JP2013075451A - Hollow panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hollow panel which is excellent in rigidity and toughness, allows bending processing and face-curving processing, can suppress an increase of panel weight, is excellent in heat insulating performance and sound absorbing performance, and suitable for a building material, a core material or the like.SOLUTION: The hollow panel 1 is composed of a hollow plate material which is formed by laminating flat-plate shaped exterior materials on both front/rear faces of the core material which is applied with three-dimensional processing for forming hollow structure. The core material is composed of a cap sheet 11 formed with a plurality of protrusions 11a which are swollen in hollow shapes, the exterior materials laminated on both the front/rear faces of the core material are composed of back sheets 12 which are laminated on opening sides of the protrusions 11a of the cap sheet 11, and liner sheets 13 which are laminated on apex face sides of the protrusions 11a of the cap sheet 11, the cap sheet 11 is composed of a synthetic resin, and the back sheets 12 and/or the liner sheets 13 are composed of metal.

Description

  The present invention relates to a hollow panel made of a hollow plate material obtained by laminating a flat exterior material on both front and back surfaces of a core material subjected to a three-dimensional process for forming a hollow structure, and in particular, has excellent strength and is bent. Further, the present invention relates to a hollow panel suitable for building materials, core materials, etc., which can be processed with a curved surface and is excellent in heat insulation and sound absorption.

In general, there is known a hollow panel made of a hollow plate material in which a flat outer packaging material is laminated on both front and back surfaces of a core material subjected to three-dimensional processing for forming a hollow structure.
This type of hollow panel is widely used, for example, as a building material constituting the wall surface, floor, ceiling, etc. of a building, and as a core material for doors and bodies of vehicles such as automobiles and trains.
As such a hollow panel, in order to increase the strength and rigidity of the panel, the core material may be constituted by a metal honeycomb structure or the like.

For example, Patent Document 1 proposes a “honeycomb panel” in which face plates are attached to both surfaces of a core material having a metal honeycomb structure.
Patent Document 2 proposes an “architectural panel plate” in which a calcium carbonate foam plate is adhered to the front and back of a core material formed by forming a glass wool plate into a mountain-shaped uneven surface.
Thus, by making the core material a metal honeycomb structure or an uneven structure, it was possible to increase the strength and rigidity of the entire panel while maintaining the hollow configuration of the hollow panel.

Japanese Patent No. 40225578 Japanese Patent No. 2912527

However, as described above, the hollow panel having the core material made of a metal honeycomb structure or the like has a problem that, even if the strength and rigidity of the panel are improved, the panel cannot be bent or curved. . The honeycomb structure is basically difficult to be bent or curved because of its structure. In particular, in the case of a metal honeycomb structure, such bending and curved surface processing is impossible.
For this reason, adopting a metal honeycomb structure or the like as a core material in order to obtain strength and rigidity impairs ease of processing, versatility, and expandability as a hollow panel.

In addition, if the core material of the hollow panel is made of metal, the weight of the entire panel increases, and the light weight characteristic that is one of the characteristics of the hollow panel is lost, and the transportability and workability of the panel are also impaired. There was a risk of being lost.
Furthermore, in hollow panels in which the core material is made of a metal honeycomb structure or the like, for example, the core material called a bubble panel / bubble board does not have heat insulation and sound absorption properties like a hollow panel having a bubble structure, and is used as a hollow panel・ There was also a problem that the usage phase was limited.

  The present invention has been proposed in order to solve the above-described conventional problems, and is a hollow structure in which flat-shaped exterior materials are laminated on both front and back surfaces of a core material that has been subjected to three-dimensional processing to form a hollow structure. It is a hollow panel made of plate material that is excellent in strength and rigidity, can be bent and curved, can suppress the increase in panel weight, and has excellent heat insulation and sound absorption properties. An object is to provide a suitable hollow panel.

  In order to achieve the above object, the hollow panel of the present invention is a hollow panel made of a hollow plate material obtained by laminating flat plate-shaped exterior materials on both front and back surfaces of a core material subjected to a three-dimensional process for forming a hollow structure. The core material is composed of a cap sheet formed with a plurality of protrusions that bulge in a hollow shape, and an exterior material laminated on both the front and back surfaces of the core material is laminated on the opening side of the cap sheet projections, And a liner sheet laminated on the top surface side of the protrusion of the cap sheet. The cap sheet is made of a synthetic resin, and the back sheet and / or the liner sheet is made of a metal.

According to the hollow panel of the present invention having such a structure, first, as a core material constituting the hollow panel, a cap sheet having a large number of protrusions is provided, and a back sheet is provided on the protrusion opening side of the cap sheet. Are stacked to form a so-called bubble board / bubble sheet in which the protrusions are sealed and sealed to form bubbles. The air bubble sheet has impact resistance and shock absorbing properties as a cushioning member for many sealed air bubbles, and has heat insulation and sound absorption effects due to the air bubbles sealed, and the panel as a whole has excellent heat insulation and sound absorption properties. A hollow panel can be realized.
Further, the plurality of bubbles provided in such a cap sheet are such that the bubbles are spaced apart from each other at a predetermined interval, and the cap sheet itself has flexibility and flexibility. By using the material, the hollow panel itself has a certain flexibility and flexibility, and the hollow panel can be bent or curved.
Furthermore, the cap sheet made of synthetic resin is lightweight and flexible, excellent in water resistance, durability and heat retention, can be washed with water, etc., and can be used repeatedly.

And in this invention, while forming the above cap sheets with a synthetic resin, the exterior material which consists of a back sheet and a liner sheet laminated | stacked on both surfaces of this cap sheet is used, for example from metals, such as iron, aluminum, and stainless steel. It consists of a metal plate.
A cap sheet made of a synthetic resin is excellent in flexibility and flexibility and is extremely light compared to a metal honeycomb structure and the like, and suppresses or prevents an increase in the weight of the entire hollow panel. be able to.
In addition, by using a metal plate as an exterior material composed of a back sheet and a liner sheet laminated on both sides of the cap sheet, the strength and rigidity of the entire hollow panel can be increased by the rigidity and strength of the metal plate itself, Compared with resin-made or paper-made hollow panels, a hollow panel having excellent rigidity and strength can be realized.
Furthermore, the metal plate itself has flexibility and plasticity that can be curved and bent, and can be bent and curved to be integrated with a cap sheet made of synthetic resin.

  As described above, according to the present invention, as a hollow panel made of a hollow plate formed by laminating flat plate-like exterior materials on both front and back surfaces of a core material subjected to three-dimensional processing to form an empty structure, strength and rigidity are obtained. In addition, it is possible to provide a hollow panel suitable for a building material, a core material, and the like, which is excellent in bending, can be bent and curved, can suppress an increase in panel weight, and has excellent heat insulation and sound absorption.

It is an external appearance perspective view of the panel edge part which shows the hollow panel which concerns on one Embodiment of this invention, (a) is the state before a cap sheet | seat, a back sheet | seat, and a liner sheet | seat are laminated | stacked, (b) is a cap sheet | seat and a back | bag. The state where the sheet and the liner sheet are laminated and fixed is shown. It is explanatory drawing which shows typically an example of the manufacturing process of the hollow panel which concerns on one Embodiment of this invention. BRIEF DESCRIPTION OF THE DRAWINGS In the hollow panel which concerns on one Embodiment of this invention, it is an external appearance perspective view of the panel edge part which shows the example in the case of sealing a panel end surface with the edge part of a back sheet, (a) is before sealing a panel end surface (B) shows a state in which the panel end face is sealed. It is an external appearance perspective view of the panel edge part which shows the other example in the case of sealing a panel end surface in the hollow panel which concerns on one Embodiment of this invention, (a) sealed the panel end surface with the edge part of the back sheet | seat. State (b) shows a state in which the edge of the back sheet and liner sheet is pressed to seal the panel end face. It is explanatory drawing which shows an example of the folding part of the hollow panel which concerns on one Embodiment of this invention, and has shown the principal part plane of the panel in which the folding part by which the cut (half cut) process was formed was formed. It is explanatory drawing which shows an example of the folding part of the hollow panel which concerns on one Embodiment of this invention, and is sectional drawing which shows the AA cross section of FIG. 5 by which the folding part was cut | disconnected (half cut). It is explanatory drawing which shows an example of the folding part of the hollow panel which concerns on one Embodiment of this invention, and is sectional drawing which shows the BB cross section of FIG. 5 by which the folding part was cut | disconnected (half cut). It is explanatory drawing which shows an example of the folding part of the hollow panel which concerns on one Embodiment of this invention, and has shown the case where a folding part is V-shaped. It is an external appearance perspective view which shows the state by which the hollow panel which concerns on one Embodiment of this invention was curved-surface processed. BRIEF DESCRIPTION OF THE DRAWINGS It is a principal part side view of the welding part which shows the state by which the hollow panel which concerns on one Embodiment of this invention was joined by welding, (a) is the state by which two hollow panels were welded by T shape, (b) Shows the state welded in the L-shape. BRIEF DESCRIPTION OF THE DRAWINGS It is a principal part side view of the instrument attachment part which shows the state by which another instrument etc. are attached to the hollow panel which concerns on one Embodiment of this invention via a volt | bolt, (a) is panel standing installation on both surfaces of a hollow panel. A state in which the instrument is fixed with a bolt, and (b) shows a state in which a panel standing instrument is attached to one side of the panel while the two hollow panels are integrally fixed with the bolt.

Hereinafter, embodiments of a hollow panel according to the present invention will be described with reference to the drawings.
FIG. 1 is an external perspective view of a panel end portion showing a hollow panel according to an embodiment of the present invention, (a) is a state before a cap sheet, a back sheet and a liner sheet are laminated, and (b) is a state. The cap sheet, the back sheet, and the liner sheet are shown stacked and fixed.
As shown in the figure, the hollow panel 1 according to the present embodiment is a hollow plate made of a hollow plate made by laminating a flat exterior material on both front and back surfaces of a core material that has been subjected to three-dimensional processing to form a hollow structure. It is a panel and is formed in a predetermined shape (for example, rectangular shape).

[Hollow panel]
Specifically, the hollow panel 1 according to this embodiment includes a cap sheet 11 that constitutes a core material, and a back sheet 12 and a liner sheet 13 that are exterior materials laminated on both surfaces of the cap sheet 11. It is a three-layer panel material.
The cap sheet 11 is a sheet on which a plurality of protrusions 11a bulging in a hollow shape are formed at predetermined intervals over the entire surface of the sheet material.
The back sheet 12 is a sheet laminated on the opening side of the protrusion 11 a of the cap sheet 11.
The liner sheet 13 is a sheet laminated on the top surface side of the protrusion 11 a of the cap sheet 11.

When the back sheet 12 is laminated on the cap sheet 11, the protrusion 11 a formed on the cap sheet 11 is sealed and sealed in a state in which air is sealed in the protrusion to form bubbles. Configured as a bubble sheet.
Further, by laminating the liner sheet 13 on the cap sheet 11, a planar sheet material in which the top surfaces of the plurality of protrusions 11a are covered with the liner sheet 13 and the unevenness and gaps by the plurality of protrusions are covered is configured. Will be.
Moreover, the cap sheet 11 in a state of being sandwiched between the back sheet 12 and the liner sheet 13 has a space between the plurality of protrusions 11a, and this space functions as an air layer.
The hollow panel 1 having such a structure is also called a bubble boat, a bubble sheet, etc., and air is enclosed in a large number of independent bubbles, and is excellent in heat insulation, sound absorption, impact resistance, etc. It can be used as a building material / core material used in buildings and structures that require such heat insulation, sound absorption, and impact resistance.

And about the hollow panel 1 which comprises the bubble board which consists of the above three-layer structures, in this embodiment, while the cap sheet | seat 11 consists of synthetic resins, it is set as the structure which the back sheet | seat 12 and the liner sheet | seat 13 consist of metals. .
Specifically, as shown in FIGS. 1A and 1B, a cap sheet 11 serving as a core material subjected to a three-dimensional process for forming a hollow structure is made of a synthetic resin. The back sheet 12 and the liner sheet 13 which are flat plate-like exterior materials laminated on both the front and back surfaces of the core material are metal plate members such as steel plates, copper plates, stainless steel plates, aluminum alloy plates, zinc alloy plates, etc. It is comprised by the metal plate.

The cap sheet 11 made of a synthetic resin is excellent in flexibility and flexibility and is extremely light compared to a metal honeycomb structure and the like, thereby suppressing or preventing an increase in the weight of the entire hollow panel. can do.
Further, by using the back sheet 12 and the liner sheet 13 which are exterior materials laminated on both surfaces of the cap sheet 11 as metal plates, the strength and rigidity of the entire hollow panel 1 can be increased by the rigidity and strength of the metal plate itself. In other words, a hollow panel having excellent rigidity and strength can be realized as compared with a hollow panel made of resin or paper.
The metal plates themselves constituting the back sheet 12 and the liner sheet 13 have flexibility and plasticity that can be curved and bent, and can be bent and integrated with the cap sheet 11 made of synthetic resin. Curved surface processing or the like is possible (see FIGS. 6 to 9).

  Here, examples of the material resin for forming the cap sheet 11 include polyolefin resins such as polypropylene and polyethylene, polystyrene resins such as polystyrene, polyester resins such as polyethylene terephthalate, and polyamide resins such as nylon. Can do. However, it is not limited to these.

Moreover, as a metal which forms the back sheet | seat 12 and the liner sheet | seat 13, iron, aluminum, stainless steel, copper, another alloy etc. can be mentioned, for example.
However, the kind of metal is not limited to these.
Moreover, as the metal plate for forming the back sheet 12 and the liner sheet 13, a metal plate whose surface is plated can be used.
Further, the metal plate forming the back sheet 12 and the liner sheet 13 may be a so-called punching metal or wire net having holes formed on the plate surface.

Both the back sheet 12 and the liner sheet 13 can be made of metal, but at least one of them can be made of metal as long as desired strength and rigidity can be obtained for the hollow panel 1. For example, the back sheet 12 can be made of metal and the liner sheet 13 can be made of the same synthetic resin as the cap sheet 11, and the liner sheet 13 can be made of metal and the back sheet 12 can be made of the same composition as the cap sheet 11. It can also be made of resin.
If the desired panel strength and rigidity can be secured in consideration of the use and cost of the hollow panel 1, at least one of the back sheet 12 and the liner sheet 13 may be made of metal.

In the hollow panel 1 according to this embodiment, first, the cap sheet 11 made of synthetic resin is continuously fed out into a sheet shape, for example, on the outer peripheral surface of a forming roll provided with a large number of cavity holes (not shown). The cap sheet 11 can be formed by vacuum forming a large number of protrusions 11a that are in contact with the molten resin and bulge into a hollow shape.
For the metal back sheet 12 and liner sheet 13, a metal plate having a predetermined thickness and size can be formed by rolling, for example.

Then, the cap sheet 11, the back sheet 12, and the liner sheet 13 formed in this way are formed on the front and back surfaces of the cap sheet 11 on which the protrusions are formed on a predetermined production line, for example, as shown in FIG. Further, by laminating the liner sheet 13, it can be manufactured as an integral hollow panel 1.
In the example shown in FIG. 2, the cap sheet 11 on which the protrusions 11 a are formed in advance, the back sheet 12 and the liner sheet 13 formed in a thin plate shape are conveyed on separate lines and pressed by the pressing roller R to be integrated. The hollow panel 1 is manufactured by being laminated.

Here, the cap sheet 11, the back sheet 12, and the liner sheet 13 are integrally laminated and fixed to form a single hollow panel 1.
Specifically, the cap sheet 11, the back sheet 12, and the liner sheet 13 can be integrally fixed by fusion bonding or using an adhesive.
For example, in the example shown in FIG. 2, when the cap sheet 11, the back sheet 12, and the liner sheet 13 are pressed and laminated by the pressure roller R, the cap sheet 11 is heated and melted by a heating roller (not shown). Thus, the cap sheet 11 is sandwiched between the back sheet 12 supplied to the opening side of the protrusion 11a and the liner sheet 13 supplied to the top surface side of the protrusion 11a, and the cap sheet 11 is bonded to the back sheet 12 and the liner by heat fusion. It can be fused and fixed to the sheet 13. Further, the back sheet 12 and the liner sheet 13 can be heated, and the cap sheet 11 can be melted and thermally fused by the back sheet 12 and the liner sheet 13 itself.

Alternatively, an adhesive may be applied to both the front and back surfaces of the cap sheet 11, and the back sheet 12 and the liner sheet 13 may be bonded and fixed integrally with each other via the adhesive.
For example, in the example shown in FIG. 2, the back sheet 12 and the liner sheet 13 that are pressed by the pressure roller R and the cap by applying an adhesive to both the front and back surfaces of the cap sheet 11 in the previous process leading to the pressure roller R. The sheet 11 can be fixed via an adhesive. The adhesive can also be applied to the back sheet 12 and the liner sheet 13 side.
Here, any adhesive may be used as long as it can fix the resin cap sheet 11 to the metal back sheet 12 and the liner sheet 13. For example, an epoxy-based, phenol-based, polyurethane-based thermosetting adhesive, or the like. Can be used.

In addition, the above hollow panels 1 can be formed in arbitrary sizes according to the use of a panel, a use situation, etc., and the number and the magnitude | sizes of the processus | protrusion 11a of the cap sheet 11 can also be set arbitrarily. . Moreover, the hollow panel 1 of arbitrary magnitude | sizes and shapes can be formed in a construction site etc. by cutting out the hollow panel 1. FIG.
For example, when the hollow panel 1 is used as a building material, it can be formed and cut into a size of a standard unit of building materials (for example, a size of a sub-block plate).
In manufacturing the hollow panel 1, the thicknesses of the cap sheet 11, the back sheet 12, and the liner sheet 13 can be appropriately adjusted in consideration of strength, rigidity, and the like required for the hollow panel 1. Usually, the thickness of each sheet | seat can be about 100 micrometers-1.5 mm, for example.

[Panel end face sealing]
In the hollow panel 1 in which the three sheets of the sheet material of the cap sheet 11, the back sheet 12, and the liner sheet 13 are laminated as described above, the end surface of the panel edge is the thickness of the back sheet 12 (the height of the protrusion 11a). Only open (see FIG. 1B).
Even if such a panel end face is in an open state, the use of the hollow panel 1 is not hindered, but by covering the panel end face with a face material or the like and sealing it, The space can be closed and sealed, and the heat insulation, sound absorption, and heat retention as a hollow panel can be further improved. In addition, it is possible to prevent inconvenience such as foreign matter entering the hollow panel 1.
In addition, by sealing and sealing the panel end face, it becomes possible to fill and circulate air or liquid in the internal space of the hollow panel 1, and the hollow panel 1 can function as a kind of radiator, It can be configured as a means / heating means.

Therefore, in the hollow panel 1 of the present embodiment, the open part of the panel end surface can be sealed and sealed.
Specifically, in this embodiment, as shown in FIG. 3, the back sheet 12 is formed so that the outer shape of the back sheet 12 is larger than the cap sheet 11 and the liner sheet 13 by the panel thickness (projection height). The 12 edge portions 12a are bent toward the cap sheet 11 so that the open end surface of the hollow plate material is sealed (see FIG. 3B).
In this way, the panel end face can be sealed simply by bending the edge 12a of the backsheet 12, and the panel end face can be closed and sealed easily and quickly without preparing a separate sealing member or the like. Can do.

Further, by bending the edge 12a of the back sheet 12 and sealing the panel end surface in this way, the edge 12a of the back sheet 12 and the edge of the liner sheet 13 are adjacently opposed or abutted. Therefore, the edge part of the back sheet 12 and the liner sheet | seat 13 of metal plates can be joined and sealed by welding.
Thereby, the sealing of the panel end face can be made a more complete sealed state, the heat insulating property and sound absorbing property of the hollow panel 1 can be further improved, and the hollow panel 1 is used as the above-described radiator. Also suitable.

In the example shown in FIG. 3 described above, the edge of the back sheet 12 is extended and bent. However, the same applies to the case where the edge of the liner sheet 13 is extended and bent. Needless to say.
Further, the edge portion of both the back sheet 12 and the liner sheet 13 can be extended and bent. In this case, since the back sheet 12 and the liner sheet 13 can be made the same size, the back sheet 12 and the liner sheet 13 can be formed of the same shape and the same size metal plate, so that the burden on the manufacturing process is reduced. become. In this case, since the edges of the back sheet 12 and the liner sheet 13 can be folded and overlapped, the above-described joining operation such as welding of the back sheet 12 and the liner sheet 13 can be omitted.

Further, as shown in FIG. 4A, when the edge of the back sheet 12 (or liner sheet 13) is extended and bent, the length of the edge 12a to be bent is set to the panel thickness (the protrusion height). ), The edge portion 12a can be further bent to the liner sheet 13 side while being bent to the cap sheet 11 side.
By doing so, the edge of the folded back sheet 12 (or liner sheet 13) can be folded and overlapped on the liner sheet 13 (or back sheet 12) side, so that the sealing of the end face of the hollow panel 1 is sealed. The degree can be increased, and welding of the back sheet 12 and the liner sheet 13 can be omitted.

In addition, as a method of sealing the end surface of the hollow panel 1, it is not limited to the form mentioned above, It can also implement | achieve with another method.
For example, as shown in FIG. 4B, the outer shape of the back sheet 12 and the liner sheet 13 is formed larger than the cap sheet 11, and the edges of the back sheet 12 and the liner sheet 13 are pressed to the cap sheet 11 side. Thus, the end face of the panel can be sealed. In this way, end-face sealing called a so-called dolphin type can be performed only by performing press working, so that the manufacturing process becomes easy and workability can be improved.
In this case as well, the edges of the pressed back sheet 12 and liner sheet 13 can of course be welded and fused.

In addition to the above, for example, a band-shaped sealing material corresponding to the open shape of the panel end face may be prepared and attached by thermal fusion or the like.
The end face sealing of the hollow panel 1 as described above can be performed on all end faces of the entire periphery of the edge of the panel, and can be performed only on a part of the end faces of the panel as necessary. .
It is of course possible to combine the different end face sealing structures described above.

[Folding part]
With respect to the hollow panel 1 as described above, a portion (folded portion) where the hollow plate material can be bent can be formed by cutting a predetermined portion of the hollow plate material.
Specifically, in the present embodiment, as shown in FIG. 5, the hollow panel 1 can be bent by forming the folded portion 2 by performing predetermined processing.
The folding portion 2 can be formed by cutting (half-cutting) a predetermined portion of the hollow panel 1 formed in a predetermined shape, so that the hollow panel 1 can be bent along the folding portion 2. can do.

The cut (half cut) may be made when forming the folded portion 2 on either the back sheet 12 side or the liner sheet 13 side of the hollow panel 1.
In the example shown in FIGS. 5 to 6, the folded portion 2 is formed by making a cut 3 on the back sheet 12 side of the hollow panel 1. As a result, the hollow panel 1 can be bent from the back sheet 12 side with the cut 3 to the liner sheet 13 side. Therefore, the hollow panel 1 is bent toward the side opposite to the surface where the cuts 3 are formed. Therefore, it is only necessary to form the notch 3 in the sheet (back sheet 12 or liner sheet 13) on the opposite side to the direction in which the hollow panel 1 is to be folded to form two folded portions.

Here, FIG. 5 is an enlarged view of the hollow panel 1 shown in FIG. 1 as viewed from the back sheet 12 side, the AA cross-sectional view of FIG. 5 is shown in FIG. The state bent at 2 is shown in FIG. Similarly, FIG. 7A shows a BB cross-sectional view of FIG. 5, and FIG. 7B shows a state where the portion is bent by the folding portion 2.
As shown in these drawings, in a portion where there is no protrusion 11a, a cut 3 is made so as to cut the fused portion between the cap sheet 11 and the back sheet 12 (see FIG. 6A), and only the liner sheet 13 is formed. The bent portion 2 is formed by bending (see FIG. 6B).
On the other hand, in the part with the protrusion 11a, a notch 3 is made so as to cut the back sheet 12 and the side wall of the protrusion 11a (see FIG. 7A), and the top surface of the protrusion 11a is formed on the liner sheet 13. The fused portion is bent to form the folded portion 2 (see FIG. 7B).

  As a result, the folded portion 2 is formed by alternately arranging portions composed only of the liner sheet 13 and portions having a double structure in which the top surface of the protrusion 11 a is fused to the liner sheet 13. become. Therefore, the folded portion 2 formed by making the cut 3 in the hollow panel 1 is partially reinforced by a portion having a double structure in which the top surface of the protrusion 11a is fused to the liner sheet 13 and folded. The strength is increased to such an extent that the ease of bending of the portion 2 is not impaired. That is, in order to reinforce the folding part 2, for example, the folding part 2 may be difficult to bend only by laminating a sheet material on a site where the folding part 2 is to be formed to form a double structure. By constructing like the folding part 2 of the present embodiment as described above, the folding part 2 has a partially double structure, so that the folding part 2 is appropriately reinforced without impairing its ease of bending. become.

In order to further increase the strength of the folded portion 2 without impairing the ease of bending, for example, a flexible film material such as a polyethylene resin film can be laminated on the hollow panel 1.
At this time, if the notch 3 is formed on the back sheet 12 side to form the folded portion 2, it is adhered to the surface on the liner sheet 13 side, that is, the surface opposite to the side on which the notch 3 is inserted, if necessary. The film material or the like can be laminated through an agent.

Although not particularly shown, when the cut portion 3 is formed from the liner sheet 13 side of the hollow panel 1 to form the folded portion 2, the cut 3 is inserted so as to cut the liner sheet 13 at a portion where the protrusion 11a is not provided. The fused portion between the cap sheet 11 and the back sheet 12 is bent to form the folded portion 2. On the other hand, at the portion where the protrusion 11a is present, a notch 3 is made so as to cut the portion where the top surface of the protrusion 11a is fused to the liner sheet 13 and the side wall portion of the protrusion 11a, and the back sheet 12 is bent and folded. 2 will be formed.
In any case, the formed folding part 2 is formed by alternately arranging portions consisting only of the back sheet 12 and portions having a double structure by fusing the cap sheet 11 to the back sheet 12. As a result, the folded portion 2 partially has a double structure, and the folded portion 2 is appropriately reinforced without impairing the ease of bending.

Moreover, it can be set as the structure which can bend the hollow panel 1 besides the folding part 2 by the above cut processes.
For example, the folding part 2 can be formed in the hollow panel 1 by performing V-shaped processing as shown in FIG.
FIG. 8 is a cross-sectional view of the hollow panel 1 (hollow panel 1) corresponding to FIG. 6 described above, in which a V-shaped processed portion 4 is formed in place of the notch 3 shown in FIG.

The V-shaped processed portion 4 shown in the figure is formed by melting the hollow panel 1 in a V-shaped cross section by applying a heating rod or the like. As shown in FIG. 8B, the hollow panel 1 is bent toward the side where the V-shaped processed portion 4 is provided. Accordingly, in this case, since the hollow panel 1 is bent toward the surface side where the V-shaped processed portion 4 is formed, a sheet (back sheet 12 or liner sheet) in a direction in which the hollow panel 1 is desired to be bent. 13), the V-shaped processed portion 4 may be inserted to form two folded portions.
In addition, the V-shaped processed part 4 formed by such melt processing is in a state where a part of the hollow panel 1 is linearly crushed, and the range surrounded by the V-shaped processed part 4 is as follows. The panel end face is sealed, and air is sealed in the panel. For this reason, even if an end face sealing structure (see FIGS. 3 to 4) is not provided at the edge of the hollow panel 1, air is enclosed in the bubbles in the range, thereby improving the heat insulating property, sound absorbing property, etc. of the hollow panel 1. It can be improved and airtightness of the panel internal space is secured.

Moreover, even if it does not provide the above bending processes (folding part 2), as shown in FIG. 9, the panel itself can be formed in a curved surface shape.
In the hollow panel 1 according to the present embodiment, a cap sheet 11 serving as a core material is formed of a synthetic resin, and the core material itself is excellent in flexibility and flexibility, and is curved when bent in an arbitrary direction. Can be.
Further, the back sheet 12 and the liner sheet 13 laminated on both surfaces of the cap sheet 11 are also made of a thin metal plate, and the metal plate itself can be curved.
Therefore, by bending the hollow panel 1 in a predetermined direction, the cap sheet 11, the back sheet 12, and the liner sheet 13 can be integrally deformed into a curved shape, for example, as a building material or a core material such as a circular wall surface. The hollow panel 1 having the form can be applied and used.

[Welding joint]
Moreover, since the sheet | seat (back sheet | seat 12 and liner sheet | seat 13) used as a panel exterior material is comprised with the metal plate, the hollow panel 1 which concerns on this embodiment is metal plates which use the some hollow panel 1 as an exterior material. It becomes possible to join by welding.
For example, as shown in FIG. 10 (a), two hollow panels 1 are arranged in a T-shape that is orthogonal to each other, and the end surface of one panel and one surface of the other panel are welded and melted at a welded portion 5. It can be joined by wearing.
Similarly, as shown in FIG. 10B, the two hollow panels 1 are arranged in an L shape, and the end surface of one panel and the one surface of the other panel are welded and fused at the welded portion 5. Can be joined.
Thus, in the hollow panel 1 of this embodiment which comprised the panel exterior material with the metal plate, panels can be welded by arbitrary arrangement | positioning / shapes, and it is excellent in versatility and expansibility as a building material or a core material. Panel material.

[Fastening with bolts, etc.]
Furthermore, in the hollow panel 1 according to the present embodiment in which sheets (back sheet 12 and liner sheet 13) serving as panel exterior materials are formed of metal plates, bolts or the like penetrate through the back sheet 12 and liner sheet 13 serving as exterior materials. Even when the bolts and the like are repeatedly attached and detached, the back sheet 12 and the liner sheet 13 which are exterior materials are not deteriorated or damaged.
For this reason, it becomes possible to use fasteners, such as a volt | bolt, in the hollow panel 1, for example, arbitrary metal fittings can be fastened and attached with a volt | bolt etc., and several hollow panels 1 can be fastened with a volt | bolt. Become.

For example, as shown in FIG. 11 (a), panel support fittings 7 a and 7 b are disposed on both bottom surfaces of the standing hollow panel 1, and the hollow panel 1 and the fittings 7 a and 7 b are integrated by bolts 6. Can be fastened. Thereby, the hollow panel 1 is supported in a standing state by the metal fittings 7a and 7b, and can be erected and arranged at an arbitrary installation location.
Similarly, as shown in FIG. 11 (b), two hollow panels 1 are arranged so as to overlap each other, and a panel support metal fitting 8 is arranged on one side of the bottom of the panel. It is also possible to integrally fasten the metal fitting 8 with the bolt 6.
In this way, in the hollow panel 1 of the present embodiment in which the panel exterior material is configured by a metal plate, the panels can be fastened and joined using a fastener such as a bolt, or an auxiliary metal fitting or the like can be attached. Even if screwing and detaching are repeated, etc., the metal panel exterior material will not be deteriorated or damaged, and the versatility and expandability as a panel used for building materials and core materials can be further improved. .

  As described above, according to the hollow panel according to the present embodiment, first, the core sheet constituting the hollow panel 1 includes the cap sheet 11 on which a large number of protrusions 11a are formed. By laminating the back sheet 12 on the protrusion opening side, each protrusion 11a is sealed and sealed to form a so-called bubble board / bubble sheet formed as bubbles. In the bubble sheet, a large number of sealed bubbles (protrusions 11a) have shock resistance and shock absorbing properties as buffer members, and also have heat insulation and sound absorption effects due to the bubbles sealed with gas, and the panel as a whole has heat insulation and sound absorption properties. A hollow panel having excellent properties can be realized.

In addition, the plurality of protrusions 11a provided in the cap sheet 11 are separated from each other by a predetermined interval, and the cap sheet itself has flexibility and flexibility. Such a cap sheet By using 11 as a core material, the hollow panel itself has a certain flexibility and flexibility, and the hollow panel 1 can be bent or curved.
Furthermore, the cap sheet 11 made of synthetic resin is lightweight and flexible, excellent in water resistance, durability, and heat retention, can be washed with water, and can be used repeatedly.

And in this embodiment, while forming cap sheet 11 with a synthetic resin as mentioned above, exterior materials which consist of back sheet 12 and liner sheet 13 laminated on both sides of this cap sheet 11 are iron, aluminum, It is configured by a metal plate made of a metal such as stainless steel.
The cap sheet 11 made of a synthetic resin is excellent in flexibility and flexibility and is extremely light compared to a metal honeycomb structure and the like, thereby suppressing or preventing an increase in the weight of the entire hollow panel. can do.

  Further, by using a metal plate as the exterior material composed of the back sheet 12 and the liner sheet 13 laminated on both surfaces of the cap sheet 11, the strength and rigidity of the entire hollow panel can be increased by the rigidity and strength of the metal plate itself. Thus, the hollow panel 1 can be realized that is superior in rigidity and strength as compared with a hollow panel made of resin or paper. Further, the metal plate itself has flexibility and plasticity that can be curved and bent, and can be easily bent and curved with the synthetic resin cap sheet 11.

Therefore, according to the hollow panel 1 according to the present embodiment, as a hollow panel made of a hollow plate material obtained by laminating a flat exterior material on both front and back surfaces of a core material subjected to a three-dimensional process for forming a hollow structure, A hollow panel that is excellent in strength and rigidity, can be bent and curved, can suppress an increase in panel weight, and has excellent heat insulation and sound absorbing properties.
This makes it possible to provide a hollow panel suitable for building materials, core materials, and the like.

The hollow panel of the present invention has been described with reference to the preferred embodiment. However, the hollow panel of the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention. Needless to say.
For example, in the above-described embodiment, only one layer of the cap sheet 11 serving as the core material is provided. However, the cap sheet may be provided with a plurality of layers. For example, two layers of cap sheets can be laminated to form a core material.

In that case, it is preferable to arrange | position each cap sheet | seat so that protrusion top surface side may oppose. In this way, the protrusions of the two-layer cap sheet can be sealed and sealed by the back sheet and the liner sheet, respectively, and the protrusions of the two-layer cap sheet can function as bubbles.
Moreover, it is also possible to provide a plurality of layers for the exterior material composed of the back sheet and the liner sheet. Further, a resin layer or the like can be further laminated on the surface of the exterior material to coat the exterior material made of a metal plate.

Further, when a core material is configured by laminating a plurality of cap sheets, the protrusions formed on each cap sheet may be different in size (opening area of bubbles) and height (depth). good.
For example, two cap sheets having different protrusion sizes can be stacked. In that case, the bubble opening side of the small protrusion can be mounted on the top surface of the large protrusion and stacked.

  The present invention is, for example, a building material constituting a wall, floor, ceiling, etc. of a building, a door of a vehicle such as an automobile or a train, a core of a body, a core of an openable door provided in a backyard of a supermarket, etc. It can utilize suitably for the hollow panel used.

DESCRIPTION OF SYMBOLS 1 Hollow panel 2 Folding part 3 Cut 4 V-shaped process 10 Hollow panel 12 Back sheet 11 Cap sheet 11a Protrusion 13 Liner sheet

Claims (8)

A hollow panel made of a hollow plate material obtained by laminating a flat exterior material on both front and back surfaces of a core material subjected to three-dimensional processing to form a hollow structure,
The core material comprises a cap sheet formed with a plurality of protrusions that bulge in a hollow shape,
The exterior material laminated on both the front and back surfaces of the core material is composed of a back sheet laminated on the opening side of the cap sheet projection, and a liner sheet laminated on the top surface side of the cap sheet projection,
The cap sheet is made of a synthetic resin,
The hollow panel, wherein the back sheet and / or liner sheet is made of metal.   The hollow panel according to claim 1, wherein the back sheet and / or liner sheet is made of iron, aluminum, or stainless steel.   The hollow panel according to claim 1 or 2, wherein the cap sheet is fused and fixed to the back sheet and / or liner sheet.   The hollow panel according to any one of claims 1 to 3, wherein the cap sheet is fixed to the back sheet and / or liner sheet via an adhesive.   The hollow panel according to any one of claims 1 to 4, wherein at least a part of the open end face of the hollow plate member is sealed.   The hollow panel according to claim 5, wherein the edge of the back sheet and / or the liner sheet is bent toward the cap sheet to seal the open edge of the hollow plate.   7. The hollow panel according to claim 5, wherein the edge of the back sheet and the liner sheet is pressed on the cap sheet side to seal the open edge of the hollow plate.   The hollow panel as described in any one of Claims 1 thru | or 7 which formed the folding part which the said hollow plate material can bend | fold by making a notch | incision in the predetermined site | part of the said hollow plate material.

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