JP2015163127A - Display rack and display rack system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display rack and a display rack system to be easily assembled.SOLUTION: A display rack 10 includes: a cylindrical body 20 to be deformed between an open state and a closed state; an upper plate 30 that is arranged on the upper side of the cylindrical body 20 and on which display articles are to be placed; middle cores 40 arranged inside the cylindrical body 20; and a lock part 50 for locking a movement between the middle cores 40 and the upper plate 30 in the closed state of the cylindrical body 20. Interlocking is obtained among the relative movement of opposing plates 21a, 21b of the cylindrical body 20, the rotation of the upper plate 30 around an upper plate hinge 35, the rotation of the cylindrical body 20 between the opposing plates 21a, 21b and the middle cores 40, and the rotation of middle core bodies 41a, 41b of the middle cores 40 around middle core hinges 45.

Description

  The present invention relates to a foldable display stand and a display stand system.

Conventionally, there has been a display stand assembled from the folded state at the time of use (for example, Patent Document 1).
However, when the conventional display stand is assembled, it is necessary to combine many parts. For this reason, the conventional display stand is complicated to assemble.

Japanese Patent No. 4286932

  An object of the present invention is to provide a display stand and a display stand system that can be easily assembled.

  The present invention solves the problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this. In addition, the configuration described with reference numerals may be improved as appropriate, or at least a part thereof may be replaced with another configuration.

-1st invention is a cylinder (20,320) which deform | transforms between an open state and a closed state, The upper board (30) which is provided in the upper side of the said cylinder and can mount a display, A central core (40, 240, 340) disposed inside the cylindrical body, and a lock portion (50) for locking movement between the central core and the upper plate when the cylindrical body is in a closed state, The cylindrical body is formed by connecting a plurality of plate portions (21a to 21f), and a pair of opposed plate portions (21a, 21b) arranged to face each other in parallel, and the plurality of plate portions, Cylindrical hinges (22a to 22f) that can be deformed are provided, and the upper plate is connected to the opposing plate portion of the cylindrical body by two cylindrical body-upper plate hinges (34a, 34b), respectively. Connected and provided with an upper plate hinge (35) for rotatably connecting the two parts of the upper plate, The middle core is located at the same position between the lower end of the middle core and the lower end of the cylindrical body, and is provided with two middle core-cylindrical hinges (44a, 44b) with respect to the opposing plate portion of the cylindrical body. A central hinge (45) that is connected and rotatably connects the two portions (41a, 41b, 341) of the central core, and when the cylindrical body is open, the two portions of the central core are In a bent state, the upper end of the center core is in contact with the lower surface of the upper plate, and when the cylindrical body is in a closed state, the two portions of the center core rotate around the center core hinge, thereby opening the center core. Folded flatter than the state, relative movement of the opposed plate portion of the cylinder, rotation of the upper plate around the upper plate hinge, and between the opposed plate portion and the central core of the cylinder The rotation and the rotation around the central hinge of the two parts of the central core are linked. Is a display stand which is characterized in.
-2nd invention is the display stand of 1st invention, The said lock | rock part (50) is the upper board notch (32c) provided in the lower side of the said upper board (30), and said center core ( 40, 240, 340), and a center notch (42c) that engages with the upper plate notch.
-3rd invention is the display stand of 2nd invention, The said lock part (50) is the said upper-plate notch according to a deformation | transformation from the open state of the said cylinder (20,320) to a closed state. (32c) and the center core notch (42c) approach to each other, and a guide portion (32d) provided to widen the opening of the upper plate notch is provided.
The fourth invention is the display stand of any one of the first to third inventions, wherein the cylindrical body (320) plate portion (21c to 21f) different from the opposing plate portion is attached to the inside. It is a display stand characterized by including a biasing member (360) that biases.
The fifth invention is the display stand according to the fourth invention, wherein the core (340) includes escape holes (326L, 326R) for escaping the biasing member (360). It is.
-6th invention is the cylinder (20, 320) which deform | transforms between an open state and a closed state, and the urging member (360) which urges | biases the said cylinder from a closed state to an open state, An upper plate (30) provided on the upper side of the cylindrical body (20, 320) and on which a display object can be placed; and a center core (40, 240, 340) disposed inside the cylindrical body. The cylindrical body is formed by connecting a plurality of plate portions (21a to 21f), and between a pair of opposed plate portions (21a, 21b) arranged in parallel and opposed to the plurality of plate portions. And cylinder hinges (22a to 22f) that connect the deformation, and the upper plate has two cylinder-upper plate hinges (34a, 34b), comprising an upper plate hinge (35) rotatably connecting the two parts of the upper plate, The urging member urges one of the plate portions of the cylindrical body that is different from the opposing plate portion (21c to 21f) to the inside, and the central core includes the lower end of the central core and the lower end of the cylindrical body. Are connected to the opposing plate portion of the cylindrical body by two core-cylinder hinges (44a, 44b), respectively, and the two portions (41a, 41b, 341) of the central core are connected. ) In a rotatable manner, and a relief hole (426L, 426R) for escaping the urging member. When the cylindrical body is in an open state, the two parts of the core are bent. The upper end of the center core is in contact with the lower surface of the upper plate, and when the cylindrical body is in a closed state, the two portions of the center core are folded by rotating around the center core hinge, The relative movement of the opposing plate portion of the cylindrical body and the upper plate height of the upper plate. The rotation around the center of the cylinder, the rotation between the opposing plate portion and the center of the cylindrical body, and the rotation around the center hinge of the two portions of the center are interlocked. It is a display stand.
-7th invention is a display stand system (1) provided with the display stand (10,210,310) of any one of 1st to 6th invention, and the display part (70) engaged with the said display stand. The display unit is a box that can accommodate the folded display stand by reversing the front and back and assembling the display stand system.

  According to the present invention, a display stand and a display stand system that can be easily assembled can be provided.

It is a perspective view of the display stand system 1 of 1st Embodiment. It is a perspective view explaining the internal structure of the display state of the display stand 10 of 1st Embodiment. It is a perspective view of the folding state of the display stand 10 of 1st Embodiment. It is a figure which shows typically the top view of the display stand 10 of the display state of 1st Embodiment, sectional drawing seen from the near side Y1, and sectional drawing seen from the left side X1. It is a figure which shows typically the top view of the display stand 10 of the folding state of 1st Embodiment, sectional drawing seen from the near side Y1, and sectional drawing seen from the left side X1. It is a figure explaining the composition of lock part 50 of a 1st embodiment. It is a figure explaining until it locks from the state from which the upper board notch 32c and upper board notch 42c of 1st Embodiment separated. It is a figure explaining the board | plate material of the cylinder 20 of 1st Embodiment. It is a figure explaining the board | plate material of the upper board 30 of 1st Embodiment, and the board | plate material of the center core. It is the figure which looked at the display part 70 of 1st Embodiment from the near side Y1, sectional drawing seen from the right side X2, and the figure seen from lower side Z1. FIG. 3 is a perspective view illustrating a state in which the display stand 10 of the first embodiment is accommodated in a display unit 70. It is an expanded view of the display part 70 of 1st Embodiment. It is a perspective view of the display stand 210 of 2nd Embodiment. It is a perspective view explaining the internal structure of the display state of the display stand 310 of 3rd Embodiment.

Embodiments of the present invention will be described below with reference to the drawings.
(First embodiment)
FIG. 1 is a perspective view of a display stand system 1 according to the first embodiment.
FIG. 1A is a perspective view of the display stand system 1 in a display state.
FIG. 1B is a perspective view illustrating the engagement between the display stand 10 and the display unit 70.
In the embodiment and the drawings, an XYZ orthogonal coordinate system is provided for ease of explanation and understanding. This coordinate system represents the vertical direction Z, the left-right direction X, and the depth direction Y of the display stand 10. The left-right direction X and the depth direction Y are horizontal coordinate axes. The near side Y1 in the depth direction Y is the direction in which the display surface 70a of the display unit 70 faces. In the embodiment, each direction is described in a state where the central axis of the cylindrical body 20 is arranged in parallel to the vertical direction Z and the surfaces of the opposing plate portions 21a and 21b are arranged in parallel to the left-right direction X. To do.

The display stand system 1 includes a display stand 10 and a display unit 70.
The display unit 70 engages with the upper edge of the display stand 10.
The display stand system 1 is used for, for example, sales promotion and sales of products. On the display stand 10, promotional items, products, and the like are placed. On the front side Y1 surface of the display unit 70, promotional items, advertisements, explanations, etc. of products are printed.

[Display stand 10]
The form of the display state of the display stand 10 will be described.
FIG. 2 is a perspective view illustrating an internal configuration of the display stand 10 according to the first embodiment in a display state.
FIG. 3 is a perspective view of the display stand 10 according to the first embodiment in a folded state.
FIG. 4 is a diagram schematically showing a top view of the display stand 10 in the display state of the first embodiment, a cross-sectional view seen from the front side Y1, and a cross-sectional view seen from the left side X1.
FIG. 5 is a diagram schematically showing a top view of the display stand 10 in a folded state according to the first embodiment, a sectional view seen from the front side Y1, and a sectional view seen from the left side X1.
FIG. 6 is a diagram illustrating the configuration of the lock portion 50 (the upper plate cutout 32c and the center cutout 42c) according to the first embodiment.
3 and 5 illustrate a state in which the members are opened to some extent from the folded state in order to easily understand the form of each member.
As shown in FIG. 2, the display stand 10 includes a cylindrical body 20, an upper plate 30, and two middle cores 40.
The cylinder 20 and the upper plate 30 are each formed of a plate material such as Kent paper or cardboard (see FIGS. 8 and 9).
The cylinder 20 is a member that is long in the vertical direction Z. The shape of the cylindrical body 20 viewed from the vertical direction Z is a hexagon. The cylinder 20 is deformed between an open state (see FIGS. 2 and 4) and a closed state (see FIGS. 3 and 5). When the cylindrical body 20 is in the open state, the display stand 10 is in the display state, and when the cylindrical body 20 is in the closed state, the display base 10 is in the folded state.

The cylinder 20 includes plate portions 21a to 21f and cylinder hinges 22a to 22f.
The plate portions 21 a to 21 f (two opposing plate portions 21 a and 21 b and four swash plate portions 21 c to 21 f) form a main part of the cylindrical body 20. The plate portions 21a to 21f are plate-shaped extending in the vertical direction Z.
The upper ends of the plate portions 21 a to 21 f protrude from the upper plate 30. Therefore, the promotional material placed on the upper plate 30 is difficult to fall.
Cylindrical hinges 22a-22f connect each plate part 21a-21f rotatably.

As shown in FIG. 4A, the cross-sectional shape of the cylindrical body 20 viewed from the vertical direction Z is as follows.
The cylindrical body 20 is line symmetric with a center line parallel to the left-right direction X as an axis of symmetry. The cylindrical body 20 is line symmetric with a center line parallel to the depth direction Y as the axis of symmetry.
The sides formed by the opposing plate portions 21a and 21b are parallel. That is, the pair of opposed plate portions 21a and 21b are arranged to face each other in parallel. The lengths of these sides are the same.
The lengths of the four oblique sides formed by the swash plate portions 21c to 21f are the same.

As shown in FIG. 2, the upper plate 30 is provided on the upper side Z <b> 2 of the cylindrical body 20. In the display state, the upper surface of the upper plate 30 is horizontal. The upper plate 30 is accommodated so that it can be accommodated in the cylinder 20.
2 and 6, the upper plate 30 includes a front piece 31a, a back piece 31b, lower pieces 32a and 32b, folded pieces 33a and 33b, hinges 34a and 34b (cylindrical body-upper plate hinge), A plate hinge 35 is provided.
The front piece 31a and the back piece 31b (two portions of the upper plate) are portions of the upper plate 30 that form the front side Y1 and the back side Y2 with respect to the upper plate hinge 35.

The lower pieces 32a and 32b are respectively connected to the edge on the back side Y2 of the front piece 31a and the edge on the front side Y1 of the back piece 31b toward the lower side Z1.
3 and 5, the lower pieces 32a and 32b are not shown. Further, in FIG. 6, the front piece 31a, the back piece 31b, and the lower pieces 32a and 32b are illustrated in an integrated configuration.
As shown in FIG. 6, the lower pieces 32a and 32b include an upper plate notch 32c and an upper plate guide portion 32d.
The upper plate cutout 32c is a cutout that engages with a core cutout 42c (described later). The upper plate notch 32 c is disposed on the lower side Z <b> 1 of the upper plate 30. The upper plate guide portion 32d has a shape that widens the gap between the upper plate cutouts 32c toward the lower end edges of the lower pieces 32a and 32b.

As shown in FIG. 2, the folding pieces 33a and 33b are respectively connected to the edge on the front side Y1 of the front piece 31a and the edge on the back side Y2 of the back piece 31b. That is, the folding pieces 33a and 33b are provided at the edge of the upper plate 30 on the opposing plate portions 21a and 21b side.
The folding pieces 33a and 33b are bonded to the inner surfaces of the opposing plate portions 21a and 21b, respectively. Thereby, the upper plate 30 is attached to the cylindrical body 20.

The hinge 34a is a connection portion between the front piece 31a and the folding piece 33a, that is, a connection portion between the front piece 31a and the opposing plate portion 21a. The hinge 34a connects the front piece 31a and the opposing plate portion 21a so as to be rotatable around the axis in the left-right direction X.
Similarly, the hinge 34b is a connection part between the back piece 31b and the folding piece 33b, that is, a connection part between the back piece 31b and the counter plate part 21b. The hinge 34b connects the back piece 31b and the counter plate portion 21b so as to be rotatable around the axis in the left-right direction X.

  The upper plate hinge 35 is provided on a center line parallel to the left-right direction X of the upper plate 30. That is, the upper plate hinge 35 is provided on a line parallel to the opposing plate portions 21a and 21b. The upper plate hinge 35 connects the front piece 31a and the back piece 31b so that they can be folded into two folded folds.

  The shape of the upper plate 30 viewed from the vertical direction Z is a hexagon that fits inside the cylindrical body 20. That is, the length of each side of the upper plate 30 is equal to the length of each plate portion 21 a to 21 f of the cylindrical body 20. Similar to the cylinder 20, the upper plate 30 is axisymmetric with respect to a center line parallel to the left-right direction X (that is, the upper plate hinge 35) as a symmetry axis, and has a center line parallel to the depth direction Y as a symmetry axis. It is line symmetric.

As shown in FIGS. 2 and 4, the core 40 is disposed inside the cylindrical body 20. The middle core 40 is disposed inside the cylindrical body 20 so as to extend in the vertical direction Z.
The two cores 40 have a symmetrical shape. Further, each of the cores 40 is line symmetric in the depth direction Y via the center line. In the vertical direction Z, the position of the lower end of the center core 40 and the position of the lower end of the cylindrical body 20 are the same.

Each core 40 includes a center core body 41a, 41b (two portions of the center core), a center core notch 42c, a center guide portion 42d, folding pieces 43a, 43b, hinges 44a, 44b (between the center core and the cylinder). Hinge) and a center hinge 45.
The center core main bodies 41 a and 41 b are main body portions of the center core 40. The core bodies 41a and 41b have the same shape. The center core bodies 41a and 41b are rotatably connected by a center core hinge 45.

  The center core notch 42c is provided at the upper end of the connecting portion (that is, the center core hinge 45) of the center core bodies 41a and 41b. The center core notch 42c engages with the upper plate notch 32c. The center guide portion 42d has a shape that widens the front end of the center core notch 42c toward the upper end edge of the center core 40 (center core bodies 41a and 41b).

  The folding pieces 43a and 43b are connected to the edge portion of the front side Y1 of the core body 41a and the edge portion of the back side Y2 of the core body 41b, respectively. The folding pieces 43a and 43b are bonded to the inner surfaces of the opposing plate portions 21a and 21b, respectively. Thereby, the core 40 is attached to the cylinder 20.

The hinge 44a is a connecting portion between the core main body 41a and the folding piece 43a, that is, a connecting portion between the core main body 41a and the counter plate portion 21a. The hinge 44a connects the core main body 41a and the counter plate portion 21a so as to be rotatable around the axis in the vertical direction Z.
Similarly, the hinge 44b is a connecting portion between the core main body 41b and the folding piece 43b, that is, a connecting portion between the core main body 41b and the opposing plate portion 21b. The hinge 44b connects the core main body 41b and the counter plate portion 21b so as to be rotatable about the axis in the vertical direction Z.
The middle core hinge 45 is a connection part of the middle core bodies 41a and 41b. The center core hinge 45 connects the center core bodies 41a and 41b so as to be rotatable about the axis in the vertical direction Z.

As shown in FIG. 6, the lock portion 50 includes the upper plate notch 32c and the core notch 42c.
The upper plate cutout 32c and the middle core cutout 42c are locked so as not to move relative to each other between the middle core 40 and the upper plate 30 by engaging with each other.

(Configuration in the display state)
The structure of the display state of the display stand 10 will be described.
・ Lock part 50
As shown in FIG. 6C, the upper plate cutout 32 c sandwiches the upper core cutout 42 c of the upper core 40. Thus, the center core 40 and the upper plate 30 are regulated so as not to move relative to each other in the left-right direction X. That is, the lock unit 50 locks the middle core 40 and the upper plate 30 so as not to move relative to each other in the left-right direction X. As will be described later, the display stand 10 is stably maintained in the display state by the lock in the left-right direction X.
As shown in FIG. 6B, the center core notch 42c sandwiches the upper plate notch 32c below the lower pieces 32a and 32b of the upper plate 30. Accordingly, the space between the center core 40 and the upper plate 30 is regulated so as not to move relatively in the depth direction Y. That is, the lock unit 50 locks the inner core 40 and the upper plate 30 so as not to move relative to each other in the depth direction Y.
As described above, the movement of the XY plane is restricted while the upper plate 30 is in contact with the upper end of the core 40.

Moreover, the display stand 10 in the display state can improve load resistance for the following reasons.
As shown in FIGS. 2 and 4, the display stand 10 in the display state is in the following state.
-The lower end of the center core 40 and the cylinder 20 contacts the installation surface.
The upper end of the core 40 contacts the lower surface of the upper plate 30.
For this reason, the load F applied to the upper surface of the upper plate 30 is mainly supported by the opposed plate portions 21 a and 21 b and the center core 40 of the cylindrical body 20.
The two core main bodies 41 a and 41 b are bent at the portion of the core hinge 45. For this reason, the core main bodies 41a and 41b can suppress buckling (bending).
Thereby, the center cores 40 respectively provided on the left and right sides can receive the load F applied to the upper surface of the upper plate 30 at the upper end of the center core 40 and can support the buckling in a suppressed state (see force F1). .

As illustrated in FIG. 4A, the core body 41 a of the left core X <b> 1 40 is connected to the end of the opposing plate portion 21 a of the cylindrical body 20. For this reason, in terms of function, the position of the hinge 44a and the position of the cylindrical hinge 22a are the same. That is, the three plate materials (the core body 41a and the plate portions 21a and 21c of the cylindrical body 20) are connected to the same shaft. Thereby, these plate materials are effectively reinforced because buckling and the like are suppressed. This is because the reinforcing effect is greater when three plate members are connected than when two plate members are connected. Similarly, the core main body 41b and the plate portions 21b and 21d of the cylindrical body 20 are effectively reinforced.
The same applies to the center core 40 of the right side X2 and the plate portions 21a, 21b, 21e, and 21f of the cylindrical body 20.

In this way, the left and right cores 40 can be supported in a state in which buckling is suppressed by receiving the load F applied to the upper surface of the upper plate 30. For this reason, the display stand 10 can improve load resistance.
Moreover, the lock part 50 suppresses distortion etc. of the display stand 10, and each board | plate material of the cylinder 20 is suppressed buckling etc. Thereby, the display stand 10 can improve the whole rigidity.

(Deformation from folded to display)
FIG. 7 is a diagram illustrating the state from the state in which the upper plate notch 32c and the upper plate notch 42c are separated from the first embodiment until they are locked.
In order to deform the display stand 10 from the folded state to the display state, the operator only has to widen the opposing plate portions 21a and 21b so as to be separated from each other.
In response to this, each member acts as follows.
・ Cylinder 20
The swash plate portions 21c and 21d rotate and open around the hinge 22b, and the swash plate portions 21e and 21f rotate and open around the hinge 22e. That is, the swash plate portions 21c to 21f are opened from the closed state. Thereby, the cylinder 20 deform | transforms from an open state to a closed state.

-Upper plate 30
The front piece 31a and the back piece 31b are opened by rotating around the hinges 34a and 34b and the upper plate hinge 35.
The hinges 34a and 34b and the upper plate hinge 35 are parallel in the axial direction. For this reason, in the XY cross section seen from the perpendicular direction Z, the upper board 30 maintains the state by which the two opposing board parts 21a and 21b are arrange | positioned in parallel.

・ Core 40
The center core bodies 41a and 41b rotate around the hinges 44a and 44b and the center core hinge 45 and are opened from the closed state.
Further, the axial center direction of the central hinge 45 and the cylindrical hinges 22b (hinge 44a) and 22c (hinge 44b) of the central core 40 of the left side X1 are parallel. Furthermore, the core main bodies 41a and 41b and the swash plate portions 21c and 21d are plate materials. Therefore, in the process in which the display stand 10 is deformed from the folded state (the state shown in FIG. 5A) to the display state (the state shown in FIG. 4A), the rotation axes of the hinges 44a and 44b and the center core hinge 45 are , Maintain parallel to each other. for that reason. From the upper end to the lower end, the core main bodies 41a and 41b and the swash plate portions 21c and 21d are deformed integrally while maintaining a substantially rhombus shape. For this reason, the center core 40 and the swash plate portion are rarely opened on one side (for example, the lower end side) wider than the other end side (for example, the upper end side).
The same applies to the core bodies 41a and 41b and the swash plate portions 21e and 21f on the right side X2.
In addition, as described above, in the XY cross section, the two opposing plate portions 21a and 21b are arranged in parallel.
As a result, the opposing plate portions 21a and 21b move in parallel so as to be separated from each other in the depth direction Y while maintaining a relative position in the XZ plan view viewed from the depth direction Y.

Lock part 50 (upper plate cutout 32c, center core cutout 42c)
As shown in FIG. 7A, in the vertical direction Z, the upper plate cutout 32c moves toward the lower side Z1, while the core cutout 42c does not move. Further, in the left-right direction X, the upper plate notch 32c does not move, while the center core notch 42c moves toward the outside in the left-right direction X. For this reason, both approach.
As shown in FIG. 7B, when the two continue to approach each other, the inner portion of the core notch 42c comes into contact with the upper plate guide portion 32d (see point 42e). For this reason, the center core notch 42c moves along the upper plate guide portion 32d while deforming the periphery of the upper plate guide portion 32d and the periphery of the center core notch 42c.
As shown in FIG. 7C, when the upper plate notch 32c and the center core notch 42c are engaged, the space between the upper plate 30 and the center core 40 is locked.
In order to release the lock, it is necessary to deform the periphery of the upper plate guide portion 32d and the periphery of the core notch 42c. For this reason, the lock is strong. In addition, in a state where the display object is placed on the upper plate 30, the upper plate 30 does not normally move to the upper side Z2. For this reason, the lock is difficult to be released.
The cylindrical body 20, the upper plate 30, and the center core 40 are interlocked with rotation around each hinge. For this reason, the cylinder 20 can maintain the hexagonal shape stably by locking the movement between the core 40 and the upper plate 30.

  Although illustration is omitted, even if the positions of the center core notch 42c and the lower pieces 32a and 32b of the upper plate 30 are shifted in the depth direction Y, the center guide portion 42d does not move the lower pieces 32a and 32b. It can be led to the center core notch 42c.

Thus, if the opposing plate portions 21a and 21b are widened so as to be separated from each other, rotation around the upper plate hinge 35 of the upper plate 30 and rotation between the opposing plate portions 21a and 21b and the center core 40 of the cylindrical body 20 The rotation around the center hinge 45 of the two portions of the center core 40 is interlocked. And the opposing board parts 21a and 21b move in parallel as above-mentioned.
Thereby, since the display stand 10 can be easily deformed from the folded state to the display state, it can be easily assembled. Moreover, the display stand 10 can be stably maintained by being locked by the lock unit 50. Furthermore, the display stand 10 can be assembled without combining other parts.

  In addition, although the above demonstrated the example which deform | transforms the display stand 10 into a display state by expanding the opposing board parts 21a and 21b so that it may space apart, it is not limited to this. As described above, the deformation of the cylindrical body 20, the upper plate 30, and the center core 40 are interlocked. For this reason, the operator can deform | transform the display stand 10 into a display state by deform | transforming a part of the cylinder 20, the upper board 30, and the center core 40. FIG. For example, the operator may apply a force to the inside of the left and right direction X with respect to the swash plate portions 21c and 21d and the swash plate portions 21e and 21f of the cylindrical body 20, and the core main bodies 41a and 41b may be You may open around the center core hinge 45. FIG.

(Deformation from display state to folded state)
A method for folding the display stand 10 will be described.
The worker only needs to perform the reverse operation of the “deformation from the display state to the folded state”.
That is, the opposing plate portions 21a and 21b may be deformed so as to approach each other. In this case, when the upper plate 30 is lifted to the upper side Z2, the upper plate notch 32c and the center core notch 42c are separated from each other, and the lock portion 50 is easily unlocked.
Thereby, the cylindrical body 20, the upper plate 30, and the center core 40 are deformed in reverse to the above-described “deformation from the display state to the folded state”.

・ Cylinder 20
The swash plate portions 21c, 21d, 21e, and 21f are deformed into a closed state.
-Upper plate 30
The front piece 31a and the back piece 31b are closed.
Also in this case, the two opposing plate portions 21a and 21b are maintained in a state of being arranged in parallel.
・ Core 40
The center core bodies 41a and 41b are folded more flat than the open state by rotating around the center core hinge 45.

Also in this case, the opposing plate portions 21a and 21b move in parallel so as to approach each other in the depth direction Y while maintaining the relative position in the XZ plan view viewed from the depth direction Y.
As described above, the display stand 10 is deformed into a folded state.
In addition, when transforming into the folded state, the operator can transform the display stand 10 into the folded state by deforming part of the cylindrical body 20, the upper plate 30, and the core 40.

Next, specific examples of each part constituting the display stand 10 will be described.
FIG. 8 is a diagram illustrating the plate material of the cylindrical body 20 according to the first embodiment.
FIG. 9 is a diagram illustrating the plate material of the upper plate 30 and the plate material of the core 40 according to the first embodiment.
In addition, the part folded at the time of incorporation etc., the crease | fold rule which functions as a hinge, etc. were shown with the dashed-two dotted line. That is, the hinges of the display stand 10 are formed by folding rules such as cardboard.

As shown in FIG. 8A, the cylindrical body 20 is formed by processing two plate materials. The plate material is formed of Kent paper or the like.
A reinforcing piece 20a is provided around the plate of the cylindrical body 20. Adhesive pieces 20b and 20c are provided on the left and right.

An operator can produce the cylindrical body 20 as follows.
(1) As shown in FIG. 8B, the reinforcing piece 20a of the plate material is folded inward, and the reinforcing piece 20a and the plate portions 21a to 21f are bonded together. Further, the left and right adhesive pieces 20b, 20c are folded inward at the ruled line (hinge) portion.
(2) Adhesive pieces 20b of two plate materials are bonded together. Further, the adhesive piece 20c is bonded to the inner surfaces of the swash plate portions 21c and 21f.
The cylindrical body 20 is completed through the above steps.
Since the reinforcing piece is folded at the upper end and the lower end of the cylindrical body 20, the strength is improved.
In addition, although detailed description is abbreviate | omitted, in order to improve the intensity | strength of the cylinder 20, you may affix another board | plate material suitably.

As shown in FIG. 9 (A1), the upper plate 30 is formed by processing two plate materials. The plate material is formed of cardboard or the like.
As for each board | plate material of the upper board 30, the folding piece 33a, the front piece 31a, and the lower piece 32a are arranged in order.

The operator can produce the upper plate 30 as follows.
(1) As shown in FIG. 9A2, the two upper plates 30 are folded inward at the ruled line (hinge) portion.
(2) The lower pieces 32a and 32b are bonded together.
The upper plate 30 is completed through the above steps.

As shown in FIG. 9 (B1), the two cores 40 are configured by processing two plate members having the same shape. The plate material is formed of cardboard or the like.
Each plate material of the core 40 has a folded piece 43a, a middle core body 41a, a middle core body 41b, and a folded piece 43b arranged in order.

An operator can produce the core 40 as follows.
(1) As shown in FIG. 9 (B2), the plate material of one of the cores 40 is folded at the ruled line (hinge) portion.
(2) The plate material of the other core 40 is folded at the ruled line (hinge) portion on the opposite side to the above (1).
The two cores 40 are each completed by the above process.

  The operator can manufacture the display stand 10 by bonding the cylindrical body 20, the upper plate 30, and the center core 40 that have been completed through the above steps.

[Display unit 70]
The display unit 70 will be described.
FIG. 10 is a view of the display unit 70 of the first embodiment viewed from the front side Y1, a cross-sectional view viewed from the right side X2, and a view viewed from the lower side Z1.
FIG. 11 is a perspective view illustrating a state in which the display stand 10 according to the first embodiment is accommodated in the display unit 70.

As shown in FIG. 10, the display unit 70 is a box having an opening 72 on the lower side Z1.
As described above, the display unit 70 has the cuts 71 in the plate portion on the near side Y1.
As shown in FIG. 11, the display stand system 1 can accommodate the folded display stand 10 in the display unit 70 at the time of transportation, storage, and the like.

Each dimension of the display unit 70 will be described.
As shown in FIG. 1B, the interval X71 between the notches 71 is equal to the length X21b in the left-right direction X of the opposing plate portion 21b of the cylindrical body 20. The length Z71 of the notch 71 in the vertical direction Z is equal to the length Z21b from which the opposing plate portion 21b protrudes from the upper plate 30. For this reason, the display part 70 is mounted | worn with the display stand 10 by inserting the notch 71 in the opposing board part 21b.
As shown in FIG. 11, the inner size of the display unit 70 is larger than the outer dimensions X10, Y10, and Z10 in a state where the cylindrical body 20 is folded so that the display unit 70 can accommodate the folded display stand 10. large.

The specific example of the board | plate material which comprises the display part 70 is demonstrated.
FIG. 12 is a development view of the display unit 70 of the first embodiment.
As shown in FIG. 12A, the display unit 70 includes plate portions 72a to 72d, a lid portion 73, a joint 74a, and surface fasteners 75a and 75d.
The plate portions 72a to 72d are portions constituting the left side X1, the near side Y1, the right side X2, and the back side Y2.
The cover part 73 is a part which comprises an upper surface. The lid portion 73 is a type of insertion lid having an insertion portion at the tip.
Note that the lid portion may also be provided on the lower side Z1 to close the top and bottom. In the case of this configuration, the lid portion on the lower side Z1 may be connected to the lower end of the plate portion 72d.

The joining margin 74a is a portion that connects between the plate portions 72a and 72d.
The hook-and-loop fasteners 75a and 75d are provided on the joining margin 74a and the plate portion 72d, respectively.
With the above configuration, the operator assembles the display unit 70 by closing the lid portion 73 after connecting the joint 74a and the plate portion 72d with the surface fasteners 75a and 75d so that the display surface 70a is on the outside. Can do.

As shown in FIG. 12 (B), the operator folds each member with a folding rule so that the folding direction of each member is opposite to that in FIG. 12 (A), so that the display surface 70a becomes inside, And the display part 70 can be assembled so that the back surface 70b may become an outer side. If the display stand 10 is accommodated in the display unit 70 assembled by reversing the front and back in this way, contamination on the display surface 70a can be suppressed.
That is, the exposed portion of the display unit 70 often becomes dirty during transportation, storage, and the like. Even when the back surface 70b, which is the exposed portion, becomes dirty in the state where the front and back sides are reversed in this way, the display portion 70 is unfolded once and the display surface 70a is outside as shown in FIG. Assemble as follows. For this reason, the display stand system 1 can protect the display surface 70a at the time of conveyance, accommodation, etc., and can assemble the display surface 70a in a clean state at the time of use.
This eliminates the need for a protective cover or the like at the time of transportation and storage, is low in cost, and can reduce the environmental load by reducing waste after assembly.

(Second Embodiment)
Next, a second embodiment of the present invention will be described.
In the following description and drawings, parts having the same functions as those of the first embodiment described above are given the same reference numerals or the same reference numerals at the end (the last two digits), and overlapping explanations are appropriately given. Omitted. Moreover, since the structure of a display part and an upper board is the same as that of 1st Embodiment, description is abbreviate | omitted.
FIG. 13 is a perspective view of the display stand 210 of the second embodiment.
FIG. 13A is a diagram illustrating the core 240 (240L, 240R) of the second embodiment.
FIG. 13B is a diagram illustrating a process of incorporating the core 240 (240L, 240R) of the second embodiment into the cylindrical body 20.
The display stand 210 of the second embodiment is different from the first embodiment in the configuration of the center core 240.
The length in the left-right direction X of the folding piece 243a of the center core 240L of the left side X1 is equal to the length of the opposing plate portion 21a of the cylindrical body 20.
The length in the left-right direction X of the folded piece 243b of the center core 240R of the right side X2 is equal to the length of the opposing plate portion 21b of the cylindrical body 20.
As shown in FIG. 13A, in the method of assembling the middle core 240, the folded piece 243a of the middle core 240L of the left side X1 and the folded piece 43a of the middle core 240R of the right side X2 are bonded. Further, the folded piece 243b of the middle core 240R of the right side X2 and the folded piece 43b of the middle core 240L of the left side X1 are bonded. Thus, an assembly in which the two cores 240L and 240R are integrated is completed.

As shown in FIG. 13B, after the assembly is inserted into the cylinder 20, the folded piece 243a of the center core 240L of the left side X1 and the inner surface of the counter plate portion 21a are bonded. Further, the folded piece 243b of the center core 240R of the right side X2 and the inner surface of the counter plate portion 21b are bonded.
For this reason, the display stand 210 can reinforce the opposing plate portions 21a and 21b with the folding pieces 243a and 243b of the cores 240L and 240R. For this reason, the display stand 210 can improve strength and load resistance.

(Third embodiment)
Next, a third embodiment of the present invention will be described.
FIG. 14 is a perspective view illustrating an internal configuration of the display stand 310 according to the third embodiment in a display state.
The display stand 310 includes a rubber 360 (biasing member).
The rubber 360 is a member for biasing the cylindrical body 320 from the closed state to the open state. The rubber 360 is a rubber band or the like.
The cylinder 320 includes rubber hooks 326L and 326R.
The rubber hooks 326L and 326R are portions where the rubber 360 is hooked. The rubber hooks 326L and 326R are disposed in regions corresponding to the cylindrical hinges 22b and 22e. The rubber hooks 326L and 326R can be provided by changing the shape of the adhesive piece (see the adhesive piece 20b shown in FIG. 8).

The center core 340 includes a relief hole 346.
The escape hole 346 is a hole through which the rubber 360 escapes by allowing the rubber 360 to penetrate the center core 340. The escape hole 346 can be provided by punching a region of the core body 341 that passes through the rubber 360 hooked on the rubber hooks 326L and 326R.
Thus, since the center core 340 includes the escape hole 346, the display stand 310 can arrange the rubber 360 across the center core 340.

With the above configuration, the rubber 360 urges the cylinder hinges 22b and 22e of the cylinder 320 inward in the left-right direction X. For this reason, plate portions 21c to 21f different from the opposed plate portions 21a and 21b among the plate portions of the cylindrical body 320 are urged inward in the left-right direction X. Thereby, the opposing board parts 21a and 21b are urged | biased so that it may space apart.
Further, the display stand 310 is rotated around the hinges of the cylindrical body 320, the upper plate, and the center core 340 as in the first embodiment. For this reason, the display stand 310 in the folded state is deformed by itself into the display state. Thereby, the worker can easily deform the display stand 310 from the folded state to the display state.
Note that the configuration of the third embodiment may be applied to the second embodiment.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to embodiment mentioned above, For example, various deformation | transformation and a change are possible like the deformation | transformation form etc. which are mentioned later, These are also It is within the technical scope of the present invention. In addition, the effects described in the embodiments are merely a list of the most preferable effects resulting from the present invention, and the effects of the present invention are not limited to those described in the embodiments. It should be noted that the above-described embodiment and modifications described later can be used in appropriate combination, but detailed description thereof is omitted.

(Deformation)
In the embodiment, an example in which the outer shape of the display stand is a hexagon is shown, but the present invention is not limited to this. For example, the outer shape of the display stand may be a square or a heptagon. In the case where the outer shape of the display stand is quadrangular, in the display state, the upper plate is quadrilateral, the plate portions 21c and 21d are integrated into a flat plate shape, and the plate portions 21e and 21f are integrated into a flat plate shape. do it.

  DESCRIPTION OF SYMBOLS 1 ... Display stand system 10,210,310 ... Display stand 20,320 ... Cylinder body 21a, 21b ... Opposite plate part 21c-21f ... Swash plate part 22a-22f ... Cylinder hinge 30 ... Upper plate 31a ... Front piece 31b ... Back piece 32 ... Upper plate notch 32a, 32b ... Lower piece 32d ... Upper plate guide part 34a, 34b ... Hinge 35 ... Upper plate hinge 40, 240 (240L, 240R), 340 ... Middle core 41a, 41b, 341 ... Middle Core body 42c ... Center core notch 42d ... Center core guide portions 44a, 44b ... Hinge 45 ... Center core hinge 50 ... Lock portion 70 ... Display portion 326L, 326R ... Rubber hook portion 346 ... Escape hole 360 ... Rubber

Claims (7)

A cylinder that deforms between an open state and a closed state; and
An upper plate provided on the upper side of the cylindrical body and capable of placing a display;
A core disposed inside the cylinder,
In the closed state of the cylindrical body, a lock portion that locks movement between the core and the upper plate;
With
The cylinder is
Formed by connecting a plurality of plate parts,
A set of opposing plate portions arranged oppositely in parallel;
A cylindrical hinge that connects the plurality of plate portions so as to enable the deformation,
The upper plate is
Connected to the opposing plate portion of the cylindrical body by two cylindrical body-upper plate hinges,
An upper plate hinge that rotatably connects the two parts of the upper plate,
The core is
The position of the lower end of the center core and the lower end of the cylindrical body are equal,
Connected to the opposing plate portion of the cylinder by two hinges between the core and the cylinder,
Comprising a core hinge that rotatably connects the two parts of the core;
In the open state of the cylinder,
Two portions of the core are bent,
The upper end of the core is in contact with the lower surface of the upper plate;
In the closed state of the cylinder,
By rotating the two parts of the center core around the center hinge, it is folded more flat than the open state,
Relative movement of the opposing plate portion of the cylindrical body, rotation of the upper plate around the upper plate hinge, rotation between the opposing plate portion of the cylindrical body and the central core, and 2 of the central core The rotation around the core hinge of the two parts,
Display stand featuring. The display stand according to claim 1,
The lock part is
An upper plate notch provided on the lower side of the upper plate;
A center core notch provided at an upper end of the center core and engaged with the upper plate notch;
Display stand featuring. The display stand according to claim 2,
The lock part is
According to the deformation of the cylindrical body from the open state to the closed state, the upper plate cutout and the core cutout approach,
Comprising a guide portion provided to widen the opening of the upper plate notch,
Display stand featuring. In the display stand in any one of Claims 1-3,
Comprising a biasing member that biases inward the plate portion of the cylindrical body that is different from the opposing plate portion;
Display stand featuring. The display stand according to claim 4,
The inner core has an escape hole for escaping the biasing member;
Display stand featuring. A cylinder that deforms between an open state and a closed state; and
An urging member for urging the cylindrical body to be in an open state from a closed state;
An upper plate provided on the upper side of the cylindrical body;
A core disposed inside the cylinder,
With
The cylinder is
Formed by connecting a plurality of plate parts,
A set of opposing plate portions arranged oppositely in parallel;
A cylindrical hinge that connects the plurality of plate portions so as to enable the deformation,
The upper plate is
Connected to the opposing plate portion of the cylindrical body by two cylindrical body-upper plate hinges,
An upper plate hinge that rotatably connects the two parts of the upper plate,
The biasing member is
Biasing the inside of the cylindrical plate portion that is different from the opposing plate portion,
The core is
The position of the lower end of the center core and the lower end of the cylindrical body are equal,
Connected to the opposing plate portion of the cylinder by two hinges between the core and the cylinder,
A core hinge that rotatably connects the two parts of the core; and
An escape hole for escaping the biasing member,
In the open state of the cylinder,
Two portions of the core are bent,
The upper end of the core is in contact with the lower surface of the upper plate;
In the closed state of the cylinder,
The two parts of the core are folded by rotating around the center hinge,
Relative movement of the opposing plate portion of the cylindrical body, rotation of the upper plate around the upper plate hinge, rotation between the opposing plate portion of the cylindrical body and the central core, and 2 of the central core The rotation around the core hinge of the two parts,
Display stand featuring. The display stand according to any one of claims 1 to 6,
A display unit engaged with the display stand;
A display stand system comprising:
The display unit
It is a box that can store the display stand in a folded state by assembling it upside down,
Display stand system characterized by.

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