JPH0336344A - Movable partition wall - Google Patents

Abstract

PURPOSE:To firmly connect a plurality of panels, which concentrate in one place at various angles, so as to improve the rigidity of a wall total unit by connecting a plurality of pillars to a relay member and each panel to each corresponding pillar. CONSTITUTION:A plurality of pillars 1, 1, pipe-shaped relay member 2 having a plurality of recessed cavity grooves, engaged with a one half part of these pillars, in the external surface and a plurality of sheets of panels 3, 3 having a recessed cavity groove, engaged with the other half part of the pillars 1, 1, in the connection surface are provided. Each pillar 1, 1 is connected to the relay member 2 by a relay member connecting means, and each panel 3, 3 is connected to each corresponding pillar 1, 1 by a panel connecting means. As this relay member 2, a material is used with the recessed cavity groove provided in four and three or two surfaces in a different direction of 90 deg., in one or two surfaces in a different direction of 120 deg. and in two surfaces in a different direction of 180 deg., respectively as the specific angle.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention is a movable wall that is installed on the floor with its upper end open, and is called a low partition and is used for simple partitions in offices and the like. This relates to movable partition walls.

[Prior Art] Conventionally, as this type of movable partition wall, for example, as shown in Japanese Patent Application No. 62-59222 filed earlier, a prismatic pipe-shaped column and one half of the column on the joint surface are used. It is known that a panel is provided with a panel having a recessed groove that can be held together, and a plurality of panels can be sequentially joined via the pillar. Specifically, an engagement hole is provided on the left and right joint surfaces of each column, and an engagement claw is provided at the bottom of the recessed groove of the panel, and the engagement claw is engaged with the retention hole. The panels are connected to the pillars by connecting the panels to the pillars. Hook holes are drilled vertically at the center of the front and rear surfaces of each column at intervals, and these hook holes are exposed to the outside through joints formed between adjacent panels. There is.

A shelf board, a desk top plate, etc. can be hung on these hook holes.

[Problems to be Solved by the Invention] By the way, with such a configuration, the panels may be arranged so as to bend toward each other (hereinafter referred to as "two-way arrangement"), or may be arranged so as to branch in three directions (hereinafter referred to as "two-way arrangement"). (hereinafter referred to as "3-way arrangement") or in a four-way branch arrangement (hereinafter referred to as "4-way arrangement"), each company that gathers at the intersection is placed on a plate-shaped bracket. etc., so that they are connected at predetermined intervals. Then, that part is hidden with a cover made of synthetic resin or the like. Therefore, it is difficult to accurately position and connect the pillars that gather at the intersection, and it is also difficult to increase the joint strength. Therefore, there are problems in that due to dimensional errors, it becomes difficult to use the hook holes at the intersection joints, and the rigidity of the entire wall tends to decrease due to insufficient strength at the intersections.

The present invention aims to solve such problems.

[Means for Solving the Problems] The present invention adopts the following configuration in order to remotely achieve the above objects.

That is, the movable partition wall according to the present invention includes a plurality of pillars, a pipe-shaped relay member having a plurality of recessed grooves on the outer surface that engage with one half of each of the pillars, and a joint. a plurality of panels each having a concave groove on a surface that engages with the other half of the column; a relay member joining means for bonding each panel to the relay member; It is characterized by comprising panel joining means for joining.

In order to reliably connect the pillar and the relay member with a simple structure, the relay member joining means is screwed into a screw hole provided inside the thickness of the relay part and the screw hole that penetrates the pillar. It is preferable that the bolt be equipped with a bolt.

To reliably bond the panel to the plate with a simple configuration,
It is preferable that the panel joining means is provided with an engaging hole provided in the hole and an engaging claw provided in the panel and extending downward.

If you want to particularly strengthen the connection between the column and the panel, attach a tightening tool to the upper end of the panel, provide a nut near the upper end of the pillar, and screw it through the tightening member and into the nut. Preferably, the attached bolt draws the column relatively toward the fastener. At this time, if the columns and panels adjacent to each other via the relay member have the same height, those panels may be tightened to the corresponding columns using a common tightening tool. On the other hand, if the columns and panels adjacent to each other via the relay member have different heights, each panel may be tightened to the corresponding column using a different tightening tool.

Specific embodiments of the relay member include one in which concave grooves are provided on each of four sides oriented at 90 degrees, one in which concave grooves are provided in three sides in different directions at 90 degrees, and 90'.
A type with concave grooves on two sides facing different directions,
A recessed groove is provided on two different sides facing 180°, a recessed groove is provided on three different faces oriented 1200°, or a recessed groove is provided on two different faces oriented 120°. There are things etc.

In order to make the relay member particularly lightweight and rigid, it is preferable to construct the relay member from an extruded aluminum material.

Specific joining modes of the panels include the following.

When joining four panels of the same height, a relay member is used in which concave grooves are provided on four different sides facing 90''.

When applying 3 tall panels and 1 short panel, these panels should be placed in 4 different 90' orientations.
LIJ with concave grooves on each surface! l! At the same time, the upper parts of the joint surfaces of the three tall panels are joined together through relay members each having recessed grooves on three sides facing 90 degrees.

Two tall orthogonal panels and two short orthogonal panels
If applied to 9 panels, these panels
At the same time, the two high-sound panels are connected through a relay member having grooves on four sides facing different 0 degrees, and grooves are formed on two sides facing 90 degrees at different angles. They are joined via a provided relay member.

When applied to two tall panels that are to be butted flush and two short panels that are to be butted flush, these panels should be fitted with recessed grooves on four different 90" sides. The two tall panels are joined together via a relay member provided, and the upper parts of the joint surfaces of the two tall panels are joined via relay members each having recessed grooves provided on two sides oriented at 90 degrees.

When applied to one tall panel and three mutually orthogonal short panels, these panels
A pipe-shaped edge member having a concave groove on one side is attached to the upper part of the joint surface of the tall panel. Keep it on.

When applying the present invention to three panels of the same height that are orthogonal to each other, these panels are joined via relay members each having recessed grooves on three different sides facing 90''.

When applying to two tall panels that are orthogonal to each other and one short panel, these panels are connected via a relay member that has recessed grooves on three different sides facing 90". At the same time, the upper portions of the joint surfaces of the two tall panels are joined via relay members each having a concave groove provided on two different sides facing 90''.

When applied to two tall panels and one short panel that are to butt flush, these panels are
They are joined via a relay member that has recessed grooves on three sides with different 0° orientations, and recessed grooves are provided on two different sides with 90' orientations between the tops of the joining surfaces of the two front high panels. They are joined via a provided relay member.

When applied to one tall panel and two short panels that are to butt together, the panels should be 9
A pipe-shaped edge having a concave groove on one side is connected to the upper part of the joint surface of the tall panel by connecting the tall panel through a relay member having concave grooves on three sides with different 0° directions. Attach the parts.

When applied to one tall panel and two mutually orthogonal short panels, the panels should be
A pipe-shaped edge member is joined via a relay member having recessed grooves on three sides in different directions, and has a recessed groove on one side on the upper part of the joint surface of the tall panel. Attach it.

When applying the present invention to three panels of the same height arranged at equal angular intervals in three ways, these panels are joined via relay members each having recessed grooves on three different sides facing 120'.

When applied to two tall panels and one short panel that are to butt together at a 120° angle, these panels should be provided with recessed grooves on three different sides facing 120°. In addition to joining via a relay member consisting of
The upper parts of the joint surfaces of the two tall panels are 1200
They are joined via a relay member having concave grooves on two faces facing different directions.

When applied to one tall panel and two short panels that are to butt together at a 120° angle, these panels should be provided with recessed grooves on three different sides facing 120°. In addition to joining via a relay member provided, a pipe-shaped edge member having a recessed groove on one side is attached to the upper part of the joint surface of the tall panel.

When applying the present invention to two panels of the same height arranged in two ways at right angles, these panels are joined via a relay member each having a concave groove on two different sides oriented at 90°.

When applying to a tall panel and a short panel that are arranged in two ways at right angles, these panels can be connected via relay members each having recessed grooves on two 90° different sides. At the same time, a pipe-shaped edge member having a concave groove on one side is attached to the upper part of the joint surface of the tall panel.

When applied to two panels of the same height arranged two ways at a 120' angle, these panels are
20' are joined via a relay member having concave grooves provided on two faces facing different directions.

When applying to a tall bamboo panel and a short panel that are arranged in two ways at a 120° angle, a relay structure is used in which these panels are provided with concave grooves on two different sides facing 120°. A pipe-shaped edge member having a concave groove on one side is attached to the upper part of the joint surface of the tall panel.

When applied to a tall panel and a short panel that are to be butted flush, these panels are joined via a relay member provided with concave grooves on two different 180' sides. At the same time, a pipe-shaped edge member having a recessed groove on one side is attached to the upper part of the joint surface of the tall panel.

[Function] With such a configuration, a plurality of pillars respectively joined to a plurality of panels gathered at one place are engaged and held in respective recessed grooves of a common relay member. Therefore, the columns can be accurately positioned with respect to each other, and the positioned state can be easily maintained over a long period of time. Moreover, since the relay member is pipe-shaped,
It is possible to exhibit high strength against bending and torsion. Therefore, a plurality of panels assembled in one place can be firmly connected via the relay member, and the entire wall can be made highly rigid.

Also, when joining panels of different heights, if you use different types of relay members as described above, for example, you can match the relay members to the height of the tall panel,
Compared to the case where a blinding cover is attached to the top of the recessed groove that engages the column on the lower panel side, the degree of freedom in the shape design of the end treatment part can be increased, and the appearance of that part can be improved. It becomes easier to improve.

[Example 1] An example of the present invention will be described below with reference to FIGS. 1 to 11.

This embodiment is for a four-way arrangement as shown in FIGS. A relay member 2 having a concave groove 21 on its outer surface, a plurality of panels 3 having a concave groove 32a on a joint surface 3a that engages with the other half of the plate 1, and each plate 1. It comprises a relay member coupling means 4 for coupling the relay member 2, and a panel coupling means 5 for coupling each panel 3 to the corresponding column 1.

As shown in FIGS. 3 and 4, the shaft 1 is shaped like a rectangular pipe with an adjuster 11 at its lower end, and has a plurality of pairs of engagement holes 12 vertically arranged on its left and right joint surfaces 1a and 1b. The holes are drilled at intervals of . The pair of engagement holes 12 are the third
As shown in the drawings and FIG. 9, it is a slit-shaped member having a slightly narrower lower end and extending vertically, and is bored with the inner edges 12a parallel to each other.

The relay member 2 is a pipe-shaped member having concave grooves 21 provided on each of four sides oriented at 90 degrees. Specifically, it comprises four outer walls 22 with different 90'' orientations, four inner walls 23 with different 90° orientations, and an intermediate wall 24 connecting these inner walls 23 and outer walls 22. , 4 above
The inner walls 23 constitute a pipe structure. Each of the recessed grooves 21 is a fold 111 provided at the opening edge of the outer wall 22.
．． l wall 22a and a protruding wall 2 protruding from the intermediate wall 24.
4a and a corresponding inner wall 23,
At the center of each inner wall 23, there is a thick wall portion 2 that protrudes toward the inner surface.
3a is formed. These outer wall 22, inner wall 23, intermediate wall 24, bent wall 22a, and protruding wall 24a are integrally made of aluminum by extrusion molding. This relay member 2 and the four dowels 1, each half of which is fitted into each concave groove 21 of the relay member 2, are connected by the relay member joining means 4, respectively. Relay member joining means 4
As shown in FIG. 6, the thick portion 23 of the relay member 2
The bolts 42 are provided with a screw hole 41 provided in a and a bolt 42 that passes through the column 1 and is screwed into the screw hole 41, and a plurality of sets are provided at intervals vertically.

As shown in Figures 1, 2, 7, and 8, the panel 3 is constructed by joining an upper frame member 31, a side frame member 32, and a lower frame member 33 made of extruded aluminum into a frame shape. A face plate 34 made of a thin iron plate is attached to both sides using an epoxy adhesive or the like, and a core material 35 is housed inside the face plate 34. The left and right side frame members 32 are rectangular pipe-shaped pieces with a recessed groove 32a that can hold one half of the pillar 1 on the outer surface that becomes the joint surface 3a of the panel 3. An inner groove 32b narrower in width than the recessed groove 32a is formed in the center of the bottom surface of the Pt 32a, and the engaging claws 6 are fixed in the portions of the inner groove 32b corresponding to the respective engaging holes 12. It is set up. As shown in FIGS. 2 and 8, the engaging claws 6 form a pair with a substrate 61 fixed to the bottom surface of the inner groove 32b and extend outward from both side edges of the substrate 61. A claw body 62 is provided.
The claw body 62 has an inverted shape that bends downward. Therefore, the panel coupling means 5 is connected to the engagement hole 12.
and the engaging claw 6.

Since the panels 3 of this embodiment are of the same height, they are fastened to each company 1 using a common fastening tool 7.

Specifically, a fastener 7 is bridged between the upper end surfaces 3c of adjacent panels 3 via the relay member 2 and the forest 1, and each end 7a of the fastener 7 is connected using a bolt 8. By fixing the panel 3 to the upper frame member 31, and tightening it by screwing each bolt 9 passed through the vicinity of the center of the tightening tool 7 into the nut 10 held at the vicinity of the upper end of each column 1. , the respective pillars 1 are relatively drawn toward the tightening tool 7.

As shown in FIGS. 7 to 11, the tightening tool 7 is
・The cross section of each end portion is U-shaped, and the lower half of both side walls of each end portion 7a are inclined in a direction that gradually approaches downward to form a tapered portion 1. ing. On the other hand, a groove 36 having a trapezoidal cross section is formed on the upper surface of the upper frame member 31 of the panel 3, and the inner surface of the groove 36 is formed into a tapered surface 37 that widens upward. By bridging the tightening tool 7 between the upper end surfaces 30 of the panel 3, its tapered surface 71 is engaged with the groove 36.

In addition, on the joint surface 3a of each panel 3 on the ash relay member 2 side,
As before, other panels 3 are joined via pillars 1. Further, the upper ends of each panel 3, pillar 1, and relay member 2 are hidden by a cover 91 made of synthetic resin.

With such a configuration, the four pillars 1 respectively joined to the four panels 3 gathered at one place are engaged with the respective recessed grooves 21 of the common relay member 2, and are connected by the bolts 42. Fixed. Therefore, each company 1 can be accurately positioned with respect to each other, and the positioning state can be maintained for a long period of time. Furthermore, since the relay part 2 is pipe-shaped, it can exhibit high strength against sprouting and twisting. Therefore, a plurality of panels 3 gathered at one place can be firmly connected via the relay member 2, and the entire wall can be made highly rigid.

Further, as in this embodiment, a tightening tool 7 is fixed to the upper end surface 3C of the panel 3, and a nut 10 is provided near the upper end of the column 1, and the nut 10 is inserted through the tightening tool 7. If the column 1 is pulled relatively toward the tightening tool 7 by the bolt 9 screwed into the column 10, the engagement claw 6 will surely engage with the engagement hole 12 of the column 1. , panel 3
The connection between the column 1 and the column 1 is also ensured. Therefore, by doing so, it is possible to obtain a movable partition wall that has particularly high rigidity and good shape retention.

12 to 15 show an embodiment in which three tall panels 3 and one short panel 3 are arranged in a four-way manner. In this case, these panels 3 are 90
They are joined via the same relay part 2 as in the embodiment described above, which has concave grooves 21 on four sides with different directions, and the upper parts of the joint surfaces of the three front high panels 3 are connected by 9
They are joined via a ψ joint member 2 which is provided with concave grooves 21 on three faces with different 0° orientations. Relay member 2,
As shown in FIG. 60, four outer walls 22 with different 90' orientations, three inner walls 23 with different 90° orientations, and an intermediate wall 2 connecting these inner walls 231 and outer walls 221
4, the three inner walls 231, an intermediate wall 241 continuous to the inner wall 231, an outer wall 22 continuous to the intermediate wall 241, and a recess continuous to the outer wall 22. With the outer wall 221 that does not have the groove 211,
It constitutes a pipe structure. The outer wall 22 that does not have the recessed groove 211 and the recessed groove 211 provided on the outer wall 221 with a different direction of 180' are the bent wall 2 provided at the opening edge of the outer wall 221.
2a1, and a protruding wall 24a protruding from the intermediate wall 241.
1 and a corresponding inner wall 231.

The other concave groove 21 includes a bent wall 22a1 and a protruding wall 24a.
, an intermediate wall 24, and a corresponding inner wall 231. A thick portion 23a1 protruding toward the inner surface is formed at the center of each inner wall 23. As shown in FIG.

A common fastener (not shown) having a T-shape in plan view is bridged between the upper ends of the tall panels 3, and each panel 3 is fastened to the corresponding panel 1 via this fastener. The short panel 3 is fastened to the forest 1 using a fastening tool 7 different from the above-mentioned fastening tool. As shown in FIG. 15, this tightening device 7 has a single-letter shape in plan view, and a U-shaped cross section, with the lower half of both side walls inclined in a direction that gradually approaches the lower side. It is formed on the tapered surface 71.

Then, this tapered surface 711 is engaged with the groove 36 formed in the upper end surface 3C of the panel 3, and the panel 3 is fixed to the upper frame member 31 using the bolt 8, and the tightening tool 7.
By screwing and tightening the bolt 9 passed through the corresponding nut 10 held near the upper end of the corresponding column 1,
The pillar 1 is relatively drawn toward the tightening tool 7.

16 to 18 show an embodiment in which two panels 3 with tall rows orthogonal to each other and two panels 3 with short rows orthogonally to each other are arranged in a four-way manner.

In this case, these panels 3 are joined via a relay member 2 similar to that of the embodiment described above, which has concave grooves 21 on each of four sides oriented at 90°, and the two panels 3 with high sound are joined together. The upper parts 161 of the joint surfaces of No. 3 are joined via a relay member 2□, which has concave grooves 212 on two different faces facing 90''.The relay member 2□ is the 61st
As shown in the figure, four outer walls 22□ with different 90° orientations.
, one outer wall 22 □ with different orientations of about 45' that connects the outer walls 22 □ that do not have the recessed grooves 21 □, two inner walls 23 □, and ψ that connects these inner walls 23 □ and the outer wall 222. It comprises a clearing 24□, the two inner walls 23□, an intermediate wall 24□ continuous to this inner wall 232, an outer wall 22□ continuous to this intermediate wall 24□, and this outer wall 22□. A pipe structure is constituted by the outer wall 22□ which does not have the concave groove 21□ which is continuous to the outer wall 22□. The recessed groove 21□ is formed by a folded wall 22a2 provided at the opening edge of the outer wall 22□, a protruding wall 24a2 protruding from the intermediate wall 24□, a corresponding inner wall 232, and a corresponding intermediate wall 242. ing. A thick inner wall 23a2 is formed in the center of each inner wall 232 and projects toward the inner surface. tall panel 3
A common fastener (not shown) having a cross-shaped shape in plan is bridged between the upper ends of the panel 3, and each panel 3 is fastened to the corresponding panel 1 via this fastener. The short panel 3 is fastened to each column 1 using separate fastening tools 7 each having a single letter shape in plan view, similar to the previous embodiment.

Figures 19 to 21 show an example of a 4-way arrangement of two tall panels 3 that should be flush with each other and two short panels 3 that should be flush with each other. There is. In this case, these panels 3 should be placed in 4 different directions at 90''.
They are joined via the same relay member 2 as in the embodiment described above, each having a concave groove 21 on the surface, and the wires are connected to the joint surfaces of the two high-sound panels 3 in two different directions of 180 degrees. ψ joint part 2 each provided with a concave groove 213
It is joined via 3. As shown in FIG. 62, the ψ joint part 23 has four outer walls 223 oriented at 90 degrees,
Two inner walls 23 with different orientations of 180°. and an intermediate wall 243 that connects these inner walls 233 and outer wall 223.
A pipe structure is constituted by an intermediate wall 243 that is continuous to 33, an outer wall 223 that is continuous to this intermediate wall 243, and an outer wall 223 that is continuous to this outer wall 223 and does not have the recessed groove 213. The recessed groove 213 is formed in the intermediate wall 24. and,
and a corresponding inner wall 233. At the center of each inner wall 233, there is a thick inner wall 23a that protrudes toward the inner surface.
3 is formed.

Between the upper ends of the two tall panels 3, a long common fastening device forming a single character shape in plan view is bridged, and each panel 3 is tightly connected to the corresponding panel 1 via this fastening device. . This fastening tool has a U-shaped cross section similar to the above-mentioned fastening tool, and the lower halves of both side walls thereof are formed into tapered portions by slanting them in a direction that gradually approaches them downward. The two short panels 3 each have separate fasteners 7 similar to the previous embodiment.
1 to each corresponding pillar 1.

FIGS. 22 to 24 show an embodiment in which one tall panel 3 and three short panels 3 orthogonal to each other are arranged in a four-way manner.

In this case, these panels 3 are joined via the above-mentioned relay member 2 which is provided with concave grooves 21 on each of the four faces oriented at 90 degrees, and one is attached to the upper part of the joint surface of the high-noise panel 3. A pipe-shaped end member 24 having a concave groove 214 on its surface is attached. The edge member 24 has a sixth
As shown in Figure 3, four outer walls 22 with different 90G orientations
4, one inner wall 234, and this inner wall 234 and outer wall 22
4 and an intermediate wall 244 that connects the
The inner wall 234, two intermediate walls 24, and four outer walls 224 constitute a pipe structure. The recessed groove 214 is formed by the intermediate wall 244 and the corresponding inner wall 234.

A wall portion 23a4 is formed in the center of each inner wall 234 and projects toward the inner surface. Each column 1 corresponding to the upper end of the tall panel 3 and the three short panels 3 is bridged with each of the above-mentioned tightening tools 71, which form a single letter shape in plan view. Each panel 3 is connected to a corresponding column 1 via a respective one.

Figures 25 and 26 show three images of the same height that are orthogonal to each other.
An example is shown in which panels 3 are arranged in three ways. In this case, these panels 3 are joined via a relay part 2 similar to that of the embodiment described above, which has concave grooves 211 on three sides oriented at 90 degrees, respectively, and the relay members 2, and three wires 1 are connected by the relay member joining means 4, respectively. A common tightening device having a T-shape in plan view is bridged between the upper ends of the panels 3, and each panel 3 is tightly connected to the corresponding column 1 via this tightening device, and the columns 1 are relatively connected to each other. He is trying to pull it toward the tightening tool.

FIGS. 27 to 29 show an embodiment in which two tall panels 3 orthogonal to each other and - short panels 3 are arranged in a three-way manner. In this case, the above-mentioned relay member 2. is formed by forming recessed grooves 211 on three sides of these panels at different angles of 90°. A relay member 22 similar to that of the above-mentioned embodiment is provided, in which the two tall panels 3 are joined together through a recessed groove 212 on two different sides of the joint surfaces of the two tall panels 3, which are oriented at 90 degrees to each other. It is joined through. A common fastener having a cross-shaped shape in plan is bridged between the upper ends of the tall panels 3, and each panel 3 is fastened to the corresponding column 1 via this fastener. The short panel 3 is fastened to the corresponding column 1 using the fastening tool 71 which is shaped like a single letter in plan view.

30 to 32 show an embodiment in which two tall panels 3 and one short panel 3 are arranged in a three-way manner. In this case, these panels are joined via the relay member 2 which is provided with recessed grooves 211 on three different faces facing 906, and the upper parts of the joint surfaces of the two tall panels 3 are connected to each other. Concave grooves 21. are formed on two sides with different 180' directions. They are joined via relay members 23, each of which is provided with a respective one. Between the upper ends of the tall panels 3, a common long fastener having the shape of a letter in plan view is bridged, and the panel 3 is fastened to the corresponding pillar 1 via this fastener. The short panel 3 is fastened to the corresponding column 1 using the fastening tool 7, which is shaped like a letter in plan view.

FIGS. 33 to 35 show an embodiment in which one tall panel 3 and two short panels 3 that are to abut each other are arranged in a three-way manner.

In this case, the relay member 2 is formed by forming the panels 3 with recessed grooves 21 on three different sides facing 90o, respectively.
At the same time, a pipe-shaped edge member 24 having a concave groove 214 on one side is attached to the upper part of the joint surface of the tall panel 3. Each pillar 1 corresponding to the upper end of each panel 3 is bridged with a separate fastening tool 71 which forms a letter shape in plan view, and each panel 3 is fastened to the corresponding pillar 1 via this fastening tool 71. There is.

36 to 38 show an embodiment in which one row of tall panels 3 and two mutually orthogonal short panels 3 are arranged in a three-way manner.

In this case, the panels 3 are joined via the relay member 2 provided with recessed grooves 21 on three different faces facing 90', and the tall panel 3 is
A pipe-shaped edge member 24 having a concave groove 214 on one side is attached to the upper part of the joint surface. Each pillar 1 corresponding to the upper end of each panel 3 is bridged with a separate tightening tool 7 which forms a letter shape in plan view, and each panel 3 is connected via this tightening tool 7.
39 and 40 respectively show an embodiment in which three panels 3 of the same height are arranged at equal angular intervals in a three-way manner. In this case, these panels 3 are provided with concave grooves 21. Relay members 2. It is connected through. Relay member 2. As shown in FIG.
It is a pipe-shaped thing which is provided with 5 respectively. Specifically, three outer walls 22. and 12
Three inner walls with different 0° orientations 23. and these inner walls 23
．． and outer wall 22. The three inner walls 235 constitute a pipe structure. Each of the recessed grooves 21. is the outer wall 22.
a folded wall 22a provided at the edge of the opening; and the inner wall 23. The protrusion g23 b'y protruding from the corresponding inner wall 23
．． and each inner wall 23. A thick portion 23a is formed in the center of the holder, and projects toward the inner surface.

Figures 41 to 43 show an example in which two high-row panels 3 and one low-pitched panel 3 to be butted at an angle of 120' are arranged in three ways at equal angular intervals. It shows. In this case, these panels 3 are provided with concave grooves 21. The relay member 2 is joined through the relay member 2, which is provided with the two tall panels 3, and the upper parts of the joining surfaces of the two tall panels 3 are respectively provided with recessed grooves 216 on two sides that are oriented at 120 degrees to each other. They are joined via 26. As shown in FIG. 65, the ψ joint member 26 has concave grooves 21 on two different sides in
．． It is a pipe-shaped thing that is provided with . Specifically, three outer walls 226 with different orientations of 120° and 12
Two inner walls 236 with different 0' orientations and these inner walls 23
6 and the outer wall 226, and the two inner walls 236 and the recessed groove 216 are
The pipe structure is constituted by the outer wall 226 that does not cover the pipe. Each recessed groove 216 includes a folded wall 22a6 provided at the opening edge of the outer wall 226, and a protruding wall 23 provided protruding from the inner wall 236.
b6, a corresponding inner wall 236, and an intermediate wall 246, and a thick inner wall 23a6 protruding toward the inner surface is formed at the center of each inner wall 236.

Figures 44 to 46 show one tall panel 3 and one
An example is shown in which two short panels 3 to be butted at an angle of 20' are arranged in three ways at equal angular intervals. In this case, these panels 3 are 120″
' Concave grooves 21 on three sides with different directions. are connected via relay members 2° each provided with a pipe-shaped edge member 27 having a concave groove 217 on one side on the upper part of the joint surface of the tall panel 3. There is. As shown in FIG. 66, the edge member 27 is a pipe-shaped member with a recessed groove 217 provided in the outer wall 22□ on the side of the tall panel 3. Specifically, the outer wall 22 having the recessed groove 217
□, a pair of parallel outer walls 227 continuous to both ends of this outer wall 227 in a perpendicular state, and a pair provided continuously to these parallel outer walls 227 and intersecting at a fixed degree of 60° on the tip side. An inclined wall 22□, - inner walls 23□, and an intermediate wall 24 connecting the inner wall 237 and the outer wall 227.
7, the inner wall 237 and the intermediate wall 2
47 and the outer wall 227 constitute a pipe structure. The recessed groove 21□ is formed by the inner wall 237 and the intermediate wall 247, and a thick inner wall 23a7 is formed in the center of each inner wall 237 and projects toward the inner surface.

47 and 48 show an embodiment in which two panels 3 of the same height are arranged in two ways. In this case, the joining surfaces of the two panels 3 are joined via the relay member 2 □, which has recessed grooves 21 □ on two faces oriented at 90° different from each other. Between the top edges of panel 3,
A common fastener having a cross-shaped shape in plan is bridged, and each panel 3 is fastened to the corresponding column 1 via this fastener.

49 to 51 show an embodiment in which one tall panel 3 and one short panel 3 are arranged in two ways at right angles. In this case, these panels 3 are joined via the relay member 2 □, which is provided with recessed grooves 21 □ on two different sides facing 90", and a A pipe-shaped edge member 28 having a concave structure 218 on one side is attached.This edge part side 28 has a 9-shaped edge member 28 as shown in FIG.
Four outer walls 228 with different 0'' orientations, one outer wall 228 with different orientations of approximately 45 degrees that connect the outer walls 228 that do not have the recessed grooves 218, one inner wall 238, and this inner wall 238 and the outer wall 228. and an intermediate wall 248 connecting the inner wall 238 and the inner wall 238.
an intermediate wall 248 continuous to the intermediate wall 248, an outer wall 228 continuous to the intermediate wall 248, and a concave groove 21 continuous to the outer wall 228.
8 and an outer wall 228 without a, a pipe structure is constructed. The recessed groove 218 is formed by the intermediate wall 248 and the corresponding inner wall 238. A thick inner wall 23a8 is formed in the center of each inner wall 238 and projects toward the inner surface. Further, separate fasteners 71 each having a monogram shape in plan view are bridged between the upper end of each panel 3 and the pillar 1, and each panel 3 is fastened to the corresponding pillar 1 via the fasteners 7. .

52 and 53 show an embodiment in which two panels 3 of the same height are arranged in two ways at an angle of 120°. In this case, these panels 3 are 12
They are joined via a relay member 26 which is provided with concave grooves 216 on two sides with different 0° orientations. In addition, between the upper ends of each panel 3, there is a common tightening device (
(not shown) is bridged, and each panel 3 is fastened to the corresponding column 1 via this fastener.

54 to 56 show an embodiment in which a tall panel 3 and a short panel 3 are arranged in two ways at an angle of 120°. In this case, these panels 3 are joined via a relay member 26 having concave grooves 216 on two faces oriented at different angles of 120 degrees, and one face is attached to the upper part of the joining face of the tall panel 3. A pipe-shaped end member 27 having a recessed groove 217 is attached to the end member 27. Further, separate fasteners 7, each having a monogram shape in plan view, are bridged between the upper end of each panel 3 and the forest 1, and each panel 3 is tightly connected to the corresponding forest 1 via the fasteners 71. .

FIGS. 57 to 59 show an embodiment in which a tall panel 3 and a short panel 3 are arranged flush with each other in two ways. In this case, these panels 3
are joined via the above-mentioned relay member 23 which is provided with recessed grooves 213 on two different faces facing 1806, and a recessed groove 214 is provided on the - side on the upper part of the joint surface of the tall panel 3. The pipe-shaped end edge member 24 is attached. Between the upper ends of the tall panel 3 and the short panel 3 and the forest 1, separate fasteners 7□, which form a monogram in plan view, are bridged, and each panel is connected via the fasteners 7. 3
We are closely tied to Company 1, which handles these issues.

In addition, in each of the above embodiments, each relay member 21 to 23
．． 26, 26 and each edge member 24, 27, 28 and the corresponding column 1 are respectively connected by the relay member joining means 4. In addition, each relay member 21 to 23.25.2
6 is integrally made of aluminum by extrusion molding.

Furthermore, in each of the above embodiments, the same reference numerals are given to the parts corresponding to the above embodiments in each drawing, and the description thereof will be omitted.

[Effects of the Invention] Since the present invention has the above-described configuration, a plurality of pillars each connected to a plurality of panels gathered at one place,
It is engaged and held in each concave groove of the common relay part. Therefore, it is possible to accurately position each grove with respect to each other, and it becomes easy to maintain the positioning state over a long period of time.

In particular, the relay member joining means for connecting each company and the relay member is equipped with a screw hole provided in the four-walled part of the relay member, and a bolt that passes through each company and is screwed into the screw hole. For example, with a simple configuration, the pillar and the relay member can be reliably connected, and the connected state can be maintained for a long period of time. Moreover, since the relay member is pipe-shaped, it can exhibit high strength against bending and torsion. Therefore, a plurality of panels assembled in one place can be firmly connected via these relay members, and the entire wall can be made highly rigid.

If the panel connecting means for connecting each panel to the corresponding company is equipped with an engaging hole provided in the forest and an engaging claw provided in the panel that bends downward, it will be possible to connect each panel reliably and easily. Since the panels can be joined to the corresponding panels in sequence, the assembly process can proceed smoothly.

If the fasteners fixed to the panel are positioned on the hook and the pillars are relatively drawn toward the fasteners, the connection between the pillars and the panel can be particularly strengthened. At that time, if adjacent columns and panels have the same height via a relay member, it is sufficient to tighten them to the corresponding columns using a common tightening tool, so that these panels are not integrally connected to each other. This makes it possible to further strengthen the connection between columns and panels.

Also, when joining panels of different heights, if different types of relay members and edge members are used as described above, for example, the relay members can be adjusted to the height of the tall panel, Compared to the case where a blind cover is attached to the top of the recessed groove that engages the lower panel side,
It is possible to improve the precision of the shape design in the end treatment portion, and it becomes easy to improve the appearance of that portion.

If the relay member is made of extruded aluminum, it will be particularly lightweight and rigid, allowing for smooth assembly work and providing excellent durability.

[Brief explanation of drawings]

Figures 1 to 11 show an example of the actual punching, and Figure 1 is a schematic perspective view when the panels are arranged in 4 ways, and Figure 2
The figure is a plan sectional view of the main part, FIG. 3 is a side view of the column, FIG. 4 is a front view of the column partially omitted, FIG. 5 is a plan sectional view showing an enlarged relay member, and FIG. The figure is a plan sectional view showing the joint state of the relay member and the pillar, FIG. 7 is a side view of the panel with a partial section, and FIG. 8 is a front sectional view showing an enlarged view of the inside of section A in FIG. 1. FIG. 9 is an exploded perspective view of the joint portion, FIG. 10 is a view taken along arrow B in FIG. 8, and FIG. 11 is a side cross-sectional view showing an enlarged portion C in FIG. 7. Fig. 12 is a schematic perspective view of a 4-way arrangement of panels of different heights, Fig. 13 is a plan sectional view of the lower side of the joint in the same embodiment, and Fig. 14 is a diagram of the joint in the same embodiment. FIG. 15 is a top sectional plan view of the tightening device. Fig. 16 is a schematic perspective view of a 4-way arrangement of panels of different heights, Fig. 17 is a plan sectional view of the lower side of the joint in the same embodiment, and Fig. 18 is a cross-sectional view of the joint in the same embodiment. It is a plane sectional view of one part side. Fig. 19 is a schematic perspective view of a 4-way arrangement of panels of different heights, Fig. 20 is a plan sectional view of the lower side of the joint in the same embodiment, and Fig. 21 is a diagram of the joint in the same embodiment. It is a top sectional view of the upper side. Fig. 22 is a schematic perspective view of a 4-way arrangement of panels of different heights, Fig. 23 is a plan sectional view of the lower side of the joint in the same embodiment, and Fig. 24 is a diagram of the joint in the same embodiment. It is a top sectional view of the upper side. FIG. 25 is a schematic perspective view of a 3-way arrangement of panels with a height of 1, il-, and FIG. 26 is a cross-sectional plan view of a joint in the same embodiment. Fig. 27 is a schematic perspective view when panels of different heights are arranged in three ways, Fig. 28 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 29 is a diagram of the joint in the same embodiment. It is a top sectional view of the upper side. Fig. 30 is a schematic perspective view when panels of different heights are arranged in three ways, Fig. 31 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 32 is a cross-sectional view of the joint in the same embodiment. It is a top sectional view of the upper side. Fig. 33 is a schematic perspective view when panels of different heights are arranged in three ways, Fig. 34 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 35 is a diagram of the joint in the same embodiment. It is a top sectional view of the upper side. Fig. 36 is a schematic perspective view of a three-way arrangement of panels of different heights, Fig. 37 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 38 is a cross-sectional view of the joint in the same embodiment. It is a top sectional view of the upper side. FIG. 39 is a schematic perspective view of a case where panels of the same height are arranged in three ways, and FIG. 40 is a plan cross-sectional view of a joint in the same embodiment. Fig. 41 is a schematic perspective view when panels of different heights are arranged in three ways, Fig. 42 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 43 is a diagram of the joint in the same embodiment. It is a top sectional view of the upper side. Fig. 44 is a schematic perspective view of the case where three panels of different heights are machined using a machining device, Fig. 45 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 46 is a joint in the same embodiment. FIG. FIG. 47 is a schematic perspective view of a case where panels of the same height are arranged in two ways, and FIG. 48 is a plan cross-sectional view of a joint in the same embodiment. Fig. 49 is a schematic perspective view when panels of different heights are arranged in two ways, Fig. 50 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 51 is a diagram of the joint in the same embodiment. It is a top sectional view of the upper side. Fig. 52 is a schematic perspective view of a case where panels of the same height are arranged in two ways, and Fig. 53 is a plan cross-sectional view of a joint in the same embodiment. Fig. 54 is a schematic perspective view when panels of different heights are arranged in two ways, Fig. 55 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 56 is a cross-sectional view of the joint in the same embodiment. It is a top sectional view of the upper side. Fig. 57 is a schematic perspective view when panels of different heights are arranged in two ways, Fig. 58 is a plan cross-sectional view of the lower side of the joint in the same embodiment, and Fig. 59 is a diagram of the joint in the same embodiment. It is a top sectional view of the upper side. Figures 60 to 62 and 64 and 6
FIG. 5 is a plan cross-sectional view of the relay system. 63, 66, and 67 are plan cross-sectional views of the edge member. 1...Mori 2...Relay member 3...Panel 3a...Joint surface 3C...Top end surface
4... Relay member joining means 5... Panel joining means 6... Engaging claw 7... Tightening tool 9... Bolt 10... Nut 12... Engaging hole 21.
...Concave groove 23a...Thick wall portion 32a...Concave groove 41...Screw hole 42...Bolts 21 to 23.29.26...Relay member 24.27.2
B... Edge member 7,... Tightening tool 211-213.21s, 216... Concave groove 214
．． 217.21s...concave groove

Claims (1)

[Claims] 1. A pipe-shaped relay member having a plurality of pillars, a plurality of recessed grooves on the outer surface that engage with one half of each of the pillars, and a pillar on the joint surface. a plurality of panels each having a recessed groove that engages with the other half of the panel; a relay member connecting means for connecting each column to the relay member; and connecting each panel to each corresponding column. A movable partition wall characterized by comprising panel joining means. 2. Claim characterized in that the relay member joining means comprises a screw hole provided in the thick portion of the relay member, and a bolt that penetrates the column and is screwed into the screw hole. The movable partition wall described in 1. 3. The movable partition wall according to claim 1 or 2, wherein the panel joining means comprises an engagement hole provided in the pillar and an engagement claw provided in the panel and bent downward. 4. Attach a tightening tool to the upper end surface of the panel, provide a nut near the upper end of the column, and relatively tighten the column with a bolt that passes through the tightening tool and is screwed into the nut. 4. The movable partition wall according to claim 3, wherein the movable partition wall is drawn in the direction of the movable partition wall. 5. Claim 4, wherein adjacent pillars and panels have the same height via a relay member, and the panels are fastened to the corresponding pillars using a common fastening tool.
Movable partition wall as described. 6. A claim characterized in that columns and panels adjacent to each other via a relay member have different heights, and each panel is individually tightened to the corresponding column using a different tightening device. The movable partition wall according to item 4. 7. Claim 1, characterized in that the relay member is provided with concave grooves on each of four sides oriented at 90 degrees.
Movable partition wall as described. 8. Claim 1, characterized in that the relay member is provided with concave grooves on each of three sides oriented at 90 degrees.
Movable partition wall as described. 9. Claim 1, characterized in that the relay member is provided with concave grooves on two sides oriented at 90 degrees.
Movable partition wall as described. 10. The movable partition wall according to claim 1, wherein the relay member is provided with concave grooves on two sides oriented at 180 degrees. 11. The movable partition wall according to claim 1, wherein the relay member is provided with concave grooves on three different sides oriented at 120°. 12. The movable partition wall according to claim 1, wherein the relay member is provided with concave grooves on two sides facing each other at 120°. 13. The movable partition wall according to claim 7, 8, 9, 10, 11 or 12, wherein the relay member is made of extruded aluminum. 14. The movable partition wall according to claim 1, characterized in that four panels of the same height are joined via the relay member according to claim 7. 15. Joining three tall panels and one short panel via the relay member according to claim 7,
Claim 8: The upper parts of the joint surfaces of the three tall panels
The movable partition wall according to claim 1, characterized in that the movable partition wall is joined via the relay member described above. 16. Two tall orthogonal panels and two short orthogonal panels are joined via the relay member according to claim 7, and the upper part of the joint surface of the two tall panels The movable partition wall according to claim 1, wherein the movable partition walls are joined to each other via the relay member according to claim 9. 17. Two tall panels that should be flushly butted and two short panels that should be flush butt are joined via the relay member according to claim 7, and the two tall panels The movable partition wall according to claim 1, wherein the upper joint surfaces of the panels are joined together via the relay member according to claim 10. 18. One tall panel and three short panels perpendicular to each other are joined via the relay member according to claim 7, and a
2. The movable partition wall according to claim 1, further comprising a pipe-shaped end member having a concave groove on its surface. 19. The movable partition wall according to claim 1, characterized in that three panels of the same height are joined via the relay member according to claim 8. 20. Joining two tall panels orthogonal to each other and one short panel via the relay member according to claim 8, and connecting the upper parts of the joining surfaces of the two tall panels to each other. The movable partition wall according to claim 1, wherein the movable partition wall is joined via the relay member according to claim 9. 21. Joining two tall panels and one short panel that are to be flush flush with each other via the relay member according to claim 8, and joining surfaces of the two tall panels. The movable partition wall according to claim 1, wherein the upper portions are joined to each other via the relay member according to claim 10. 22. One tall panel and two short panels to be butted to each other are joined via the relay member according to claim 8, and a 2. The movable partition wall according to claim 1, further comprising a pipe-shaped end member having a concave groove on its surface. 23. One tall panel and two mutually orthogonal short panels are joined via the relay member according to claim 8, and on the upper part of the joint surface of the tall panel,
The movable partition wall according to claim 1, further comprising a pipe-shaped edge member having a recessed groove on one side. 24. The movable partition wall according to claim 1, characterized in that three panels of the same height are joined via the relay member according to claim 11. 25. Two tall panels to be butted together at an angle of 120° and one short panel are joined via the relay member according to claim 11, and the tall two
The movable partition wall according to claim 1, characterized in that the upper parts of the joint surfaces of the two panels are joined via the relay member according to claim 12. 26. Joining one tall panel and two short panels that are to butt each other at an angle of 120° via the relay member according to claim 11, and joining the tall panels. Claim 1 characterized in that a pipe-shaped edge member having a concave groove on one side is attached to the upper part of the surface.
Movable partition wall as described. 27. The movable partition wall according to claim 1, characterized in that two panels of the same height are joined via the relay member according to claim 9. 28. Claim 9: A tall panel and a short panel.
A pipe-shaped edge member having a concave groove on one side is attached to the upper part of the joint surface of the tall panel while being joined via the relay member as described above. The movable partition wall described in 1. 29. The movable partition wall according to claim 1, characterized in that two panels of the same height are joined via the relay member according to claim 12. 30. Claim 1: tall panel and short panel
A claim characterized in that the tall panel is joined via the relay member according to item 2, and a pipe-shaped edge member having a recessed groove on one side is attached to the upper part of the joint surface of the tall panel. The movable partition wall according to item 1. 31. A tall panel and a short panel to be flushly butted are joined via the relay member according to claim 10, and a recessed groove is formed on one side of the upper joint surface of the tall panel. 2. The movable partition wall according to claim 1, further comprising a pipe-shaped end member having a pipe shape.