JP3201906U - Panel unit - Google Patents

Abstract

A panel unit that can easily and easily connect a plurality of polygonal panels. A panel unit has a plurality of rectangular panels P4, P6, P11 and a plurality of connecting shafts, and each rectangular panel P4, P6, P11 constitutes a panel cube 101. The rectangular panels P4, P6, and P11 form a ring alignment group RG2 between the rectangular panels P4, P6, and P11 so that the connection holes of the connection rings arranged on the side end faces face each other. Each connecting shaft is inserted through a connecting hole of each connecting ring constituting each ring alignment group RG2 to connect each rectangular panel P4, P6, P11 in a pivotable manner, and each rectangular panel P4, P6, P11 is connected to the panel. Hold in the rectangular parallelepiped 101. [Selection] Figure 5

Description

  The present invention relates to a panel rectangular parallelepiped used for buildings such as houses, animal traps, etc., or a panel unit used for panel fences, animal enclosures and the like.

  As a technique of the panel unit, Patent Document 1 discloses a beast trap that connects a plurality of shelf units with a connecting coil. Each shelf unit is formed in a rectangular shape and is configured by arranging a plurality of vertical iron wires and horizontal iron wires in a grid.

  However, in Patent Document 1, the connection of each shelf unit needs to wrap the connection coil around the connection rebar wire (vertical wire) of each shelf unit, and the connection coil is wound around each connection iron wire while bypassing each horizontal wire. Is not easy, and the connecting operation of each shelf unit becomes complicated.

Utility Model Registration No. 3172057

  An object of the present invention is to provide a panel unit that can easily and easily connect a plurality of polygonal panels.

  Claim 1 according to the present invention is a panel unit that constitutes a rectangular parallelepiped panel including right and left side surfaces, a ceiling surface, a bottom surface, and a back surface, and includes a panel body that forms a rectangular outer edge at a plurality of side end surfaces, and a plurality of connection rings. Including a plurality of rectangular panels arranged in a plurality along the side end surfaces and held in the panel body, and a plurality of connecting shafts inserted through the connecting rings. Each connecting ring has a connecting hole, the hole center line of the connecting hole is located on a straight line parallel to each side end face, and is equidistant from both end points of each side end face The connecting holes pass through the connecting ring along the hole center line, and the plurality of rectangular panels constitute the left and right side surfaces, the ceiling surface, the bottom surface, and the back surface, and each side end surface The connection holes of the connection rings arranged in Oppositely, a ring alignment group is formed between the respective rectangular panels, and the plurality of connecting shafts pass through the connecting holes of the connecting rings constituting the ring aligning groups to pivot the rectangular panels. The panel unit is characterized in that it is freely connected and each rectangular ring is held in the panel rectangular parallelepiped.

  According to a second aspect of the present invention, there is provided a panel body that forms a rectangular outer edge at a plurality of side end faces, and a plurality of connecting rings, and a plurality of the connecting rings are arranged along a pair of parallel side end faces parallel to each other. A plurality of rectangular panels that are held in the panel body, and a plurality of connecting shafts that are inserted through the connecting rings, each connecting ring having a connecting hole, The hole center lines of the connection holes are positioned on a straight line parallel to the respective parallel side end faces, and are arranged at equal intervals between both end points of the respective parallel side end faces, and the connection holes extend along the hole center lines. The plurality of rectangular rings are continuously arranged in parallel, the connection holes of the connection rings arranged on the one parallel side end face, and the other parallel side end face arranged on the other parallel side end face Each rectangular panel facing each other through the connection holes of each connection ring A ring alignment group is formed, and the plurality of connection shafts are inserted through the connection holes of the continuous connection rings constituting the ring alignment groups, and the rectangular panels arranged in series are rotatably connected. It is related with the panel unit characterized by this.

  According to a third aspect of the present invention, in the panel unit according to the second aspect, the connecting shafts are driven into the ground and the rectangular panels arranged side by side are erected on the ground.

  According to a fourth aspect of the present invention, there is provided a panel main body that forms a rectangular outer edge with a plurality of side end faces, and a plurality of connection rings, and a plurality of the connection rings are arranged along the side end faces. One rectangular panel and another rectangular panel to be held, and a connecting shaft inserted into each of the connecting rings, each connecting ring having a connecting hole, and the connecting hole The hole center line is positioned on a straight line parallel to the side end face, and is arranged at equal intervals between both end points of the side end face, and the connection hole penetrates the connection ring along the hole center line. The one rectangular panel and the other rectangular panel are arranged side by side, and the continuous holes of the continuous rings arranged on the side end faces are opposed to each other so that the rings are aligned between the rectangular panels. Forming a group, and the connecting shafts constitute the ring alignment group. By inserting the coupling hole of the respective connecting ring, the one rectangular panel, and a panel unit, characterized by pivotally connecting the other one of the rectangular panel.

  A fifth aspect of the present invention includes a panel body that forms a polygonal outer edge at a plurality of side end faces, and a plurality of connection rings, and a plurality of the connection rings are arranged on the side end faces and are held by the panel body. A polygon panel and a connecting shaft inserted through the connecting ring, each connecting ring having a connecting hole, and a hole center line of the connecting hole is parallel to the side end surface Are arranged at equal intervals between both side points of the side end surface, and the connection hole penetrates the connection ring along the hole center line, and the one polygon panel, and The other polygon panel is continuously arranged, facing the connection holes of the connection ring arranged on the side end face to form a ring alignment group between the polygon panels, and the connection shaft is The connection holes of the connection rings constituting the ring alignment group are inserted. To, relates to a panel unit, characterized by connecting said one polygonal panel, and the other one polygonal panel pivotally.

According to the first aspect of the present invention, a plurality of rectangular panels are arranged side by side to form the left and right side surfaces, the ceiling surface, the bottom surface, and the back surface of the panel rectangular parallelepiped.
The rectangular panels on the left side surface, the ceiling surface, the bottom surface, and the back surface face the connection holes of the connection rings arranged on the side end surfaces to form a ring alignment group between the rectangular panels. The ring alignment group is configured by aligning the connection rings between the rectangular panels in a straight line. The plurality of connecting shafts are inserted through the connecting holes of the ring alignment groups formed between the rectangular panels.
Each rectangular panel is connected by a connecting shaft in each ring alignment group, and is configured in a panel rectangular parallelepiped. When each rectangular panel is connected by each connecting shaft, each connecting shaft holds each rectangular panel in a panel rectangular parallelepiped.
Accordingly, the rectangular panels can be connected to each other simply by inserting the connecting shafts into the connecting holes of the connecting rings constituting the ring alignment groups, thereby forming a panel rectangular parallelepiped. It is possible to easily and easily connect the rectangular panels.
Moreover, the panel rectangular parallelepiped from which a volume differs can be comprised by selecting the connection number of a rectangular panel suitably. The panel cuboid includes a panel cube.

According to claim 2 of the present invention, in each of the plurality of rectangular panels, the connection holes of the connection ring arranged on one plane side end face and the connections arranged on the other parallel side end face are opposed to each other. A ring alignment group is formed between them. The plurality of connection shafts are inserted through the connection holes of the connection rings constituting the ring alignment groups (multiple ring alignment groups) formed between the rectangular panels.
Each rectangular panel is connected by a connecting shaft in each ring alignment group, and is continuously arranged in a direction orthogonal to each parallel side end face.
Thereby, each rectangular panel can be mutually connected only by inserting a connecting shaft in the connecting hole of each connecting ring which comprises each ring alignment group, and a plurality of rectangular panels can be arranged side by side. It is possible to easily and easily connect the rectangular panels.

In Claim 3 which concerns on this invention, a continuous panel fence and a beast enclosure can be comprised by standing up a some rectangular panel on the ground.
When each rectangular panel is connected by each connecting shaft, it can turn around each connecting shaft as a turning center. Thereby, the ground can be partitioned while forming an arbitrary fence outer edge by drawing each rectangular panel.

According to a fourth aspect of the present invention, in one rectangular panel and another rectangular panel, the connection holes of the connection rings arranged on the side end faces are opposed to each other, and a ring alignment group is formed between the rectangular panels. . The connecting shaft is inserted through the connecting hole of each connecting ring constituting the ring alignment group.
Thereby, one rectangular panel and another one rectangular panel are connected only by inserting the connecting shaft into the connecting hole of each connecting ring constituting the ring alignment group.
In addition, since one rectangular panel and the other rectangular panel are pivotally connected by a connecting shaft, they can be swung in a range of 360 ° with the connecting shaft as a turning center. Thereby, the rectangular panels can be arranged side by side at an arbitrary angle. It is possible to easily and easily connect one rectangular panel and another rectangular panel.
In a rectangular panel, the panel body is a rectangular outer edge such as a square outer edge or a rectangular outer edge.

According to claim 5 of the present invention, in one polygon panel and another polygon panel, the connection holes of the connection rings arranged on the side end faces are opposed to each other, and a ring alignment group is provided between the polygon panels. Form. The connecting shaft is inserted through the connecting hole of each connecting ring constituting the ring alignment group.
Thereby, one polygon panel and another one polygon panel are connected only by inserting a connection axis in a connection hole of each connection ring which constitutes a ring alignment group.
In addition, since one polygon panel and the other polygon panel are pivotably connected by a connecting shaft, they can be swung within an angle range of 360 ° with the connecting shaft as a turning center. Thereby, each polygon panel can be arranged in parallel at an arbitrary angle. It is possible to easily and easily connect one polygon panel and another polygon panel.
In the polygonal panel, the panel body has an N-shaped outer edge (N = 3, 4, 5,..., N: natural number). The polygonal panel is, for example, a triangular panel, a rectangular panel, a pentagonal panel, or the like.
For example, one polygon panel may be a triangular panel, and the other polygon panel may be a rectangular panel. For example, each polygon panel may have a different number of corners.

It is a front view which shows the panel unit of 1st Embodiment. It is a front view which shows the rectangular panel which comprises the panel unit of 1st Embodiment. It is a figure which shows the rectangular panel which comprises the panel unit of 1st Embodiment, Comprising: (a) is a BB arrow directional view of FIG. 2, (b) is CC arrow directional view of FIG. It is a figure which shows the panel unit of 1st Embodiment, Comprising: It is an AA arrow line view of FIG. It is the front view which applied the panel unit of 2nd Embodiment to the beast capture cage. It is the figure which applied the panel unit of 2nd Embodiment to the beast capture cage, Comprising: It is a front view of the state which opened and closed the door. It is the rear view which applied the panel unit of 2nd Embodiment to the beast trap. It is the left view which applied the panel unit of 2nd Embodiment to the beast trap. It is the right view which applied the panel unit of 2nd Embodiment to the beast trap. It is the bottom view which applied the panel unit of 2nd Embodiment to the beast trap. It is the well figure which applied the panel unit of 2nd Embodiment to the beast capture trap. It is a front view which shows the panel unit of 3rd Embodiment. It is a front view of the lattice panel main body which constitutes the panel unit of a 3rd embodiment. It is a figure of the lattice panel main body which comprises the panel unit of 3rd Embodiment, Comprising: (a) is an EE arrow line view of FIG. 13, (b) is an FF arrow line view of FIG. It is a figure of the lattice panel main body which comprises the panel unit of 3rd Embodiment, Comprising: (a) is a GG arrow line view of FIG. 13, (b) is a HH arrow line view of FIG. It is a front view of the rectangular panel which comprises the panel unit of 3rd Embodiment. It is a figure which shows the rectangular panel which comprises the panel unit of 3rd Embodiment, Comprising: (a) is the II arrow directional view of FIG. 16, (b) is the JJ arrow directional view of FIG. It is a figure which shows the panel unit of 3rd Embodiment, Comprising: It is the DD arrow directional view of FIG. It is a top view which shows the panel unit of 4th Embodiment. It is a figure which shows the panel unit of 4th Embodiment, Comprising: It is a KK arrow line view of FIG. It is a front view which shows the modification of the rectangular panel which comprises the panel unit of 1st Embodiment. It is a front view which shows a triangular panel as a polygon panel.

  The panel unit of 1st and 4th embodiment is demonstrated with reference to FIG. 1 thru | or FIG.

<First Embodiment>
The panel unit PU1 of the first embodiment (hereinafter referred to as “panel unit PU1”) will be described with reference to FIGS.

  1 to 4, the panel unit PU1 includes one polygon panel P1, another one polygon panel P2, and a connecting shaft S.

  Each of the polygonal panels P1 and P2 is configured by a rectangular panel (for example, a square panel) as shown in FIGS. 1 to 3 (hereinafter, referred to as “one rectangular panel P1 and another rectangular panel P2”). .

  Each rectangular panel P1, P2 has a lattice panel body 2 (panel body) and a plurality of connecting rings R, R,.

As shown in FIGS. 1 to 3, the lattice panel body 2 is formed in a rectangular shape (for example, a square shape) with a plurality of side end faces 1 </ b> A to 1 </ b> D.
The lattice panel body 2 has a plurality of vertical iron wires 3, 3,... And a plurality of horizontal iron wires 5, 5,. The vertical iron wires 3, 3,... Are arranged in parallel at equal intervals in the horizontal direction H of the lattice panel body 2, and constitute a vertical lattice. The horizontal iron wires 5, 5,... Are arranged in parallel at equal intervals in the vertical direction G perpendicular to the horizontal direction H of the grid panel body 2 to form a horizontal grid. The vertical grid and the horizontal grid are arranged so that the vertical iron wires 3, 3,... And the horizontal iron wires 5, 3,. The vertical iron wires 3, 3,... And the horizontal iron wires 5, 5,.

As shown in FIGS. 1 to 3, the horizontal iron wires 5 and 5 arranged at both ends in the longitudinal direction G of the lattice panel body 2 constitute side end faces 1A and 1B (upper end face and lower end face).
As shown in FIGS. 1 to 3, the vertical iron wires 3 and 3 arranged at both ends in the horizontal direction H of the lattice panel body 2 constitute side end faces 1C and 1D (left end face and right end face).
Thereby, in the lattice panel main body 2, as shown in FIG. 1 thru | or 3, each horizontal iron wire 5 and 5 and each vertical iron wire 3 and 3 comprise several side end surface 1A-1D, and each side end surface 1A. Form a rectangular outer edge (e.g., a square outer edge) at ~ 1D. A rectangular outer edge means a square outer edge such as a square outer edge or a rectangular outer edge.
The side end faces 1A and 1B constitute a pair (first pair) of parallel side end faces 1A and 1B in parallel with each other. The side end faces 1C and 1D constitute a pair (second pair) of parallel end faces 1C and 1D in parallel with each other.
Each side end surface 1A-1D cross | intersects at each end point 2A-2D, as shown in FIG. Each of the end points 2A to 2D is a vertex of the lattice panel body 2 at the rectangular outer edge.

  A plurality of connecting rings R, R,... Are arranged along the side end faces 1A to 1D of the rectangular panels P1, P2. Each connection ring R, R,... Has a connection hole 6. The connection hole 6 is formed in a circular hole, for example (see FIG. 3).

On the side end face 1A, a plurality of connecting rings R, R,... (Hereinafter referred to as “connecting ring RA”), as shown in FIGS. The two end points 2A and 2B of the side end face 1A are arranged at equal intervals with a straight line Aa parallel to the line Aa. The straight line Aa is set at a position separating the interval TA from the side end surface 1A in the direction G (axial center direction G of the vertical iron wire 2) orthogonal to the side end surface 1A.
Each of the connection rings RA, RA,... Is disposed on the horizontal iron wire 5 of the lattice panel body 2 and welded to the horizontal iron wire 3 and the vertical iron wire 3 as shown in FIGS.
In each coupling ring RA, RA,..., The coupling hole 6 is inserted (penetrated) through the coupling ring RA along the hole center line α1.
Accordingly, each rectangular panel P1, P2 has a plurality of connection rings RA, RA,..., And a plurality of the connection rings RA, RA,. To do.

On the side end face 1B, a plurality of connecting rings R, R,... (Hereinafter referred to as “connecting ring RB”), as shown in FIG. 2 and FIG. Are arranged at equal intervals between the two end points 2C and 2D of the side end face 1B. The straight line Ba is set at a position separating the interval TA from the side end surface 1B in the direction G orthogonal to the side end surface 1B.
As shown in FIGS. 1 to 3, each of the connecting rings RB, RB,... Is disposed on the horizontal iron wire 5 of the lattice panel body 2 and welded to the horizontal iron wire 5 and each vertical iron wire 3.
In each connection ring RB, RB,..., The connection hole 6 is inserted (through) the connection ring RB along the hole center line α2.
Accordingly, each rectangular panel P1, P2 has a plurality of connection rings RB, RB,..., And a plurality of connection rings RB, RB,. To do.

On the side end face 1C, a plurality of connecting rings R, R,... (Hereinafter referred to as “connecting ring RC”), as shown in FIGS. Is located on a straight line Ca parallel to the two end points 2A and 2C of the side end face 1C and arranged at equal intervals. The straight line Ca is set at a position separating the interval TA from the side end surface 1C in the direction H (axial direction H of the horizontal iron wire 5) orthogonal to the side end surface 1C.
Each of the connection rings RC, RC,... Is disposed on the horizontal iron wire 5 of the lattice panel body 2 and welded to the horizontal iron wire 5 and the vertical iron wire 3 as shown in FIGS.
In each of the connection rings RC, RC,..., The connection hole 6 is inserted (through) the connection ring RC along the hole center line α3.
Accordingly, each rectangular panel P1, P2 has a plurality of connection rings RC, RC,..., And a plurality of connection rings RC, RC,. To do.

In the side end face 1D, a plurality of connecting rings R, R,... (Hereinafter referred to as “connecting ring RD”), as shown in FIGS. Is located on a straight line Da parallel to the two end points 2B and 2D of the side end face 1D and arranged at equal intervals. The straight line Da is set at a position separating the interval TA from the side end surface 1D in the direction H perpendicular to the side end surface 1D.
As shown in FIGS. 1 to 3, each of the connecting rings RD, RD,... Is disposed on the horizontal iron wire 5 of the lattice panel body 2 and welded to the horizontal iron wire 5 and the vertical iron wire 3.
In each of the connection rings RD, RD,..., The connection hole 6 is inserted (through) the connection ring RD along the hole center line α4.
Thus, each rectangular panel P1, P2 has a plurality of connection rings RD, RD,..., And a plurality of connection rings RC, RC,. To do.

In the lattice panel body 2, the connection rings RA and RB are alternately arranged on the side end faces 1A and 1B (parallel side end faces 1A and 1B).
The connection rings RC and RD are alternately arranged on the side end faces 1C and 1D (parallel end faces 1C and 1D).

In each of the connection rings RA to AD, the hole center lines α1 to α4g of the connection hole 6 are arranged on the same plane HA as shown in FIGS.
Thereby, the connection hole 6 of each connection ring RA-RD is arrange | positioned in the same height position in the width direction M orthogonal to the horizontal direction H and the vertical direction G of the lattice panel main body 2. FIG.

  The connecting shaft S is inserted through each connecting ring RA, RB, RC, RD. The connecting shaft S is formed in a cylinder or a column.

As shown in FIGS. 1 and 4, the panel unit PU1 faces the side end face 1B of one rectangular panel P1 and the side end face 1A of the other rectangular panel P2 so that the rectangular panels P1 and P2 are arranged in series. Set up.
As shown in FIGS. 1 and 4, the one rectangular panel P1 and the other one rectangular panel P2 are connected to the connecting rings RB, RB, arranged on the side end surface 1B (the other parallel side end surface) of the rectangular panel P1, respectively. .. And the connection holes 6 of the connection rings RA, RA,... Arranged on the side end surface 1A (one parallel side end surface) of the rectangular panel P2 are opposed to each other between the rectangular panels P1, P2. A ring alignment group RG1 is formed.
As shown in FIG. 1, the ring alignment group RG1 arranges the connection rings RB, RB,... In alignment between the connection rings RA, RA,..., And connects the connection rings RA, RA, RA to the connection rings RB,. RB,... Are aligned and formed.
As shown in FIGS. 1 and 4, the connection holes 6 of the connection links RB, RB,... And the connection holes 6 of the connection rings RA, RA,. Aa, Ba) are arranged in agreement.

The connecting shaft S is inserted through the connecting holes 6 of the connecting rings RA, RA,..., RB, RB,... Constituting the ring alignment group RG1, and swivels one rectangular panel P1 and the other rectangular panel P2. Connect freely.
Thereby, as shown in FIG. 4, one rectangular panel P1 and the other one rectangular panel P2 can be swung in the range of an angle of 360 ° with the connecting shaft S as a swiveling center.

Further, in the rectangular panel P1, the connecting holes 6 of the connecting rings RC, RC,... Arranged on the side end face 1C, and the connecting holes 6 of the connecting links RD, RD, ... arranged on the side end face 1D of the rectangular panel P2. Opposing each other, a ring alignment group is formed between the rectangular panels P1 and P2. The connecting shaft 6 is inserted into the connecting holes 6 of the connecting links RC and RD constituting the ring alignment group, so that one rectangular panel P1 and the other rectangular panel P2 can be connected to each other so as to be rotatable.
Similarly, in each rectangular panel P1, P2, the connection holes 6 of the connection rings RA, RA,... And the connection holes 6 of the connection rings RD, RD,. The connection shaft 6 and the connection holes 6 of the connection rings RD, RD,... Are opposed to each other, and the connection shaft 6 is inserted into the connection holes 6 of the connection rings constituting the ring alignment group. P1 and the other rectangular panel P2 can be pivotably connected.

Second Embodiment
A panel unit PU2 (hereinafter referred to as “panel unit PU2”) of the second embodiment will be described with reference to FIGS.
5 to FIG. 11, the same reference numerals as those in FIG. 1 to FIG.

5 to 11, the panel unit PU2 constitutes a panel cuboid 101 (including a panel cube). The panel cuboid 101 includes left and right side surfaces 101A and 101B, a ceiling surface 101C, a bottom surface 101D, and a back surface 101E, and is open to the front surface.
The panel unit PU2 has a plurality of rectangular panels P3, P4,..., P11 and a plurality of connecting shafts S, S,. Each of the rectangular panels P3, P4,..., P11 has the same configuration as the panel unit PU1 (see FIGS. 1 to 3).

  The plurality of rectangular panels P3, P4,..., P11 constitute left and right side surfaces 101A, 101B, a ceiling surface 101C, a bottom surface 101D, and a back surface 101E of the panel cuboid 101.

  Each rectangular panel P3, P4 constitutes a ceiling surface 101C. The rectangular panels P3 and P4 are continuously arranged side by side as shown in FIG. 5 to FIG. 9 and FIG. Each rectangular panel P3, P4 is connected to the connecting hole 6 of each connecting ring RA, RA,... Arranged on the parallel side end face 1A (side end face 1A) of one rectangular panel P3, and to the parallel side of the other rectangular panel P4. A ring alignment group RG2 is formed between the rectangular panels P3 and P4 with the connection holes 6 of the connection rings RB, RB,... Arranged on the end surface 1B (side end surface 1B) facing each other. The connecting shaft S is inserted through the connecting holes 6 of the connecting rings RA and RB constituting the ring alignment group RG2 to connect the rectangular panels P3 and P4 so as to be rotatable.

  Each rectangular panel P5, P6 constitutes a bottom surface 101D. The rectangular panels P5 and P6 are connected and juxtaposed as shown in FIGS. Each rectangular panel P5, P6 has a connecting hole 6 of each connecting ring RA, RA,... Arranged on the parallel side end face 1A (side end face 1A) of one rectangular panel P5 and a parallel side of the other rectangular panel P6. A ring alignment group RG3 is formed between the rectangular panels P4 and P5 so that the connection holes 6 of the connection rings RB, RB,... Arranged on the end surface 1B (side end surface 1B) face each other. The connecting shaft S is inserted through the connecting holes 6 of the connecting rings RA and RB constituting the ring alignment group RG3 to connect the rectangular panels P5 and P6 so as to be rotatable.

  Each rectangular panel PP7, P8 constitutes the left side surface 101A. The rectangular panels P7 and P8 are continuously arranged side by side as shown in FIG. 5 to FIG. 8, FIG. 10, and FIG. Each rectangular panel P7, P8 is connected to the connecting hole 6 of each connecting ring RB, RB,... Arranged on the parallel side end face 1B (side end face 1B) of one rectangular panel P7, and to the parallel side of the other rectangular panel P8. A ring alignment group RG4 is formed between the rectangular panels P7 and P8 so that the connection holes 6 of the connection rings RA, RA,... Arranged on the end surface 1A (side end surface 1A) face each other. The connecting shaft S is inserted through the connecting holes 6 of the connecting rings RA and RB constituting the ring alignment group G4 to connect the rectangular panels P7 and P8 so as to be rotatable.

  Each rectangular panel P9, P10 constitutes the right side surface 101B. The rectangular panels P9 and P10 are continuously arranged side by side as shown in FIG. 5 to FIG. 7 and FIG. 9 to FIG. Each rectangular panel P9, P10 has a connecting hole 6 of each connecting ring RA, RA,... Arranged on the parallel side end face 1A of one rectangular panel P9, and a parallel side end face 1B (side end face of the other rectangular panel P10. A ring alignment group RG5 is formed between the rectangular panels P9 and P10 so that the connection holes 6 of the connection rings RB, RB,. The connection shaft S is inserted through the connection holes 6 of the connection rings RA and RB constituting the ring alignment group RG5 to connect the rectangular panels P9 and P10 so as to be rotatable.

The rectangular panel units P7 and P8 on the left side surface 101A are connected to the rectangular panels P5 and P6 on the bottom surface 101C, as shown in FIGS.
The rectangular panels P7 and P5 on the left side surface 101A and the bottom surface 101C are connected to the connection holes 6 of the connection rings RD, RD,... Arranged on the parallel side end surface 1D (side end surface 1D) of the rectangular panel P7 and the parallel side of the rectangular panel P5. A ring alignment group RG6 is formed between the rectangular panels P5 and P7 so that the connection holes 6 of the connection rings RC, RC,... Arranged on the end surface 1C (side end surface 1C) face each other. The connection shaft 6 passes through the connection holes 6 of the connection rings RC and RD constituting the ring alignment group RG6, and rotatably connects the rectangular panels P5 and P7.
Further, the rectangular panels P8, P6 are connected to the connecting holes 6 of the connecting rings RD, RD,... Arranged on the parallel end face 1D (side end face 1D) of the rectangular panel P8, and the parallel end face 1C (side) of the rectangular panel P6. A ring alignment group RG7 is formed between the rectangular panels P8 and P6 with the connection holes 6 of the connection rings RC, RC,... Arranged on the end face 1C) facing each other. The connection shaft 6 passes through the connection holes 6 of the connection rings RC and RD constituting the ring alignment group RG7, and connects the rectangular panels P8 and P6 so as to be rotatable.

As shown in FIGS. 7, 8, and 11, the rectangular panels P7 and P8 on the left side surface 101A are arranged orthogonal to the rectangular panels P3 and P4 on the ceiling surface 101D and connected to the rectangular panels P3 and P4. Is done.
Each rectangular panel P7, P3 includes a connecting hole 6 of each connecting ring RC, RC,... Arranged on the parallel end face 1C (side end face 1C) of the rectangular panel P7, and a parallel end face 1D (side end face 1D) of the rectangular panel P3. .. Are arranged so as to face each other and the ring alignment group RG8 is formed between the rectangular panels P7 and P3. The connection shaft 6 passes through the connection holes 6 of the connection rings RC and RD constituting the ring alignment group RG8, and connects the rectangular panels P7 and P3 so as to be rotatable.
Further, the rectangular panels P8, P4 are connected to the connecting holes 6 of the connecting rings RC, RC,... Arranged on the parallel end face 1C (side end face 1C) of the rectangular panel P8, and the parallel end face 1D (side) of the rectangular panel P4. A ring alignment group RG9 is formed between the rectangular panels P8 and P4 so that the connection holes 6 of the connection rings RD, RD,... Arranged on the end face 1D) face each other. The connection shaft 6 passes through the connection holes 6 of the connection rings RC and RD constituting the ring alignment group RG9, and connects the rectangular panels P8 and P4 so as to be rotatable.

The rectangular panels P9 and P10 on the right side surface 101B are arranged orthogonal to the rectangular panels P5 and P6 on the bottom surface 101C as shown in FIGS. 7, 9 and 10, and are connected to the rectangular panels P9 and P10. .
Each rectangular panel P9, P5 has a connecting hole 6 in each connecting ring RC, RC,... Arranged on a parallel side end face 1C (side end face 1C) of the rectangular panel P9, and a parallel side end face 1D (side end face 1D) of the rectangular panel P5. The ring alignment group RG10 is formed between the rectangular panels P9 and P5 so that the connection holes 6 of the connection rings RD, RD,. The connecting shaft S is inserted through the connecting holes 6 of the connecting rings RC and RD constituting the ring alignment group RG10 to connect the rectangular panels P9 and P5 so as to be rotatable.
Further, the rectangular panels P10 and P6 are connected to the connecting holes 6 of the connecting rings RC, RC,... Arranged on the parallel end face 1C (side end face 1C) of the rectangular panel P10, and the parallel end face 1D (side) of the rectangular panel P6. A ring alignment group RG11 is formed between the rectangular panels P10 and P6 so that the connection holes 6 of the connection rings RD, RD,... Arranged on the end face 1D) face each other. The connecting shaft S is inserted through the connecting holes 6 of the connecting rings RC and RD constituting the ring alignment group RG11 to connect the rectangular panels P10 and P6 so as to be rotatable.

The rectangular panels P9 and P10 on the right side surface 101B are arranged orthogonal to the rectangular panels P3 and P4 on the ceiling surface 101C as shown in FIGS. 7, 9 and 11, and are connected to the rectangular panels P3 and P4. The
Each rectangular panel P9, P3 includes a connecting hole 6 of each connecting ring RD, RD,... Arranged on the parallel side end face 1D (side end face 1D) of the rectangular panel P9, and a parallel side end face 1C (side end face 1C) of the rectangular panel P3. ), The ring alignment group R12 is formed between the rectangular panels P9 and P3. The connection shaft S is inserted through the connection holes 6 of the connection rings RC and RD constituting the ring alignment group RG12 to connect the rectangular panels P9 and P3 so as to be rotatable.
Further, the rectangular panels P10 and P4 are connected to the connecting holes 6 of the connecting rings RD, RD,... Arranged on the parallel end face 1D (side end face 1D) of the rectangular panel P10, and the parallel end face 1C (side of the rectangular panel 4). A ring alignment group RG13 is formed between the rectangular panels P10 and P4 with the connection holes 6 of the connection rings RC, RC,... Arranged on the end face 1C) facing each other. The connection shaft S is inserted through the connection holes 6 of the connection rings RC and RD of the ring alignment group RG13 to connect the rectangular panels P10 and P4 so as to be rotatable.

  The rectangular panel P11 constitutes the back surface 101E. As shown in FIGS. 5 to 11, the rectangular panel P11 is arranged orthogonal to the rectangular panels P3, P5, P7, and P9, and is connected to the rectangular panels P3, P5, P7, and P9.

  The rectangular panels 11, P3 are connected to the connecting holes 6 of the connecting rings RB, RB,... Arranged on the parallel side end face 1B (side end face 1B) of the rectangular panel P11, and the parallel side end face 1A (side end face 1A) of the rectangular panel P3. ), The ring alignment group RG14 is formed between the rectangular panels P11 and P3. The connecting shaft S is inserted through the connecting holes 6 of the connecting rings RA and RB constituting the ring alignment group RG12 to connect the rectangular panels P11 and P3 so as to be rotatable.

  Each rectangular panel P11, P5 includes a connecting hole 6 of each connecting ring RB, RB,... Arranged on the parallel side end face 1B (side end face 1B) of the rectangular panel P11, and a parallel side end face 1A (side end face 1A) of the rectangular panel P5. The ring alignment group RG15 is formed between the rectangular panels P11 and P5 so that the connection holes 6 of the connection rings RA, RA,. The connecting shaft S is inserted through the connecting holes 6 of the connecting rings RA and RB constituting the ring alignment group RG15 to connect the rectangular panels P11 and P5 so as to be rotatable.

  Each rectangular panel P11, P7 has a connecting hole 6 in each connecting ring RD, RD,... Arranged on a parallel side end face 1D (side end face 1D) of the rectangular panel P11, and a parallel side end face 1A (side end face 1A) of the rectangular panel P7. The ring alignment group RG16 is formed between the rectangular panels P11 and P7 so that the connection holes 6 of the connection rings RA, RA,. The connection shaft S is inserted through the connection holes 6 of the connection rings RD and RA constituting the ring alignment group RG16 to connect the rectangular panels P11 and P7 so as to be rotatable.

  Each rectangular panel P11, P9 is connected to a connecting hole 6 of each connecting ring RC, RC,. The ring alignment group RG17 is formed between the rectangular panels P11 and P5 so that the connection holes 6 of the connection rings RB, RB,. The connection shaft S is inserted through the connection holes 6 of the connection rings RC and RB constituting the ring alignment group RG17 to connect the rectangular panels P11 and P9 so as to be rotatable.

The panel unit PU2 connects the respective rectangular panels P3, P4,..., P11 with the ring alignment groups RG2 to RG17, and constitutes a panel cuboid 101 that opens to the front surface.
As shown in FIGS. 5 to 9, the connecting shafts S, S,... Connect the rectangular panels P3 to P11 so as to be pivotable by the ring alignment groups RG2 to RG17, and connect the rectangular panels P3 to P11 to the panel. Hold in the rectangular parallelepiped 101.

<Application example>
As shown in FIGS. 5 to 11, the panel unit PU2 is applied to, for example, an animal trap X (box cage).
The beast trap X is used, for example, for capturing beasts such as wild spiders, monkeys, and bears.
The animal trap X is composed of a panel cuboid 101, an opening / closing door 102, and a trigger device (not shown).
The panel cuboid 101 constitutes a cocoon body (hereinafter referred to as “cocoon body 101”). The cage main body 101 has a beast intrusion port 103, and the beast intrusion port 103 opens in the front surface 101 </ b> F of the panel cuboid 101.
As shown in FIGS. 5 and 6, the open / close door 102 opens and closes the beast entry port 103. The opening / closing door 102 is guided by a guide device 104. The guide device 104 is fixed to the rectangular panels P8 and P10 on the left and right side surfaces 101A and 101B on the side of the beast entry port 103.
As shown in FIG. 6, the open / close door 102 is held at a position where the beast entry port 103 is released by a trigger device (not shown). The trigger device releases the holding of the opening / closing door 103 in accordance with the invasion of the beast, whereby the opening / closing door 102 closes the beast intrusion port 103.

Panel unit PU2 of 2nd Embodiment can comprise the panel rectangular parallelepiped 101 (saddle main body) which has arbitrary volumes by increasing / decreasing the connection number of a rectangular panel.
Panel unit PU2 of 2nd Embodiment is not limited to the case where it applies to the beast capture cage X, It can apply also to the panel rectangular parallelepiped which becomes the foundations, such as a house.

<Third Embodiment>
A panel unit PU3 (hereinafter referred to as “panel unit PU3”) according to a third embodiment will be described with reference to FIGS.
12 to 18, the same reference numerals as those in FIGS. 1 to 4 denote the same members or the same components, and thus detailed description thereof will be omitted.

  12 to 18, the panel unit PU3 is configured to include one polygon panel P13, another one polygon panel P14, and a connecting shaft S.

  Each of the polygon panels P13 and P14 is configured by a rectangular panel (for example, a square panel) as shown in FIGS. 12 to 18 (hereinafter, referred to as “one rectangular panel P13, another one rectangular panel P14”). ).

  Each rectangular panel P13, P14 has a lattice panel body 22 and a plurality of connecting rings N, N,... As shown in FIGS.

The lattice panel body 22 is formed at a rectangular outer edge with a plurality of side end faces 1A to 1D.
The lattice panel body 22 includes a plurality of vertical iron wires 3, 3,..., A plurality of horizontal iron wires 5, 5,.

  Each vertical iron wire 3, 3,... Constitutes a vertical lattice, and each horizontal iron wire 5, 5,. The vertical grid and the horizontal grid are arranged with the vertical iron wires 3, 3,... And the horizontal iron wires 5, 5,. Each of the longitudinal iron wires 3, 3,... And the horizontal iron wires 5, 5,.

  As shown in FIGS. 12 and 13, the rectangular frame 31 is composed of a plurality of L-shaped frame flat steel members 23 to 26. Each frame flat steel material 23-26 has side end flat steel 23A-26A and inner side flat steel 23B-26B, and is formed in L shape by each flat steel 23A-26A, 23B-26B. Each frame flat steel material 23-26 is formed in a rectangle (for example, square) by welding.

  In the lattice panel body 22, as shown in FIG. 13, the rectangular lattice 22F is arranged in a rectangular frame 31, and the vertical iron wires 3, 3,. Weld. .. Are welded to the inner flat bars 25B and 26B of the frame flat steel members 25 and 26, respectively.

In the lattice panel body 22, the side end flat bars 23A, 24A of the frame flat steel members 23, 24 constitute the side end faces 1A, 1B (upper end face, lower end face) as shown in FIGS. .
The side end flat bars 25A and 26A of the frame flat steel members 25 and 26 constitute side end faces 1C and 1D (left end face and right end face) as shown in FIGS.
Thereby, in the lattice panel main body 22, as shown to FIG. 12 thru | or 18, each side end flat steel 23A-26A comprises several side end surface 1A-1D, and each side end surface 1A-1D is a rectangular outer edge ( For example, a square outer edge) is formed. The rectangular outer edge means a square outer edge such as a square outer edge or a rectangular outer edge.
The side end flat bars 23A and 24A of the frame flat steel members 23 and 24 constitute a pair (first pair) of parallel side end faces 1A and 1B in parallel with each other. The side end face flat bars 25A, 26A of the frame flat steel members 25, 26 constitute a pair (second pair) of parallel side end faces 1C, 1D in parallel with each other.
The side end faces 1A to 1D intersect at the end points 22A to 22D. Each of the end points 22A to 22D is a vertex of the lattice panel body 22 at the rectangular outer edge.

  Each side end flat steel 23A, 24A has a plurality of connecting screw holes 35A, 35A,..., 35B, 35B,.

Each of the connecting screw holes 35A, 35A,... Is formed in the side end flat steel 23A (side end surface 1A) at equal intervals in the horizontal direction H of the lattice panel body 2.
The hole center line 35a of each of the connecting screw holes 35A, 35A,... Is located on a straight line a1 parallel to the inner flat bar 23B in the width direction M orthogonal to the horizontal direction H and the vertical direction G of the lattice panel body 22. It is arranged on the side end flat steel 23A. The straight line a1 is set in the width direction M at a position separating the interval SA from the inner flat bar 23B.
Each of the connecting screw holes 35A, 35A,... Penetrates (penetrates) the side end flat bar 23A in the longitudinal direction G of the lattice panel body 2.

Each of the connecting screw holes 35B, 35B,... Is formed in the side end flat steel 24A (side end surface 1B) at equal intervals in the horizontal direction H of the lattice panel body 22.
The hole center line 35b of each of the connecting screw holes 35B, 35B,... Is positioned on the side end flat bar 24A in the width direction M of the lattice panel body 22 and located on a straight line a2 parallel to the inner flat bar 24B. The straight line a2 is set in the width direction M at a position separating the interval SA from the inner flat bar 24B.
Each of the connecting screw holes 35B, 35B,... Penetrates (penetrates) the side end flat bar 24A in the longitudinal direction G of the lattice panel body 2.

  In the lattice panel body 22, the connecting screw holes 35A, 35A,... And the connecting screw holes 35B, 35B,. Staggered arrangement is made on flat steels 23A, 24A (each side end face 1A, 1B).

  Each side end flat steel 25A, 26A has a plurality of connecting screw holes 35C, 35C,..., 35D, 35D,.

The connecting screw holes 35C, 35C,... Are formed in the side end flat steel 25A at equal intervals in the longitudinal direction G of the lattice panel body 2.
The hole center line 35c of each of the connecting screw holes 35C, 35C is located on the side end flat bar 25A in the width direction M of the lattice panel body 22 and located on a straight line a3 parallel to the inner flat bar 25B. The straight line a3 is set in the width direction M at a position separating the interval SB from the inner flat bar 25B.
Each of the connecting screw holes 35C, 35C,... Penetrates (penetrates) the side end flat steel 25A in the lateral direction H of the lattice panel body 22.

The connection screw holes 35D, 35D,... Are formed in the side end flat steel 26A (side end surface 1C) at equal intervals in the longitudinal direction G of the lattice panel body 22.
The hole center line 35d of each of the connecting screw holes 35D and 35D is located on the side end flat bar 26A in the width direction M of the lattice panel body 22 and located on a straight line a4 parallel to the inner flat bar 26B. The straight line a4 is set in the width direction M at a position separating the interval SB from the inner flat bar 26B.
Each of the connecting screw holes 35D, 35D,... Penetrates (penetrates) the side end flat steel 26A in the lateral direction H of the lattice panel body 22.

  In the lattice panel main body 22, the connection screw holes 35C, 35C,... And the connection screw holes 35D, 35D,. Staggered arrangement is made on flat steel 25A, 26A (each side end face 1C, 1D).

  In the lattice panel body 22, the distances SA and SB between the straight lines a1 to a4 are set to values that allow the hole center lines 35a to 35d of the connecting screw holes 35A to 35D to be arranged on the same plane HB.

  As shown in FIGS. 12, 12, 16, and 17, the connecting rings N, N,... Follow the side end flat bars 23A to 26A (each side end face 1A to 1D) of each rectangular panel P1, P2. Several are arranged. Each connection ring N, N,... Has a connection hole 28 and a screw shaft 29. The connection hole 28 is formed as, for example, a long hole (hereinafter referred to as “connection long hole 28”).

In the side end flat steel 23A (side end surface 1A), a plurality of connecting rings N, N,... (Hereinafter referred to as “connecting ring NA”), as shown in FIG. Threaded onto 35A, 35A,... And fixed to the side end flat steel 23A.
Thereby, each connection ring NA, NA,... Is held by the lattice panel body 22 of each rectangular panel P13, P14.
As shown in FIGS. 16 and 17, each of the connection rings NA, NA,... Is located on a straight line Ab parallel to the side end flat bar 23A and the side center flat bar 23A. Are arranged at equal intervals between the two end points 22A and 22B. The straight line γ1 is set at a position separating the interval TB from the side end flat bar 23A in the direction G orthogonal to the side end flat bar 23A (side end surface 1A).
Further, in each of the connection rings NA, NA,..., The connection long hole 28 extends in the direction G perpendicular to the straight line γ1 and the side end flat steel 23A (side end surface 1A), and is connected along the hole center line γ1. The NA is inserted (penetrated) (see FIG. 17).

In the side end flat steel 24A (side end surface 1B), a plurality of connecting rings N, N,... (Hereinafter referred to as “connecting rings NB”), as shown in FIG. , 35B,... Are fixed to the side end flat steel 24A.
Thereby, each connection ring NB, NB,... Is held by the lattice panel body 22 of each rectangular panel P13, 14.
As shown in FIGS. 16 and 17, each of the connecting rings NB, NB,... Is located on a straight line Bb parallel to the side end flat bar 24A and the side center flat bar 24A. Are arranged at equal intervals between the two end points 22C and 22D. The straight line γ2 is set at a position separating the interval TB from the side end flat bar 24A in the direction G perpendicular to the side end flat bar 24A (side end surface 1B).
Further, in each of the connecting rings NB, NB,..., The connecting long hole 28 extends in the direction G orthogonal to the straight line γ2 and the side end flat steel 25A (side end surface 1B), and is connected along the hole center line γ2. The NB is inserted (see FIG. 17).

In the side end flat steel 25A (side end surface 1C), a plurality of connecting rings N, N,... (Hereinafter referred to as “connecting ring NC”), as shown in FIG. It is screwed to 35C, 35C,... And fixed to the side end flat steel 25A.
Thereby, each connection ring NC, NC,... Is held by the lattice panel body 22 of each rectangular panel P13, P14.
As shown in FIGS. 16 and 17, each of the connecting rings NC, NC,... Is located on a straight line Cb parallel to the side end flat bar 25A and the side center flat bar 25A. Are arranged at equal intervals between the two end points 22A and 22C. The straight line γ3 is set at a position separating the interval TB from the side end flat bar 25A in the direction H orthogonal to the side end flat bar 25A (side end surface 1C).
Further, in each of the connecting rings NC, NC,..., The connecting elongated hole 28 extends in a direction H orthogonal to the straight line γ3 and the side end flat steel 25A (side end surface 1C), and connects the connecting ring NC along the straight line γ3. Insert (through) (see FIG. 17).

In the side end flat steel 26A (side end surface 1D), a plurality of connecting rings N, N,... (Hereinafter referred to as “connecting ring ND”), as shown in FIG. Threaded onto 35D, 35D,... And fixed to the side end flat steel 26A.
Thereby, each connection ring ND, ND,... Is held by the lattice panel body 22 of each rectangular panel P13, P14.
As shown in FIGS. 16 and 17, each of the connecting rings ND, ND,... Is located on a straight line Db parallel to the frame flat bar 23D and the hole center line γ4 of the connecting long hole 28, and The two end points 22B and 22D are arranged at equal intervals. The straight line Db is set at a position separating the interval TB from the side end flat bar 26A in the direction H orthogonal to the side end flat bar 26A (side end surface 1D).
Further, in each of the connection rings ND, ND,..., The connection elongated hole 28 extends in the direction H perpendicular to the hole center line γ4 and the frame flat steel 23D (side end surface 1D), and extends along the straight line γ4. Is inserted (penetrated) (see FIG. 17).

In the lattice panel body 22, the connection rings NA, NA,... And the connection rings NB, NB,... Are arranged in a staggered manner on the side end flat bars 23A, 24A (parallel side end surfaces 1A, 1B).
The connecting rings NC, NC,... And the connecting rings ND, ND,... Are arranged in a staggered manner on the side end flat bars 25A, 26A (parallel side end faces 1C, 1D).

In each rectangular panel P3, P4, the interval TB between the straight lines Ab to Db is set to a value that allows the center lines γ1 to γ4 of the connection rings NA to ND to be arranged on the same plane HB.
Thereby, the connection long holes 28 of the connection rings NA to ND are arranged at the same height position in the width direction M of the lattice panel body 22.

Each connection ring NA-ND is detachable with respect to each side end surface 1A-1D (each side end flat steel 24A-26A) by the screw shaft 29 and each connection screw hole 35A-35D.
Thereby, each connection ring RA-RD can be mounted | worn with arbitrary one or some side end flat steel 23A-26A (side end surface 1A-1D).
In addition, each connection ring NA-ND can also employ | adopt the structure completely fixed to each side end flat steel 24A-26A by welding.

As shown in FIGS. 12 and 18, the panel unit PU3 includes a side end flat steel 24A (side end face 1B) of one rectangular panel P13 and a side end flat steel 23A (side end face 1A) of another rectangular panel P14. The rectangular panels P13 and P14 are continuously arranged in parallel.
One rectangular panel P13 and the other rectangular panel P14 are connected to the connection holes 28 of the connection rings NB, NB,... Arranged on the side end flat steel 24A (the other parallel side end surface 1B) of the rectangular panel P13. , And the connecting holes 28 of the connecting rings NA, NA,... Arranged on the side end flat steel 23A (one parallel side end face 1A) of the other rectangular panel P14, facing each other, the rectangular panels P13, P14. A ring alignment group RG21 is formed therebetween.
As shown in FIGS. 12 and 18, the ring alignment group RG21 arranges the connection rings NA, NA,... In alignment between the connection rings NB, NB,... And connects the connection rings NB, NB,. Formed by arranging the rings NA, NA,.
As shown in FIG. 18, the connection long holes 28 of the connection rings NA, NB,... Are arranged so as to coincide with the hole center lines γ1, γ2 (straight lines Ab, Bb).

The connecting shaft S passes through the connecting elongated holes 28 of the connecting rings NA, NA,..., NB, NB,... Constituting the ring alignment group RG21, and connects the one rectangular panel P13 and the other rectangular panel P14. Connect to swivel.
Thereby, as shown in FIG. 18, one rectangular panel P13 and the other one rectangular panel P14 can be swung in the range of 360 degrees with the connecting shaft S as the swivel center.

Further, in the rectangular panel P13, the connecting rings NC, NC,... Connecting holes 28 arranged on the side end flat steel 25A (side end surface 1C) and the rectangular panel P14 are arranged on the side end flat steel 26A (side end surface 1D). A ring alignment group is formed between the rectangular panels 13 and 14 so that the connection holes 28 of the connection links ND, ND,. The connection shaft S is inserted through the connection holes 28 of the connection links NC and ND constituting the ring alignment group, so that one rectangular panel P13 and the other rectangular panel P4 can be connected to each other so as to be rotatable.
Similarly, in each rectangular panel P13, P14, the connection hole 28 of each connection ring NA, NA,... And the connection hole 28 of each connection ring ND, ND,. The connecting holes 6 and the connecting holes 28 of the connecting rings NC, NC,... Are opposed to each other, and the connecting shaft 6 is inserted into the connecting holes 28 of the connecting rings constituting the ring alignment group. The other rectangular panel P14 can be pivotably connected.

<Fourth embodiment>
Panel unit PU4 of 4th Embodiment is demonstrated with reference to FIG.19 and FIG.20.
19 and 20, the same reference numerals as those in FIGS. 1 to 18 denote the same members or the same configurations, and thus detailed description thereof will be omitted.

19 and 20, the panel unit PU4 has a plurality of rectangular panels P15, P16,..., P32 and a plurality of connecting shafts S, S,. Each rectangular panel P15, P16,..., P32 has a lattice panel body 22, a plurality of connection rings NA, NA,..., And a plurality of connection rings NB, NB,. Like the panel unit PU3, a plurality of each of the connection rings NA, NA,... Is arranged along the side end flat steel 23A (one parallel side end face 1A) and held in the lattice panel body 22. Like the panel unit PU3, a plurality of connecting rings NB, NB,... Are arranged along the side end flat steel 24A (the other parallel side end face 1B) and held in the lattice panel body 22.
Each of the rectangular panel units P15, 16,..., P32 is configured by removing the connecting rings NC, ND from the side end faces 1C, 1D (side end flat steels 25A, 26A) with respect to the rectangular panels of FIGS. To do.

In the panel unit PU4, the plurality of rectangular panels P15, P16,..., P32 are continuously arranged in parallel as shown in FIGS.
In the panel unit PU4, the rectangular panel units P15, P16,..., P32 are erected on the ground CH.
In FIG. 17, the rectangular panels P <b> 18 and P <b> 19 are arranged so as to be orthogonal to each other by turning around the connecting shaft S about the turning center. Similarly, the rectangular panels P23 and P24 and the rectangular panels P31 and P32 are arranged in parallel with each other.
Thereby, panel unit PU4 can comprise the fence etc. which comprise the panel fence, the enclosure fence which captures a wild beast, etc. by arranging several rectangular panels P15, P16, ... in parallel.

Each rectangular panel P15, P16 includes a connecting hole 28 of each connecting ring NA, NA,... Arranged on a side end flat steel 23A (another parallel side end face 1A) of the rectangular panel P15, and a side end of the rectangular panel P16. A ring alignment group RG31 is formed between the rectangular panels P15 and P16 with the connecting rings NB, NB,... Arranged on the flat steel 24A (one parallel end face 1B) facing each other. The connecting shaft S is inserted through the connecting holes 28 of the connecting rings RA and RB constituting the ring alignment group RG31 to connect the rectangular panels P15 and P16 so as to be rotatable. Further, the connecting shaft S is driven into the underground CS, and the rectangular panels P15 and P16 are erected on the ground CH.
Similarly, the rectangular panels P16, P17, P18,..., P32 are also connected to the connection holes 28 of the connection rings NA, NA,... Arranged on one parallel side surface 1A (side end flat steel 23A) and the other one. Of the parallel side end face 1B (side end flat steel 24A) of the connecting rings NB, NB,... Facing each other and the ring alignment group RG32 between the rectangular panels P16, 17, 18,. RG33,..., RG46 are formed. The connecting shafts S, S,... Are inserted into the connecting holes 28 of the connecting rings RA, RB constituting the ring alignment groups RG32, RG33,. Connect to swivel. Further, the connecting shafts S, S,... Are driven into the underground CS, and the rectangular panels P16, P17,.
Thereby, each rectangular panel P15, P16, ... is connected with each connection ring RA, RB and each connection axis S, S, ..., and divides the area HS and is arranged in parallel.
Moreover, in each rectangular panel P15, P32, each connection axis | shaft S, S passes through the connection hole 28 of each connection ring NB, NB, ..., and is driven into underground CS, Between each rectangular panel P15, P32. Form the doorway.

As shown in FIG. 18, the panel unit PU4 may have an obstacle Z such as a tree, a rock, or a house when the rectangular panels P15, P16,. At this time, in FIG. 18, each rectangular panel P25 is erected on the ground CH while avoiding the obstacle Z by turning about the connecting shafts S, S,... Connected to the rectangular panels P24, P26. it can.
In this way, in each of the rectangular panels P15, P16,..., P32, it can be partitioned into the region HS of the arbitrary fence outer edge by turning around the connection axis S of the ring alignment groups RG31 to RG46.

Further, as shown in FIG. 20, the panel unit PU4 has height adjustment rings 58 and 59, and the adjustment rings 58 and 59 are attached to the outer circumferences of the connection shafts S, S,. , P16,..., P32 are adjusted in height position.
The height adjustment ring 58 is formed in a cylindrical shape, and has an adjustment screw hole 58A and a bolt 58B that open to the inner and outer peripheral surfaces. The height adjustment ring 58 is disposed between the ground ring CH and the connection ring NA (or connection ring NB) on the ground CH side of the ring alignment groups RG31, RG32,.
The height adjustment ring 59 is formed in a cylindrical shape and is disposed between the connection rings NA and NB.
In the panel unit PU4, the height of each rectangular panel P15, P16,..., P32 is adjusted by moving the height adjusting rings 58, 59 in the axial direction G of the connecting shafts S, S,.
Subsequently, a bolt 58B is screwed into the adjustment screw hole 58A of the height adjustment ring 58, and the height adjustment ring 58 is fixed to the connecting shaft S.

In the panel unit PU4, each of the rectangular panels P15 and P16 can be inclined in the axial direction G of the connecting shaft 6 through the connecting long hole 28 as shown in FIG.
Accordingly, when there is an undulating ground (inclined ground), the rectangular panels P15, P16,..., P32 are inclined in the axial direction G of each connecting shaft S, so that the undulating ground (inclined ground) continues. Can stand.

In the panel unit PU1 of the first embodiment, as shown in FIG. 21, the connection rings RA and RB are formed integrally with the vertical iron wires 3, 3,... And the horizontal iron wires 5, 5,. The panels P1 and P2 can be held by the lattice panel body 2.
In FIG. 21, each of the connection rings RA, RB is integrally formed at both shaft ends 3a, 3B of the respective vertical iron wires 3, 3,. Each of the connecting rings RA, RA,... Forms a connecting hole 6 by bending the uniaxial end 3a side of each vertical iron wire 3, 3,. Each of the connecting rings RB, RB,... Is formed on the other shaft end 3B side of each of the vertical iron wires 3, 3,. The connecting rings RB, RB,... Are formed by bending the other end 3b of each longitudinal iron wire 3, 3,... Annularly to form a connecting hole 6, and further bent in the axial direction H of the horizontal iron wire 5. RA and RB are alternately arranged on the side end faces 1A and 1B.
The rectangular panels P1 and P2 in FIG. 19 can be applied to the panel unit P4 of the fourth embodiment, and a plurality of rectangular panels P1, P1,..., P2, P2,. .

  In panel unit P3 of 3rd Embodiment, the panel rectangular parallelepiped 101 in panel unit PU2 of 2nd Embodiment can be comprised by connecting several rectangular panel P13, P14 (refer FIG. 16).

  In the panel units PU1, PU3 of the first and third embodiments, the polygonal panels P1, P2, P13, P14 are not limited to rectangular panels, but are N-shaped (N = 3, 4, 5, 6, 7,... N: natural number) panels, such as triangles, trapezoids, pentagons, hexagons,... For example, as a polygon panel, as shown in FIG. The triangular panel TP has a triangular panel main body 61, and the triangular panel main body 61 is formed on the outer edge of the triangle by a plurality of side end faces 1A to 1C. Each side end face 1A-1C of each triangular outer edge has a plurality of connecting rings RA-RC (or NA-NC). As in FIGS. 1 to 4 and 12 to 17, a plurality of connecting rings RA to RC (NA to NC) are arranged along the side end faces 1 </ b> A to 1 </ b> C of the outer edge of the triangle to form a triangular panel body of the triangular panel TP. 61.

In the panel units PU1 to PU4 of the first to fourth embodiments, the panel body of the rectangular panel is not limited to the lattice panel bodies 2 and 22, and for example, a metal flat panel, a composite panel, or the like can be adopted.
A composite panel is a panel etc. which arrange | position a rectangular flat plate to the both end surfaces of the lattice panel main bodies 2 and 22. FIG.

In 1st and 3rd embodiment, one polygon panel P1, P13 can be comprised by a triangle panel, and another one polygon panel P2, P14 can be comprised by a rectangular panel.
Thus, one polygonal panel P1, P13 and the other polygonal panels P2, P14 have different numbers of corners, such as triangular and rectangular panels, trapezoidal and rectangular panels, pentagonal and rectangular panels, etc. Can be configured.
Further, in the panel units PU1 and PU3 of the first and third embodiments, each of the rectangular panels P1 to P4 can be configured by a panel having the same number of corners, for example, a triangular panel, a trapezoidal panel, or the like.

In the panel units YU1 and YU3 of the first and third embodiments, one rectangular panel P1 (P3) and the other rectangular panel P2 (P4) are pivotally connected by a connecting shaft S, and the connecting shaft S is turned. It can also be applied to merchandise display shelves and the like by standing in a folding screen with a predetermined angle as the center. Moreover, after connecting one rectangular panel P1 (P3) and the other one rectangular panel P2 (P4) with the connection axis | shaft S, the both ends of the connection axis | shaft S are fixed to an up-down direction, and also to partitions, such as a store Applicable.
In addition, the panel units PU1 and PU2 of the first and third embodiments can partition a private space in facilities such as a gymnasium for emergency evacuation, and can also be applied to emergency bedding beds and shelves for hanging clothes.

  The present invention is suitable for a structure such as a house, a beast trap, or a continuous panel fence that divides land into a predetermined area.

PU2 Panel unit 101 Panel rectangular parallelepiped 101A Left side surface 101B Right side surface 101C Bottom surface 101D Ceiling surface 101E Rear surface 1A-1D Side end surface 23A-26A Side end flat steel RA-RD Connection ring S Connection shaft 6 Connection hole α1-α4 Hole center line Aa- Da straight line RG2 to RG17 ring alignment group

Claims (5)

A panel unit constituting a panel rectangular parallelepiped composed of left and right side surfaces, a ceiling surface, a bottom surface and a back surface,
A plurality of rectangular panels having a panel main body forming a rectangular outer edge on a plurality of side end faces, and a plurality of connection rings, wherein a plurality of the connection rings are arranged along the side end faces and held on the panel main body. When,
A plurality of connecting shafts inserted through the connecting rings;
Comprising
Each of the connecting rings is
It has a connection hole, the hole center line of the connection hole is located on a straight line parallel to the side end faces, and is arranged at equal intervals between both end points of the side end faces,
The connecting hole is
Penetrates the connecting ring along the hole centerline;
The plurality of rectangular panels are:
Configure the left and right side surfaces, the ceiling surface, the bottom surface and the back surface,
Opposing the connection holes of the connection rings arranged on the side end faces, forming a ring alignment group between the rectangular panels,
The plurality of connecting shafts are
The rectangular panels on the left and right side surfaces, the ceiling surface, the bottom surface and the back surface are pivotally connected through the connection holes of the connection rings constituting the ring alignment groups, and the rectangular panels. Is held in the panel rectangular parallelepiped. A panel body that forms a rectangular outer edge with a plurality of side end faces, and a plurality of connecting rings, and a plurality of the connecting rings are arranged along a pair of parallel side end faces that are parallel to each other, and held by the panel body. , Multiple rectangular panels,
A plurality of connecting shafts inserted through the connecting rings;
Comprising
Each of the connecting rings is
It has a connection hole, the hole center line of the connection hole is located on a straight line parallel to each parallel side end face, and is arranged at equal intervals between both end points of each parallel side end face,
The connecting hole is
Penetrates the connecting ring along the hole centerline;
The plurality of rectangular panels are:
Are arranged side by side,
Ring alignment between the rectangular panels by facing the connection holes of the connection rings arranged on the one parallel side end face and the connection holes of the connection rings arranged on the other parallel side end face Forming a group,
The plurality of connecting shafts are
A panel unit characterized in that the continuous rectangular panels are pivotally connected by inserting through the connection holes of the connection rings constituting the ring alignment groups. Each of the connecting shafts
The panel unit according to claim 2, wherein each of the rectangular panels that are driven into the ground and continuously arranged are erected on the ground. One rectangular panel having a rectangular outer edge formed by a plurality of side end surfaces, a plurality of connection rings, a plurality of the connection rings arranged along the side end surfaces, and held by the panel main body, and another one A rectangular panel of
A connecting shaft inserted into each connecting ring;
Comprising
Each of the connecting rings is
It has a connection hole, the hole center line of the connection hole is located on a straight line parallel to the side end surface, and arranged at equal intervals between both end points of each front end surface,
The connecting hole is
Penetrates the connecting ring along the hole centerline;
The one rectangular panel and the other rectangular panel are:
Opposing the connection holes of the connection rings arranged continuously on the side end face, forming a ring alignment group between the rectangular panels,
The connecting shaft is
A panel unit characterized in that the one rectangular panel and the other rectangular panel are pivotally connected by being inserted through connection holes of the connection rings constituting the ring alignment group. One polygon panel having a panel main body forming a polygonal outer edge by a plurality of side end faces, a plurality of connection rings, and a plurality of the connection rings being arranged along the side end faces and held by the panel main body. And one other polygon panel,
A connecting shaft inserted into each connecting ring;
Comprising
Each of the connecting rings is
It has a connection hole, the hole center line of the connection hole is located on a straight line parallel to the side end surface, and is arranged at equal intervals between both end points of the side end surface,
The connecting hole is
Penetrates the connecting ring along the hole centerline;
The one polygon panel and the other polygon panel are:
Facing the connection holes of each of the connection rings arranged continuously on the side end face, forming a ring alignment group between the polygon panels;
The connecting shaft is
A panel unit characterized in that the one polygon panel and the other polygon panel are pivotally connected by inserting through the connection holes of the connection rings constituting the ring alignment group.

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