic skeleton 1 on the left side is referred to as skeleton 1a, and the basic skeleton 1 on the right side arranged at intervals from the skeleton 1a is referred to as skeleton 1b.
In order to form the skeleton structure 2D, as shown in FIG. 8B, the skeleton 1a and the skeleton 1b are arranged so as to be separated from each other so that a quadrangular space in a plan view is formed between the two skeletons. do. Since this space is an interval between the basic skeletons (frames 1a and 1b), such a space will be referred to as an "interval space" below.
As can be seen from FIG. 8B, two struts 2 of the skeleton 1a and two struts 2 of the skeleton 1b are arranged at the four corners of the quadrangle in the plan view of the space. However, in a quadrangular space in a plan view, between the two struts 2 in the skeleton 1a and between the two struts 2 in the skeleton 1b, at the upper end of the struts 2, a horizontal beam is provided. Since 3 has already been erected, in the space shown in FIG. 8B, at the upper end of the support column 2, two of the four sides of the quadrangle in a plan view are lateral to the basic skeletons 1a and 1b. It is formed by a bridge 3.

Then, as described below, the skeleton 1a and the skeleton 1b are connected by erection of the connecting pipe 8 between the struts of the two pairs of skeletons 1a and the struts of the skeleton 1b at the upper end of the struts 2. can do.
The connecting pipe 8 is a pipe material having the same inner diameter and outer diameter as the support column 2 and the horizontal beam 3, and at each end of both ends, like the support column 2 and the horizontal beam 3, the pin 61 of the sub joint 6 is used. Is formed with two holes through which the pipe material can be penetrated (see FIG. 3).
Therefore, the connecting pipe 8 can be erected between the two columns 2 via the joint 4 in the same manner as the cross beam 3, and the length of the connecting pipe 8 allows two sets of basic skeletons (ie, skeletons). The distance between 1a and 1b) is determined.

As can be seen from FIG. 7A, in the corner portion of the quadrangle in the plan view in the basic frame 1, at the upper end portion of the support column 2, the support column 2 and the horizontal beam 3 have five leg portions 51. However, since two of the five legs 51 are not used in the basic skeleton 1, by using one of the unused legs 51, a connecting pipe can be used. 8 allows the skeleton 1a and the skeleton 1b to be connected.
That is, there are two pairs of opposing struts (struts 2 of the skeleton 1a and struts 2 of the skeleton 1b) between the skeleton 1a and the skeleton 1b in which the space is formed. Also, the joint body 5 attached to the upper end of the support column 2 of the frame 1a and the joint body 5 attached to the upper end of the support column 2 of the frame 1b have leg portions 51 that face each other and are not used. Therefore, the skeleton 1a and the skeleton 1b are erected by connecting the connecting pipe 8 to the unused leg portions 51 facing each other and erection of the joint body 5 of the skeleton 1a and the joint body 5 of the skeleton 1b. It can be connected via the joint 4.

Specifically, the joint body 5 of the skeleton 1a and the joint body 5 of the skeleton 1b facing each other and unused legs 51 are inserted into both ends of the connecting pipe 8 to form the sub-joint 6. When attached, the pin 61 can be connected through the hole of the connecting pipe and the hole 52 of the leg portion so that the connecting pipe 8 does not come off from the leg portion 51. This work is the same as connecting the pipe material of the horizontal beam 3 to the leg portion 51 of the joint body 5, and can be performed without using a tool or by using a simple tool.
In this way, as shown in FIG. 11A, the skeleton 1a and the skeleton 1b can be connected by two connecting pipes 8.

The skeleton 1a and the skeleton 1b are connected by two connecting pipes 8 at the upper end of the support column 2, and the connecting pipes 8 are erected on two sides of a quadrangle in a plan view formed between the two skeletons. Therefore, the two basic skeletons of the skeleton 1a and the skeleton 1b can be connected and arranged side by side.
In this way, the skeleton structure 2D can be constructed by arranging them side by side at intervals between the two basic skeletons.

In the skeleton structure 2D of FIG. 11A, a space separated from the outside is formed by attaching a sheet or curtain made of cloth or vinyl to the side surface of the space formed by each of the skeleton 1a and the skeleton 1b, and further to the ceiling surface. Therefore, two sets of basic skeletons (framework 1a and skeleton 1b) can be arranged with a space of a quadrangle in a plan view.

In the skeleton structure 2D in FIG. 11 (a), the skeleton-shaped skeletons in each of the basic skeletons face in the same direction, but as shown in FIGS. 12 (a) to 12 (c), they face each other. It can also be oriented in the opposite direction, and the skeleton 1a or skeleton 1b can be oriented in the spacing space formed between the skeleton 1a and the skeleton 1b.
As already described, the skeleton-shaped framework in the basic skeleton 1 can serve as an entrance / exit to the space formed by the basic skeleton 1.

Next, using four sets of the basic skeletons 1 which are the above-mentioned skeletons for forming a space, the four sets of basic skeletons are arranged apart in a "rice field" shape and all adjacent to each other. An embodiment of the present invention will be described in which two sets of basic skeletons are arranged so that the distance between them forms a quadrangular space in a plan view. The skeleton structure of this embodiment is shown in FIG. 13 (a). Hereinafter, the skeleton structure of this embodiment is referred to as "framework structure 4D".

As shown in FIGS. 13 (a) and 13 (b), the four basic skeletons 1 used in the skeleton structure 4D are referred to as "framework 1a" to "framework 1d" in the clockwise direction, respectively.
To form the skeleton structure 4D, as shown in FIG. 13 (b), the four basic skeletons are arranged apart in a "rice field" shape, and between all the adjacent basic skeletons. Arrange so that a quadrangular space is formed in a plan view. That is, a quadrangular space is formed between the skeleton 1a and the skeleton 1b, between the skeleton 1b and the skeleton 1c, between the skeleton 1c and the skeleton 1d, and between the skeleton 1d and the skeleton 1a. Has been done.

As can be seen from FIG. 13B, the arrangement of all adjacent basic skeletons is the arrangement of the two basic skeletons 1 before the two basic skeletons 1 form the skeleton structure 2D. That is, it is the same as that shown in FIG. 11 (b). That is, the skeleton 1a and skeleton 1b, the skeleton 1b and skeleton 1c, the skeleton 1c and skeleton 1d, and the skeleton 1d and skeleton 1a are all two basic skeletons before the two basic skeletons 1 form the skeleton structure 2D. Same as placement.
Therefore, for the adjacent basic skeletons, for example, in the skeleton 1a and the skeleton 1b, between the struts 2 of the two pairs of skeletons 1a and the struts 2 of the skeleton 1b, as in the case of constructing the skeleton structure 2D. By erection of the connecting pipe 8 at the upper end of the support column 2, the skeleton 1a and the skeleton 1b can be connected by the two connecting pipes 8. Then, in the skeleton 1b and skeleton 1c, the skeleton 1c and skeleton 1d, and the skeleton 1d and skeleton 1a, two connecting pipes 8 can be erected in the same manner to connect the two basic skeletons to each other.

In the construction of the skeleton structure 4D, as in the skeleton structure 2D, the struts facing each other (for example, the struts 2 of the skeleton 1a and the struts of the skeleton 1b) are located between the two basic skeletons in which the space is formed. There are two pairs of 2), and in any of these two pairs, the upper end of the joint body 5 attached to the upper end of the support 2 of the one basic frame 1 and the upper end of the support 2 of the other basic 1 frame. Since the joint bodies 5 attached to the portions have legs 51 that are opposed to each other and are not used [see FIG. 7 (a)], the joint body 5 of the basic frame of one set and the other of the joint bodies 5 By connecting the connecting pipes 8 to the unused legs 51 facing each other and erection of the joint body 5 of the basic frame of the set, both basics are connected via the joint 4 as in the frame structure 2D. The skeletons can be connected to each other.
In this way, two sets of adjacent basic skeletons 1 can be connected to each other by two connecting pipes 8. Then, the skeleton structure 4D can be constructed by connecting all two adjacent basic skeletons 1 with two connecting pipes 8.
In the skeleton structure 4D in which the four basic skeletons are arranged, a space (interval space) having the same spacing as the skeleton structure 2D is formed between all two adjacent basic skeletons.

In the skeleton structure 4D, as in the skeleton structure 2D, two adjacent basic skeletons are connected by two connecting pipes 8 and formed between the two basic skeletons at the upper end of the support column 2. Connecting pipes 8 will be erected on two of the four sides of the quadrangle in the plan view of the space, and all two adjacent basic skeletons, that is, skeleton 1a and skeleton 1b, skeleton 1b and skeleton 1c , The skeleton 1c and the skeleton 1d and the skeleton 1d and the skeleton 1a can be connected and arranged. A horizontal beam 3 is erected on the remaining two sides of the four sides of the quadrangle in the plan view of the space formed between the two basic frames.

As can be seen from FIGS. 13 (a) and 13 (b), in the skeleton structure 4D, four sets of basic skeletons 1 arranged in the shape of a "rice field" are arranged at a distance from each other. A character-shaped space is formed, and a quadrangular space in a plan view is also formed at the center of the four basic frames arranged in the shape of a "rice field". One support 2 is provided from each of the four basic frames 1 at the corner of the quadrangle in the plan view of the space at the center of the four basic frames, and the four columns 2 are arranged. There is. A connecting pipe 8 is erected at the upper ends of the four columns 2, forming the four sides of the above-mentioned quadrangle in a plan view.

By attaching a sheet or curtain made of cloth or vinyl to the side surface of each frame of the four basic frames 1 constituting the frame structure 4D, and further to the ceiling surface, it is possible to form a space separated from the four exteriors. can. As already described, the skeleton-shaped framework in the basic skeleton 1 can be used as an entrance / exit to the space formed by the basic skeleton 1.
FIG. 18 shows a skeleton structure 4D in which a sheet and a curtain are attached to the side surfaces of the four basic skeletons 1. The curtain is attached to the basic skeleton-shaped framework, and the seats are attached to the other side frameworks. In FIG. 18, the curtains of the two sets of basic skeleton 1 are open, but the curtains of the other two sets of basic skeleton 1 are closed.

In the skeleton structure 4D, the four basic skeletons arranged in the shape of a "rice field" are arranged apart from each other, and the space in which the cruciform in a plan view is arranged can be used as a passage or a material storage place. As can be seen from FIG. 13 (a), it is erected at the lower end of the support column 2 at the corner of the plan view quadrangle at the center of the four basic skeletons 1 arranged in the shape of a "field" of the skeleton structure 4D. Since there is no connecting pipe 8 to be connected, it is convenient to use the space of the cruciform in a plan view as a passage.
Comparing FIG. 13 (a) and FIG. 18, in FIG. 13 (a), the width of the interval space of the plan view cruciform is drawn larger than that in FIG. 18, which is shown in FIG. 13 (a). This is to clearly show the arrangement of the support column 2, the horizontal beam 3, and the connecting pipe 8.

FIG. 14 shows four columns arranged at the corners of a quadrangle in a plan view of the space at the center of the four basic skeletons 1 arranged in the shape of the above-mentioned “field” in the skeleton structure 4D. Similar to the upper end portion, the skeleton structure in which the connecting pipe 8 is connected to form four sides of a quadrangle in a plan view is shown not only on the upper end portion but also on the lower end portion. Hereinafter, this skeleton structure will be referred to as "framework structure 4D'".
In the skeleton structure 4D', two of the basic skeletons of one set located at the four corners of the planar view quadrangle formed between all the two adjacent sets of basic skeletons described above. On the two struts of the stanchion and the other set of basic skeletons facing each of the two struts, on the central side of the skeleton structure of the two struts of the one set of basic skeletons. Between the struts 2 located and the struts 2 located on the central side of the skeleton structure of the two struts of the other set of basic skeletons facing the struts, not only the upper ends of the struts Also at the lower end, as with the upper ends of the columns, the connecting pipes 8 are connected to each other through the mounted joints 4, that is, the joint bodies 5 facing each other and the unused legs 51, in a plane of space. They are erected and connected so as to form one side of a rectangular shape.

In the skeleton structure 4D', the four basic skeletons arranged in the shape of a "field" are flat on both the upper end and the lower end of the four columns arranged at the corners of the quadrangle in a plan view. Since the connecting pipe 8 is erected so as to form the four sides of the visual quadrangle, the skeleton structure can be made more rigid than the skeleton structure 4D.
The space of the four basic skeletons arranged in the shape of a "field" in the skeleton structure 4D'can be used as a passage, a material storage place, etc. However, a connecting pipe 8 is erected at the lower end of the four columns 2 arranged at the corners of the square in the plan view at the center of the four basic frames 1 arranged in the shape of a "field". Therefore, when using it as a passage, the connecting pipe 8 obstructs the passage, so it is desirable to take measures such as laying a mat.

In the skeleton structure 4D shown in FIG. 13 (a), the skeleton-shaped frameworks in the respective basic skeletons are oriented in the same direction in the skeleton 1a and the skeleton 1b, and in the skeleton 1c and the skeleton 1d, respectively, and the former The two basic skeletons 1 and the latter two basic skeletons 1 face in opposite directions, but are not limited to this, as in the skeleton structure 2D (see FIG. 12). Although not shown in FIG. 13 (a), four sets of basic skeleton-shaped frameworks may face the above-mentioned plane-viewing cruciform spacing space.
Regarding the orientation of the frame in the basic frame, the frame structure 4D'is the same as the frame structure 4D.
As already described, the skeleton-shaped skeleton in the basic skeleton can be used as a gateway to the space formed by the basic skeleton.

In the skeleton structure 4D', each of the four stanchions 2 arranged at the corners of the quadrangle in a plan view formed at the center of the four basic skeletons 1 arranged in the shape of a "field". As shown in FIG. 15, when the corner member 7 is attached to the corner portion formed by the support column 2 and the horizontal beam erected at the lower end portion of the support column, the skeleton structure 4D'is further solidified. Can be.

Specific examples of the dimensions of the frame structure 4D and 4D'are as follows, but of course, the dimensions are not limited to these.
・ Basic skeleton (frame for space formation): length 2m x width 2m x height 2m
・ Width of the space between plane-viewing crosses: 0.5 to 1 m
Further, the plan-view shape of each frame in the four basic frames need not be the same as long as the lengths of the cross beams forming the width of the adjacent basic frames are the same.
Further, the width of the space between the cruciforms in a plan view does not have to be the same in the intersecting direction, and may be different. The width of the interval space can be easily adjusted by changing the length of the connecting pipe 8.

In the skeleton structure 4D and 4D', 4 sets of basic skeletons are formed, and 2 sets of skeleton structures 2D are arranged and connected at a distance to construct a skeleton structure consisting of 6 sets of basic skeletons. can do.
That is, the two connected basic skeletons of the skeleton structure 2D are further separated from the two adjacent skeletons of any one of the four basic skeletons of the skeleton structure 4D or the skeleton structure 4D'. The two skeletons in the former skeleton structure 4D or skeleton structure 4D'and the two skeletons in the latter skeleton structure 2D are connected by a connecting pipe to form a skeleton structure 4D or skeleton structure 4D'. The same structure can be constructed to form a skeleton structure in which six basic skeletons are arranged at a distance. FIG. 16 shows a skeleton structure including six basic skeletons (frames 1a to 1f) constructed in this way.

Also, for two adjacent skeletons of any of the four basic skeletons of skeleton structure 4D or skeleton structure 4D', one of yet another skeleton structure 4D or 4D' is adjacent. The basic skeletons in which the two skeletons are connected are arranged apart from each other, and the former two skeletons and the latter two skeletons are connected by a connecting pipe to be the same as the skeleton structure 4D or the skeleton structure 4D'. It is possible to construct a skeleton structure in which eight sets of skeletons for space shaping are arranged apart from each other. FIG. 17 shows a skeleton structure including eight sets of basic skeletons (frames 1a to 1h) constructed in this way.

As described above, in the skeleton structure of the present invention, four, six, or eight basic skeletons (frames for space formation) are connected by a connecting pipe via a joint used for the basic skeleton. In the same way, it is possible to construct a skeleton structure having a basic skeleton of 10, 12, 14 ...
Since the skeleton structure of the present invention collectively connects four or more basic skeletons (frames for forming a space) apart from each other, it can be installed in a more stable state.
In addition, since the basic skeleton can be stored compactly after disassembly, and the main component connecting the basic skeleton is only the connecting pipe, the skeleton structure of the present invention can be stored compactly even after disassembly. It can be done and does not require a large storage space.

1: Space formation skeleton (basic skeleton)
2: Support column 3: Horizontal beam 4: Joint 5: Joint body 51: Leg 52: Hole formed in the leg 6: Sub joint (substantially C-shaped clip, split pin)
61: Pin 62: Gripping part 63: Head 7: Corner material 71: Main body member 72: Gripping member 721: Gripping part 722: Socket part 8: Connecting pipe

Claims (4)

The space-forming skeletons in which the following columns and horizontal beams are connected via joints are arranged in a "rice field" shape with four sets separated from each other, and all two adjacent space-forming skeletons are arranged. Arrange them so that the distance between the skeletons forms a quadrangular space in a plan view.
The two columns of the space-forming skeleton of one of the two sets of space-forming skeletons located at the four corners of the planar view of the space formed by the space and the two struts of the space-forming skeleton. Two pipes between the two struts of the other set of space-forming skeletons facing each of the struts, via joints in the space-forming skeleton attached to the upper ends of the struts. Four sets of space formation, characterized in that a connecting pipe, which is a material, is erected so as to form two sides of the square in a plan view, and all two adjacent sets of space-forming frames are connected to each other. A skeleton structure in which the skeletons for the purpose are separated and arranged in the shape of a "field".
(Record)
Supports made of pipe material are arranged at the corners of the quadrangle in a plan view.
At the upper end of the column, a horizontal beam made of pipe material is erected between the columns to form the four sides of the quadrangle, and at the lower end of the column, from the pipe material between the columns. A horizontal beam is erected to form the three sides of the quadrangle.
A skeleton for forming a space in which a strut and a horizontal beam are connected via a joint. The joint consists of a joint body and a sub-joint, and the joint body is a regular hexahedron block and a right angle from each of the five sides of the block. It has five protruding legs, and the sub-joint is a member with pins.
Holes are formed in both ends of the pipe material that constitutes the columns and the cross beams and the legs of the joint body through which the pins of the sub-joint can pass.
Of the above five legs of the joint body, the legs protruding in the direction perpendicular to the other four legs are inserted into the ends of the pipe members of the columns, and the pipe members of the horizontal beams are inserted. The leg of any of the other four legs is inserted into the end of the
The legs and columns of the joint body and the legs and cross beams of the joint body are skeletons for space formation that are connected by inserting the pins of the sub-joint into the above holes. Further, in all the two adjacent sets of space-forming skeletons, the skeleton of the two struts of one set of space-forming skeletons located at the four corners of the plan-view quadrangle. Attached to the lower end of each of the columns between the column located on the center side of the structure and the column located on the center side of the frame structure of the two columns of the other set of space-forming skeletons. A connecting pipe was erected so as to form one side of the square in a plan view through a joint in the space-forming skeleton, and all two adjacent space-forming skeletons were connected to each other. The skeleton structure according to claim 1, wherein the four sets of skeletons for forming a space are separated and arranged in a "field" shape. Adjacent 2 of any of the four sets of space-forming skeletons having a skeleton structure in which the four sets of space-forming skeletons according to claim 1 or 2 are spaced apart and arranged in a "field" shape. Two sets of space-forming skeletons in which the columns and horizontal beams are connected via joints are arranged separately from the skeletons of the skeletons, and the former two skeletons and the latter two skeletons are arranged. The six sets of space-forming skeletons according to claim 1 or 2 are separated from each other to form the same skeleton structure as the skeleton structure arranged in the shape of a "rice field". A skeleton structure in which the skeletons for space shaping are arranged apart from each other. Adjacent 2 of any of the four sets of space-forming skeletons having a skeleton structure in which the four sets of space-forming skeletons according to claim 1 or 2 are spaced apart and arranged in a "field" shape. With respect to the skeleton of the skeleton, four sets of skeletons for space formation having a skeleton structure in which the four sets of skeletons for space formation according to claim 1 or 2 are separated and arranged in a "field" shape are provided. Arranged at a distance, two adjacent skeletons of one of the former four skeletons for space formation and two adjacent skeletons of any of the latter four skeletons. Eight sets of space forming skeletons, characterized in that the same skeleton structure as the skeleton structure in which the four sets of space forming skeletons according to claim 1 or 2 are separated and arranged in a "field" shape is formed. A skeleton structure in which the skeletons are arranged apart from each other.

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