KR200373629Y1 - Fiber Reinforced Composite Panel of Straight and Curved Tubular Profile Having Snap-Fit Connection and Connectors thereof - Google Patents

Abstract

The present invention has a polygonal hollow section and is made of fiber-reinforced composite material and is connected in parallel with each other by mechanical coupling of snap-fit type, so that the building structure, tank structure, platform, sidewalk deck, bridge deck, arch, round pipe And fiber reinforced composite panels that form civil engineering and building structures in open or closed sections, such as circular tanks, and connectors that connect the panels at a predetermined angle to each other or in a T-shape or circular connection. It is about.

In the present invention, the upper plate (2), the lower plate (3) and the abdominal plate (4) is composed of a plurality of flat or curved polygonal hollow cross section, one side of the first downward protrusion coupling portion (15a) and the second downward A protrusion coupling part 15b is formed, and the first downward protrusion coupling part 15a is formed downward from the end of the upper extension part 5 in which the upper plate 2 extends further to the side. The second downward protrusion coupling portion 15b is formed to protrude downward from the outer surface of the outer abdominal plate 4; On the other side of the panel 1, the first upward protrusion coupling portion 15a 'and the second upward protrusion are mechanically coupled to the first and second downward protrusion coupling portions 15a and 15b so as to be detachable from each other. Coupling portion 15b 'is formed, and the first upward protrusion coupling portion 15a' is provided to protrude upward from the outer surface of the outer abdominal plate 4, and the second upward protrusion coupling portion 15b 'is the lower plate. (3) is provided upward from the end of the lower extension (5 ') is formed to extend further; The protrusion coupling portions 15a, 15a ', 15b, and 15b' are formed with protrusions 15c and 15c 'corresponding to each other so as to form a mechanical coupling, so that the adjacent bottom plate tube 1' and Fiber-reinforced composite panel, characterized in that coupled to the mechanical detachment in a vertical direction to form a polygonal or circular cross-sectional structure, and a connector for connecting the panels perpendicular to each other or T-shaped or at an angle Is provided.

Description

Fiber Reinforced Composite Panel of Straight and Curved Tubular Profile Having Snap-Fit Connection and Connectors

The present invention relates to a fiber-reinforced composite flat and curved panels of hollow sections, and connectors for the same. Specifically, the present invention has a flat or curved polygonal hollow cross section, is made of fiber-reinforced composite, and is a snap-fit type. The fiber-reinforced composite flat and curved panels connected in parallel to each other by a mechanical combination of the same to form a structure such as a building structure, a tank structure, a platform, a sidewalk deck, and a bridge deck, and the panels are connected to each other at an angle, or It relates to a connector to be connected in a T-shape.

There is a growing interest in technology for manufacturing structures such as walls of building structures and floors of sidewalks using fiber reinforced composite panels of hollow sections. As a system using such hollow cross-section fiber reinforced composite panel (hereinafter, abbreviated as "panel"), a system of inserting a connector called a toggle between them while the sides of neighboring panels are in contact with each other is known. 1A is a perspective view showing a configuration in which two panels are connected side by side by a conventional panel system, and FIG. 1B is a schematic partial perspective view of a structure in which two panels are connected at right angles.

1A and 1B, in the conventional panel system, the panel 100 has a cross section in which a plurality of polygonal hollows 101 are formed to extend laterally, and on both sides of the panel 100. Toggle coupling portions 102 recessed in recesses are formed. The panel 100 is connected to each other by a toggle 200, the toggle 200 has a shape in which both ends protrude from the center portion is recessed. The toggle coupling portion 102 has a shape corresponding to the toggle 200 can be fitted.

The panel 100 of such a configuration, as shown in Figure 1a, the panel 100 is arranged so that both sides face each other with the toggle 200 in the transverse direction of the panel 100, the toggle coupling portion 102 By being inserted into) is coupled to each other, the protruding portion of the toggle 200 is fitted to the concave portion of the toggle coupling portion (102).

In order to connect the panels 100 to each other at right angles, a two-way or three-way connector 300 should be used, and the three-way connector 300 is illustrated in FIG. 1B. The three-way connector 300 is located at the corners of both panels 100 are arranged at a right angle, the toggle coupling portion 102 is formed on three sides of the connector 300, the three-way connector ( The toggle 200 is inserted into and coupled between the panels 100 facing each side of the 300. In order to vertically connect the panel 100 in a T-shape, a new panel 100 is disposed next to the toggle coupling portion 102 in which the toggle 100 is not inserted in FIG. 1B, and the toggle 100 is interposed therebetween. Insert).

However, in the conventional panel system as described above, the following points are pointed out as disadvantages or limitations.

First, there is a disadvantage that the number of parts used is large. As described above, in order to connect the two panels must use a separate member called a toggle, the handling is cumbersome and assembly is cumbersome. In particular, there is a limit to the range in which the panel can be utilized due to the direction in which the toggle is inserted in the transverse direction of the panel. For example, if the structure of the type shown in Figure 1b has a considerable length in the transverse direction of the panel, that is, in the vertical direction in the drawing, the length of the toggle must be long accordingly, so inserting such a long toggle from one side of the panel Is a very difficult task. If the length of the toggle becomes longer, it is very likely that the toggle is broken by buckling or the like in the process of inserting the toggle. In addition, in order to insert the toggle in the lateral direction, sufficient space for inserting the toggle must be secured on the transverse side of the panel. However, in the field where this space cannot be secured, the conventional panel system cannot be used. There is.

Above all, in the conventional panel system as described above, the toggle can only serve as a shear connector, so the connection can be opened when subjected to a bending load, and the strength of the toggle is low and the connection strength of the panel is vulnerable to bending, shear and tension. There is a problem of being low. Figure 2 shows a photograph of a toggle and toggle coupling portion broken by a flexural load test on a conventional panel connected by a toggle. In the case of a toggle having a short length as described above and having a protruding shape at both ends, since the shear stress is supported only by the protruding portions at both ends, any of the protruding portions are damaged or protruding portions as shown in FIG. 2B. If the holding toggle is broken, it will no longer be able to connect the panels.

The present invention was developed to overcome the disadvantages and limitations of the conventional panel system using the above toggle, can reduce the number of parts, can overcome the limitations according to the assembly direction of the panel, the connection strength of the panel In addition, the fiber reinforced composite panel with a new structure, which improves workability and structural stability by allowing the panel to be connected in a simple and robust mechanical detachable manner in connecting the panels to each other, An object of the present invention is to provide a connector of a new structure that effectively connects the panel to allow construction of a structure.

1A is an assembled perspective view showing a configuration in which two flat panels are connected side by side to each other by a conventional panel system.

1B is a schematic partial perspective view of a structure in which two flat panels are connected at right angles in a conventional panel system.

FIG. 2 is a photograph of a toggle and toggle coupling portion broken by a flexural load test on a conventional flat panel connected by a toggle. FIG.

3A and 3B are schematic perspective views of the fiber-reinforced composite flat panel according to the present invention, respectively, and an assembly cross-sectional view showing that the flat panel is assembled.

Figure 4 is an enlarged view of the coupling form of the protrusion coupling portion provided in the flat panel of the present invention.

Figure 5 is an enlarged view showing another embodiment of the coupling form of the protrusion coupling portion provided in the flat panel of the present invention.

6 is a schematic perspective view of a finishing member installed and finished at the outermost side of the flat panel according to the present invention.

7A is a perspective view of a right angle connection connector used to connect two flat panels at a right angle.

FIG. 7B is a perspective view illustrating a state in which two flat panels are connected to each other at right angles by the right-angle connection connector shown in FIG. 7A.

8A is a perspective view of a non-orthogonal connection connector used to connect two flat panels at an angle.

8B is a perspective view illustrating a state in which two flat panels are inclined at a predetermined angle to each other by the non-orthogonal connector shown in FIG. 8A.

FIG. 9A is a perspective view of a square cross-sectional structure fabricated using the right angle connector shown in FIG. 7A. FIG.

FIG. 9B is a perspective view of a spherical cross-sectional structure having a partition fabricated using the right angle connector shown in FIG. 7A and the T-type connector shown in FIG. 10A.

FIG. 10A is a perspective view of a T-type connector used to connect three flat panels to form a T-shape. FIG.

FIG. 10B is a perspective view illustrating a state in which three flat panels are vertically connected to each other by a T-shaped connector shown in FIG. 10A to form a T-shape.

11a is a schematic perspective view of a cylindrical structure manufactured by connecting and assembling the curved panels according to the present invention.

11B is a schematic perspective view of an arch structure manufactured by connecting and assembling the curved panels according to the present invention.

<Brief description of the main parts of the drawing>

1 panel 20 right-angle connector

30 T type connector

In the present invention, in order to achieve the above object, a fiber-reinforced composite panel composed of a top plate, a bottom plate and an abdominal plate having a plurality of flat or curved polygonal hollow cross-section, the first side of the bottom plate tube A downward protrusion coupling portion and a second downward protrusion coupling portion are formed, wherein the first downward protrusion coupling portion is formed downward from an end portion of the upper extension portion in which the upper plate extends further to the side surface, and the second downward protrusion coupling portion is outer side. It is formed in the form protruding downward on the outer surface of the abdominal plate; The other side surface of the bottom plate tube is formed with a first upward protrusion coupling portion and a second upward protrusion coupling portion which is mechanically coupled in a snap-fit form so as to be detachable from the first and second downward protrusion coupling portions, respectively. A first upward protrusion coupling portion protrudes upward from an outer side surface of the outer abdominal plate, and a second upward protrusion coupling portion is upwardly provided from an end portion of the lower extension portion in which the lower plate is further extended; The protrusion coupling portions are formed with protrusions corresponding to each other to form a mechanical coupling, and are coupled to each other by a snap-fit type mechanical detachment method in a direction perpendicular to a neighboring bottom plate tube to form a bottom plate. Provided is a fiber-reinforced composite panel.

In the present invention, as a specific embodiment of the panel, the inner end portion of the upper extension portion is formed in the form of a projecting support portion for supporting the front end portion of the first upward protrusion coupling portion from the rear side, the end portion of the lower extension portion A recess is formed in the inner side, and when the second downward protrusion coupling portion and the second upward protrusion coupling portion are coupled, the protrusion supporting portion supporting the front end portion of the second downward protrusion coupling portion from the rear is formed to protrude. Provided is a fiber-reinforced composite panel, which is configured to increase the resistance in the horizontal direction in a state where the protrusion coupling portions are coupled to each other to further strengthen the coupling state of the protrusion coupling portions.

In addition, the present invention provides a right-angle connection connector for connecting the fiber-reinforced composite panel at right angles to each other, the right-angle connection connector is made of a fiber-reinforced composite material, consisting of a lower portion and a central portion formed perpendicular to the T-shaped Has a cross section in the shape and extends in the transverse direction to the transverse length of the panel; In the T-shaped cross section of the right-angled connector, at one end of the lower portion, a second upward protrusion coupling portion coupled to the second downward protrusion coupling portion of the second panel is formed to protrude vertically in the inward direction of the lower portion, and at the other end of the lower connection portion, A second downward protrusion coupling portion engaged with the second upward protrusion coupling portion of the first panel is formed to protrude in the other end direction of the lower portion from the inside of the lower portion; A first downward protrusion coupling portion is formed at an end portion of the center portion perpendicular to the lower portion in the T-shaped cross section of the right angle connecting connector, and the first downward protrusion coupling portion may be coupled to the first upward protrusion coupling portion of the first panel. It is formed so as to protrude vertically from the central end portion in the downward direction of the drawing, while the first upward protrusion engaging portion is formed to protrude in the direction of the end portion of the central portion on the opposite side of the first downward protrusion coupling portion at the end of the central portion, The first downward protrusion coupling portion and the second downward protrusion coupling portion of the perpendicularly connecting connector at the corners at which the first panel and the second panel face at right angles to each other, respectively, the first upward protrusion coupling portion and the second upward protrusion of the first panel. Coupled to the protrusion coupling portion, the first upward protrusion coupling portion and the second upward protrusion coupling portion of the right-angle connecting connector are respectively connected to the first downward protrusion coupling portion and the second downward protrusion coupling portion of the second panel; Provided is a right-angled connector of the fiber reinforced composite panel characterized in that the first panel and the second panel is connected to each other at a right angle to each other.

In addition, the present invention is made of the fiber-reinforced composite panel described above as a T-type connecting connector to form a T-shape by connecting two panels arranged horizontally and one panel arranged vertically to each other at a right angle, the T-type connection The connector is made of a fiber-reinforced composite material, has a T-shaped cross section consisting of a lower portion and a central portion integrally formed perpendicularly thereto, and extends laterally in accordance with the transverse length of the panel; In the T-shaped cross section of the T-shaped connector, at one end of the lower portion, a second upward protrusion coupling portion coupled to the second downward protrusion coupling portion of the second panel is formed to protrude vertically in the inward direction of the lower portion, and at the other end of the lower portion. A second downward protrusion coupling portion engaged with the second upward protrusion coupling portion of the first panel is formed to protrude in the other end direction of the lower portion from the inside of the lower portion; A first downward protrusion coupling portion is formed at an end portion of the center portion perpendicular to the lower portion in the T-shaped cross section of the T-type connecting connector, wherein the first downward protrusion coupling portion is coupled to the first upward protrusion coupling portion of the first panel. Protrude in a vertical direction from the central end to the lower portion, while the first upwardly protruding portion protrudes toward the end of the central portion at an opposite side of the first downward protruding portion; A first upward protrusion coupling portion protruding from the lower outer portion of the lower portion is coupled to the first downward protrusion coupling portion of the third panel; The other end of the lower portion is further provided with a horizontal portion extending in the third panel direction; At the end of the horizontal portion, a second upward protrusion coupling portion coupled to the second downward protrusion coupling portion of the third panel is provided to protrude upward, and the first and third panels and the second panel face each other at right angles. The first downward protrusion coupling portion and the second downward protrusion coupling portion of the T-type connecting connector are respectively coupled to the first upward protrusion coupling portion and the second upward protrusion coupling portion of the first panel at the edges of the T-type connecting connector. The first upward protrusion coupling portion and the second upward protrusion coupling portion of the first downward protrusion coupling portion and the second downward protrusion coupling portion of the second panel, respectively, the first downward protrusion coupling portion and the first side of the third panel The two downward protrusion coupling portions are coupled to the first upward protrusion coupling portion and the second upward protrusion coupling portion respectively provided on the outer side of the lower portion of the T-type connecting connector, so that the first panel and the second panel 1b are two first panels. This T-shape is characterized in that to be connected to each other T-type connector of the fiber reinforced composite panel is provided.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and embodiment of the present invention. 3A and 3B are fiber reinforced composite panels according to the present invention, respectively, showing a schematic perspective view of a flat panel 1 made of a flat surface and showing that the panel 1 is coupled with a neighboring panel 1 '. Assembly section. In the present specification, the term “panel” is used to mean both a panel forming a plane and a panel forming a curved surface, but a panel forming a curved surface is separately designated as a “curved panel”. However, as noted above, when necessary, a flat panel may be designated as a "flat panel".

As shown in FIGS. 3A and 3B, the panel 1 has a plurality of polygonal hollows 101 extending in the transverse direction. In the present invention, the shape and number of the hollow is not limited and may be variously modified. The fiber-reinforced composite panel 1 is composed of a resin selected from polyester, vinyl ester, panol or epoxy, and reinforcing fibers, and is produced by a pull molding method. The reinforcing fibers include glass fibers, carbon fibers, aramid fibers, and the like, but are not limited thereto. Various fibers may be used as the reinforcing fibers, and the above-described fibers may be mixed and used.

In the present invention, the panel 1 is assembled such that the neighboring panel 1 'and the side thereof are integrally connected to each other, and are coupled to approach the vertical panel with respect to the neighboring panel 1', and the neighboring panel 1 '. (1 ') combined with a simple yet robust mechanical removal method. To this end, a first downward protrusion coupling portion 15a and a second downward protrusion coupling portion 15b are formed on one side of the panel 1, and the first and second downward directions are formed on the other side of the panel 1. The first upward protrusion coupling portion 15a 'and the second upward protrusion coupling portion 15b' which are mechanically coupled to each of the protrusion coupling portions 15a and 15b to be detachably formed are formed.

Specifically, in the embodiment shown in the drawings, one side of the panel (1, 1 ') there is an upper extension portion 5, the upper plate 2 is extended and the lower plate 3 is extended on the other side An extension part 5 'exists, and the first downward protrusion coupling part 15a protrudes downward from an end of the upper extension part 5. In addition, one side of the panel (1, 1 ') is formed in a form protruding the second downward protrusion coupling portion 15b in the downward direction on the outer surface of the outer abdominal plate (4). On the other hand, on the other side surface of the panel (1, 1 '), the first upward protrusion coupling portion (15a') which is engaged with the first downward protrusion coupling portion (15a) is upward from the outer surface of the outer abdominal plate (4) It protrudes and is provided in the lower portion is provided with a second upward protrusion coupling portion 15b 'upwardly coupled to the second downward protrusion coupling portion 15b at the end of the lower extension portion 5'.

FIG. 4 is an enlarged view of an embodiment in which the first downward protrusion coupling portion 15a and the first upward protrusion coupling portion 15a 'are coupled to each other, and the first downward protrusion coupling portion 15a and the first downward protrusion coupling portion 15a' are coupled to each other. The protrusions 15c and 15c 'of the corresponding shape are formed in the upward protrusion coupling portion 15a', respectively, so that the protrusions 15c and 15c 'are bitten to each other to form a strong mechanical coupling. On the other hand, in order to increase the resistance in the horizontal direction in the state where the protrusion coupling portion is coupled with each other, the end of the first upward protrusion coupling portion (15a ') to support the rear end of the upper extension portion (5a') It is preferable that the protruding support part 51 is formed to protrude. The structure described above is equally applicable to the coupling structure of the second downward protrusion coupling portion 15b and the second upward protrusion coupling portion 15b '. For reference, FIG. 4 shows an example of the arrangement of fibers inside the protrusion coupling parts 15a and 15a 'as a dotted line. In the present invention, the inside of the protrusion coupling parts 15a, 15a', 15b and 15b 'is shown. Since the fibers may be arranged in the longitudinal direction as shown by the dotted lines in the above, even if shear force is applied to the protrusions between the panels 1 and 1 ', sufficient rigidity can be exerted through the above-described fiber arrangement.

When the panel 1 of the present invention is connected to the neighboring panel 1 ', the panel 1 is coupled to the neighboring panel 1' by being placed and pressed from above, as shown in FIG. The first upward protrusion coupling portion 15a 'of (1') is fitted with the first downward protrusion coupling portion 15a of the panel 1, which is positioned downward from above, and is coupled to the first upward protrusion coupling portion 15a '. The upward protrusion coupling portion 15b 'is coupled to the second downward protrusion coupling portion 15b of the panel 1 so that both panels 1 and 1' are firmly coupled by mechanical engagement.

At this time, since the first upward protrusion coupling part 15a 'and the second downward protrusion coupling part 15b have a predetermined elasticity, when the panel 1 is pressed with a force of a predetermined level or more, the protrusions 15c, As the slip occurs between 15c '), the first upward protrusion coupling portion 15a' and the second downward protrusion coupling portion 15b are finely retracted to facilitate mechanical coupling of the protrusion period. After the protrusions 15c and 15c 'are slipped from each other, the first upward protrusion coupling part 15a' and the second downward protrusion coupling part 15b are returned to each other by elasticity so that the protrusions 15c and 15c 'are retracted. They are firmly inherited from one another. In particular, the present invention is provided with a protrusion supporting portion 51 for supporting the end portions of the first upward protrusion coupling portion 15a 'and the second downward protrusion coupling portion 15b from the rear to exert a horizontal resistance force, After the coupling portions are coupled to each other, the first upward protrusion coupling portion 15a 'and the second downward protrusion coupling portion 15b do not open so that the protrusion coupling portions may be coupled to each other very firmly.

On the other hand, when the panel 1 is drawn out with a certain force or the like, the slippage occurs between the protrusions 15c and 15c 'as described above, and the first upward protrusion coupling part 15a' and the second downward protrusion coupling are similar to the above. The portion 15b is finely backed out so that the engagement state between the protrusion coupling portions can be easily released. Therefore, the structure can be freely assembled and disassembled, and the panel can be recycled.

FIG. 5 illustrates another embodiment of the protrusion coupling unit. As illustrated in FIG. 5A, two or more protrusions formed on the protrusion coupling unit may be provided. If it is not intended to dismantle the panel (1, 1 ') at all, in applying the present invention, it may be used by further increasing the bonding strength by bonding in the state in which the adhesive is applied to the protrusion coupling portion.

On the other hand, the outermost side of the panel 1 is provided with a finishing member 10, the shape of the finishing member 10 is shown in perspective in FIG.

Next, referring to FIGS. 7A and 7B, and FIGS. 8A and 8B, a structure for connecting two panels 1 at a predetermined angle and a connection connector used therein will be described. 7A and 7B relate to an embodiment in which the two panels 1 are connected at right angles, and FIGS. 8A and 8B relate to embodiments in which the two panels 1 are connected at different angles.

First, an embodiment connected at right angles will be described below. Here, the right angle does not mean a strict 90 degrees, but means a range that can be called a right angle at about 90 degrees back and forth.

FIG. 7A is a perspective view of a right angle connection connector 20 used to connect two panels 1a and 1b at right angles, and FIG. 7B shows two panels 1a and 1b by means of the right angle connection connector 20. 1 is a cross-sectional view showing a state in which the first panel 1a and the second panel 1b are connected to each other at right angles.

Right angle connecting connector 20 is made of fiber reinforced composite material in the same way as the panels (1a, 1b), and has a T-shaped cross section consisting of the lower portion 21 and the central portion 22 integrally formed perpendicular thereto, It extends laterally according to the transverse length of the panel 1a, 1b. At one end of the lower portion 21 in the T-shaped cross section of the right-angle connecting connector 20, a second upward protrusion coupling portion 15tb 'coupled to the second downward protrusion coupling portion 15b of the second panel 1b is provided. It is formed to protrude vertically in the inward direction of the lower side 21, the second downward protrusion coupling is coupled to the other end of the lower portion 21 and the second upward protrusion coupling portion (15b ') of the first panel (1a). The part 15tb protrudes in the other end direction of the lower part 21 from the inner side of the lower part 21, and is formed.

Meanwhile, a first downward protrusion coupling part 15ta is formed at an end portion of the central portion 22 perpendicular to the lower portion 21 in the T-shaped cross section of the right angle connecting connector 20. The portion 15ta protrudes from the end of the central portion 22 vertically in the downward direction of the drawing so as to be coupled to the first upward protrusion coupling portion 15a 'of the first panel 1a. On the other hand, at the end of the central portion 22, the first upward protrusion coupling portion 15ta 'is formed on the opposite side of the first downward protrusion coupling portion 15ta to protrude toward the end portion of the central portion 22.

Accordingly, when the first panel 1a and the second panel 1b are connected at right angles to each other, as shown in FIG. 7B, the first downward protrusion coupling part 15ta and the second protrusion of the right angle connecting connector 20 are illustrated. The downward protrusion coupling portion 15tb is coupled to the first upward protrusion coupling portion 15a 'and the second upward protrusion coupling portion 15b' of the first panel 1a, respectively. At the same time, the first upward protrusion coupling portion 15ta 'and the second upward protrusion coupling portion 15tb' of the right-angle connecting connector 20 are respectively the first downward protrusion coupling portion 15a of the second panel 1b. And a second downward protrusion coupling portion 15b, respectively. Since the first panel 1a and the second panel 1b are connected to the right-angle connecting connector 20 in the above manner, the first panel 1a and the second panel 1b are connected at right angles to each other. Therefore, the use of such a right-angle connection connector 20 it is possible to easily manufacture a structure of a closed quadrilateral cross section as shown in Figure 9a and 9b. The structure of the quadrilateral cross section shown in FIG. 9A can be utilized, for example, as a box culvert structure.

Next, a structure in which the two panels 1a and 1b are tilted and connected at a predetermined angle will be described with reference to FIGS. 8A and 8B. FIG. 8A is a perspective view of a non-square connection connector 30 used to connect two panels 1a and 1b to each other at another angle, and FIG. 8B shows two panels 1a by the non-angle connection connector 30. That is, sectional view showing a state in which the first panel 1a and the second panel 1b are connected to each other in an inclined form at a predetermined angle.

As shown in FIG. 8A, the non-orthogonal connecting connector 30 is made of fiber reinforced composite material in the same manner as the panels 1a and 1b. The web 31 is provided at the center and the first and second portions are provided on both sides thereof. It is composed of the downward protrusion coupling portion (15ca, 15cb) and the first and second upward protrusion coupling portion (15ca ', 15cb'). First, the first and second upward protrusion coupling parts 15ca 'and 15cb' are the first and second upward protrusion coupling parts 15a 'and 15b' provided in the flat panel 1a and 1b of the present invention described above. 8B, the first and second downward protrusion coupling parts 15a and 15b of the second panel 1b are respectively coupled to each other.

Meanwhile, first and second downward protrusion coupling parts 15ca and 15cb are provided on the other side of the web 31 of the non-angled connector 30, respectively. The two downward protrusion coupling portions 15ca and 15cb are provided so as to face downward with a predetermined angle with respect to the web 31. The first and second downward protrusion coupling portions 15ca and 15cb of the non-angle connecting connector 30 are coupled to the first and second upward protrusion coupling portions 15a 'and 15b' of the first panel 1a, respectively. do. At this time, since the first and second downward protrusion coupling portions 15ca and 15cb of the non-angle connecting connector 30 are opened at a predetermined angle from the web 31, the first and second panels 1a and 1b are provided. When connected to the non-orthogonal connection connector 30, as shown in Figure 8b, the first and second panels (1a, 1b) are connected in an inclined form with each other at a predetermined angle. When the first and second downward protrusion coupling portions 15ca and 15cb of the non-orthogonal connector 30 adjust the angles of the web 31, the first and second panels 1a and 1b are formed at various angles. Can be connected. Therefore, when a plurality of panels are connected using the non-orthogonal connection connector 30, a polygonal structure can be easily made.

On the other hand, the panel according to the present invention may be connected in a form orthogonal to each other, that is, three panels to form a T-shape, in the following, with reference to Figures 10a and 10b T-type connecting connector for the T-shaped connection of such a panel 40 will be described.

FIG. 10A is a perspective view of a T-type connecting connector 40 used to connect three panels 1a, 1b. 1c to form a T-shape, and FIG. The panel 1a, 1b, 1c, that is, the second panel 1b is a cross-sectional view showing a state in which the second panel 1b is connected to the first panel 1a and the third panel 1c at right angles to form a T shape. The first panel 1a and the third panel 1c are on the same plane, and the second panel 1b is connected perpendicularly thereto.

The T-type connecting connector 40 is made of fiber reinforced composite material in the same manner as the panels 1a, 1b, and 1c. As shown in FIG. 10A, the basic shape thereof is a right-angle connecting connector 20 shown in FIG. 7A. Similar to). That is, the T-type connecting connector 40, in addition to the configuration of the right-angle connecting connector 20 shown in Figure 7a, the first downward protrusion coupling portion 15a and the second downward protrusion coupling portion of the third panel 1c. And a first upward protrusion coupling portion 15pa 'and a second upward protrusion coupling portion 15pb' respectively coupled to 15b.

In more detail, only the protrusion coupling part additionally provided in the T-type connecting connector 40 will be described. In the middle of the lower side 21 of the T-type connecting connector 40, the first panel of the third panel 1c may be used. A first upward protrusion coupling portion 15pa 'coupled to the downward protrusion coupling portion 15a is formed to protrude. On the other hand, the other end of the lower portion 21 is further provided with a horizontal portion 23 extends in the direction of the third panel 1c, and at the end of the horizontal portion 23, the third portion of the third panel 1c is provided. A second upward protrusion coupling portion 15pb 'coupled to the second downward protrusion coupling portion 15b protrudes upward. In addition, the protrusion 21 provided in the lower portion 21 and the center portion 22 to be connected to the lower portion 21 and the center portion 22 and the first panel 1a and the second panel 1b has been described above. Since the same as the case of the right-angle connection connector 20, repeated description is omitted.

Using the T-type connecting connector 40 of the above configuration, as shown in Figure 10b three panels (1a, 1b, 1c) can be connected to each other forming a T-shaped, the first panel (1a) and the second panel Since (1b) is connected to the T-type connecting connector 40 is the same as the case of the right-angle connection connector 20 described with reference to Figure 7b it will not be repeated description. Meanwhile, referring to the configuration in which the third panel 1c is connected to the T-type connecting connector 40, the first downward protrusion coupling part 15a and the second downward protrusion coupling part 15b on one side of the third panel 1c are described. ) Is coupled to the first upward protrusion coupling portion 15pa 'and the second upward protrusion coupling portion 15pb' which are provided outside the lower portion 21 of the T-type connecting connector 40, respectively. In the present invention, two first panels 1a and 1c and one second panel 1b may be connected to each other by a T-shape by the T-type connection connector 40 as described above.

In addition, by connecting the three panels to form a T-shape by the T-shaped connection connector 40, and then coupled to face the other T-shaped panels, it is possible to manufacture a structure forming an H-shape, If the use of the right-angle connection connector 20 shown in Figure 7a and 7b in addition to it can be produced a structure as shown in Figure 9b.

On the other hand, with respect to the T-type connecting connector 40 above, it has been described that the two first panel (1a, 1c) and the second panel (1b) are joined in a perpendicular form to meet at right angles, but also referred to as a right angle It does not mean a strict 90 degrees, but means a thing that can be called a right angle at 90 degrees back and forth. In addition, the first panels 1a and 1c are not limited to the flat panel as shown in the drawing, and the curved panels as described later are also included.

In the above, the present invention has been described by exemplifying a flat panel as a panel. Next, the curved panel will be described with reference to FIGS. 11A to 11B.

11A shows a schematic view of a cylindrical tank structure manufactured using the curved panel of the present invention, and FIG. 11B shows a schematic diagram of an arch structure manufactured using the curved panel of the present invention.

The curved panel of the present invention basically has the same configuration as the flat panel shown in FIGS. 3A and 3B, but has a feature that the shape is formed of a curved surface having a predetermined curvature rather than a flat surface. In addition, the configuration of the protrusion coupling parts and the like formed on both sides of the panel is the same as the flat panel described above, and the repeated description is omitted. The assembly of the curved panel is also performed in the same manner as the flat panel. In the manufacturing of the cylindrical closed cross-sectional structure as shown in Fig. 11A, the entire flat panel is continuously joined by pushing the last panel in the vertical direction as shown in the drawing. You can do that.

Thus, the curved panel is composed of a curved surface having a predetermined curvature, and when connecting a plurality of curved panels, it is possible to manufacture a structure having a cylindrical closed cross section as shown in Figure 11a. Further, by adjusting the curvature of the curved panel it is possible to produce a cross section of the cylindrical structure not only circular but also elliptical. As such, the cylindrical structure having a closed cross-section manufactured using the curved panel according to the present invention may be used as a tank structure, a pier, a pillar, a pile, or the like, and may also be used as a water and sewage pipe.

On the other hand, as an example of the cross-sectional structure, the curved panel of the present invention can also be used in the arch structure as shown in Figure 11b.

In addition, according to the present invention, in forming the cylindrical or arched structure described above, by combining a curved panel and connectors similar to the flat panel and the connectors described above, a cylindrical or arched structure having a partition or the like, or other various structures I can make it.

In the present invention, the hollow 101 of the panel may be filled with a filler such as concrete, filler, rubble, solid waste mixture, mortar, polymer mortar, urethane resin, and the like. In this way, filling the hollow exhibits a heat insulating effect, a noise preventing effect, and the like, and in the case of a structure requiring a certain weight or more, an effect of increasing the weight of the structure is also exhibited. In particular, the panel forms a sandwich structure by the filler material, thereby exhibiting an effect of increasing rigidity. However, the hollow 101 does not necessarily need to be filled with a filler.

On the other hand, in the present invention, the protrusion coupling portion is detachably coupled mechanically, in practice, according to the user's intention may be used by permanently bonding the protrusion coupling portion by applying an adhesive.

The present invention as described above has an excellent synergistic effect as compared to the toggle using panel system shown in Figure 1a and 1b.

First of all, the present invention does not require a separate component used for assembling the panel, compared to a conventional toggle using panel system. In other words, the use of a separate member called a toggle, unlike the conventional panel system, the connection is completed simply by assembling both panels, so the handling is easy and the assembly operation is very simple.

In addition, in the conventional toggle using panel system, there is a limit to the range in which the panel can be utilized due to the direction in which the toggle is inserted in the transverse direction of the panel. There is no need to secure a separate space for insertion, and therefore has the advantage that it can be easily used in various sites. In particular, there is no risk of breaking the toggle in the toggle insertion process as in the conventional case, since the assembly is made by simply pressing, the assembly operation is very simple.

Particularly, in the present design, since the panel is completely coupled to two neighboring panels, the joints of the panels may be mutually formed to form a solid integrated structure between the panels without the connection gap, which is a problem with the conventional toggle. Since the fiber can be reinforced within the joint, i.e., the projection joint, the bond strength is very high and the connection strength of the panel is significantly improved over the conventional toggle using panel system.

Furthermore, using the inclined connector, right angle connection connector or T-type connection connector according to the present invention, the panel can be freely connected in an inclined state, a right angle state or an orthogonal state at a predetermined angle, so that a building wall, a floor plate, a platform, a box culvert It can be applied to various structures such as structures having open and closed cross-sectional structures, such as tank structures, pipe structures, and the like, and its utilization is further doubled.

In particular, the panel according to the present invention can also be configured as a curved panel having a curved surface, by connecting such a curved panel, it is possible to easily produce a cylindrical closed cross-section structure or an arcuate open cross-section structure, such a curved structure as a tank Structures, piers, columns, piles, pipes, arch structures, etc. can be achieved, the scope of application is very wide.

In the above described the configuration and features of the present invention based on the embodiment according to the present invention, the present invention is not limited to this and can be freely changed according to the technical idea of the present invention.

Claims (4)

A flat or curved fiber-reinforced composite panel (1) consisting of a top plate (2), a bottom plate (3) and an abdominal plate (4) having a plurality of plane or curved polygonal hollow cross sections, On one side of the panel 1, a first downward protrusion coupling portion 15a and a second downward protrusion coupling portion 15b are formed, and the first downward protrusion coupling portion 15a is formed by the upper plate 2. It is formed in the downward direction at the end of the upper extension portion 5 which is further extended to the side, the second downward protrusion coupling portion 15b is formed to protrude downward on the outer surface of the outer abdominal plate (4) Become; On the other side of the panel 1, the first upward protrusion coupling portion 15a 'which is mechanically coupled in a snap-fit form so as to be detachable from the first and second downward protrusion coupling portions 15a and 15b, respectively. And a second upward protrusion coupling part 15b ', the first upward protrusion coupling part 15a' protrudes upward from the outer surface of the outer abdominal plate 4, and the second upward protrusion coupling part 15b. ') Is provided upwardly from an end of the lower extension part 5' formed by extending the lower plate 3; The protrusion coupling portions 15a, 15a ', 15b, and 15b' are formed with protrusions 15c and 15c 'corresponding to each other so as to form a mechanical coupling, so that the adjacent bottom plate tube 1' and Are coupled to each other by a snap-fit mechanical detachment in a vertical direction, The first upward protrusion coupling portion 15a 'is formed inside the end portion of the upper extension portion 5 so as to increase the resistance in the horizontal direction in the state where the protrusion coupling portions are coupled to each other to further strengthen the engagement state of the protrusion coupling portion. The protruding support part 51 which supports the front-end | tip of the rear part is formed in the shape which protruded, and the recessed part is formed also in the inside of the edge part of the lower extension part 5 ', and the said 2nd downward protrusion coupling part 15b and the said When the second upward protrusion coupling portion 15b 'is coupled, the protrusion support portion 51 supporting the front end of the second downward protrusion coupling portion 15b is formed in a protruding shape. Fiber-reinforced composite panels. The method of claim 1, The hollow 101 of the panel is filled with a filler, fiber reinforced composite panel, characterized in that to form a sandwich panel structure. As a right angle connecting connector 20 for connecting two fiber-reinforced composite panels 1a and 1b of claim 1 at right angles to each other, The right angle connector 20 is made of a fiber reinforced composite material, has a T-shaped cross section consisting of the lower portion 21 and the central portion 22 integrally formed perpendicularly thereto, the transverse direction of the panels (1a, 1b) Extend transverse to the length; At one end of the lower portion 21 in the T-shaped cross section of the right-angle connecting connector 20, a second upward protrusion coupling portion 15tb 'coupled to the second downward protrusion coupling portion 15b of the second panel 1b is provided. It is formed to protrude vertically in the inward direction of the lower side 21, the second downward protrusion coupling is coupled to the other end of the lower portion 21 and the second upward protrusion coupling portion (15b ') of the first panel (1a). The portion 15tb is formed to protrude in the other end direction of the lower portion 21 from the inner side of the lower portion 21; A first downward protrusion coupling portion 15ta is formed at an end portion of the central portion 22 perpendicular to the lower portion 21 in the T-shaped cross section of the right-angle connecting connector 20, and the first downward protrusion coupling portion ( 15ta is protruded vertically from an end portion of the central portion 22 so as to be coupled to the first upward protrusion coupling portion 15a 'of the first panel 1a, and is formed at the end portion of the central portion 22. On the opposite side of the first downward protrusion coupling portion 15ta, the first upward protrusion coupling portion 15ta 'is formed to protrude in the end direction of the center portion 22, The first downward protrusion coupling part 15ta and the second downward protrusion coupling part 15tb of the right angle connecting connector 20 at the corners at which the first panel 1a and the second panel 1b face at right angles to each other. Is coupled to the first upward protrusion coupling portion 15a 'and the second upward protrusion coupling portion 15b' of the first panel 1a, respectively, and the first upward protrusion coupling portion 15ta of the right-angled connector 20 is connected. ') And the second upward protrusion coupling portion 15tb' are coupled to the first downward protrusion coupling portion 15a and the second downward protrusion coupling portion 15b of the second panel 1b, respectively. Right angle connecting connector of the fiber reinforced composite panel, characterized in that) and the second panel (1b) are connected to form a right angle to each other. T-shaped by connecting the fiber-reinforced composite panel (1a, 1c) of the two claims 1 arranged horizontally and the fiber-reinforced composite panel (1b) of claim 1 or 2 arranged perpendicularly to each other at right angles. As the T-shaped connecting connector 40, The T-type connecting connector 40 is made of a fiber reinforced composite material, has a T-shaped cross section consisting of a lower portion 21 and a central portion 22 integrally formed thereon, and the panels 1a, 1b, and 1c. Extend transverse to the transverse length of the transverse direction; A second upward protrusion coupling portion 15tb 'coupled to the second downward protrusion coupling portion 15b of the second panel 1b at one end of the lower portion 21 in the T-shaped cross section of the T-type connecting connector 40. Is formed to protrude vertically in the inward direction of the lower side 21, the second downward projection coupled to the second upward protrusion coupling portion (15b ') of the first panel (1a) at the other end of the lower portion (21). The engaging portion 15tb is formed to protrude in the other end direction of the lower portion 21 from the inner side of the lower portion 21; A first downward protrusion coupling portion 15ta is formed at an end portion of the central portion 22 perpendicular to the lower portion 21 in the T-shaped cross section of the T-type connecting connector 40. The first downward protrusion coupling portion 15ta protrudes vertically downward from an end portion of the central portion 22 so as to be coupled to the first upward protrusion coupling portion 15a 'of the first panel 1a. A first upward protrusion coupling portion 15ta 'protrudes toward an end of the central portion 22 on the opposite side of the first downward protrusion coupling portion 15ta; In the middle of the outer side of the lower portion (21), a first upward protrusion coupling portion (15pa ') which is engaged with the first downward protrusion coupling portion (15a) of the third panel (1c) is formed to protrude; The other end of the lower portion 21 is further provided with a horizontal portion 23 extending in the direction of the third panel 1c; At the end of the horizontal portion 23, a second upward protrusion coupling portion 15pb 'coupled to the second downward protrusion coupling portion 15b of the third panel 1c is provided to protrude upward. The first downward protrusion coupling part 15ta and the second downward direction of the T-type connecting connector 40 at corners at which the first and third panels 1a and 1c and the second panel 1b face at right angles to each other. The protrusion coupling portion 15tb is coupled to the first upward protrusion coupling portion 15a 'and the second upward protrusion coupling portion 15b' of the first panel 1a, respectively, and is formed of the T-type connecting connector 40. The first upward protrusion coupling portion 15ta 'and the second upward protrusion coupling portion 15tb' are respectively coupled to the first downward protrusion coupling portion 15a and the second downward protrusion coupling portion 15b of the second panel 1b. The first downward protrusion coupling portion 15a and the second downward protrusion coupling portion 15b of one side of the third panel 1c are respectively provided outside the lower portion 21 of the T-type connecting connector 40. Coupled with the first upward protrusion coupling part 15pa 'and the second upward protrusion coupling part 15pb', the two first panels 1a and 1c and one second panel 1b form a T-shape. T type of fiber reinforced composite panel, characterized in that to be connected to each other Results connector.