KR100698475B1 - An Insert Structure for Mechanical Combination of Sandwich Panels - Google Patents

Abstract

An insert structure for mechanical combination of a sandwich panel is provided to improve the stability of the combination structure by increasing the assembling rigidity of the sandwich panel with an outer flange. An insert(100) is divided into an upper part(100a) and a lower part(100b), and outer flanges(150a,150b) are formed in the insert to increase the assembling rigidity of a sandwich panel and the insert. A male screw is formed in a lower end of the upper part, and thread-connected to a female screw inside the lower part. An insertion hole is formed in the sandwich panel corresponding to flanges(130a,130b) of the insert. The upper part and the lower part of the insert are inserted to the sandwich panel, and the upper part is combined with the lower part of the insert by an assembling part(160). The outer flange of the upper part is contacted to the upper part of the sandwich panel, and the outer flange of the lower part of the insert is contacted to the lower part of the sandwich panel.

Description

Insert Structure for Mechanical Fastening of Sandwich Panels {An Insert Structure for Mechanical Combination of Sandwich Panels}

1 is a cross-sectional view of a sandwich panel insert structure according to the prior art.

Figure 2 is an exploded cross-sectional view of the insert according to the present invention.

3 is a cross-sectional view of the sandwich panel insert structure according to the present invention.

** Description of the symbols for the main parts of the drawings **

100: insert 100a, 100b: insert top and bottom

110: main body 120: fastener

130, 130a, 130b: flange 140: inlet

150a, 150b: outer flange 160: coupling portion

200: sandwich panel

210: face material 220: heart material

The present invention relates to an insert structure for mechanical fastening of a sandwich panel, and more particularly, to an insert structure that can have a high fastening strength when connecting the mounting or external components to the sandwich panel through bolts. .

A sandwich panel is a panel made of metal (or fiber-reinforced composite) plates on both sides, like a sandwich, with a core in the middle. Plates on both sides are called face materials, which mainly use materials of high strength and rigidity, and core materials use relatively weak materials to maintain the cross section. Sandwich panels are classified into embossing sandwich panels, flat surface sandwich panels, and the like according to their form. Long members give unevenness to the panel surface at regular intervals because of their reduced smoothness. These panels are embossed sandwich panels, and panels with only joints like stones are called flat sandwich panels. There are also curved panels for use as roofing materials. In addition, the core material of the sandwich panel is EPS (styrofoam), polyurethane, PUR, PIR, glass wool, mineral wool and the like. Glass wool is an artificial mineral fiber made by melting silica sand, which is a raw material for glass, at high temperature. Glass wool sandwich panel is produced in Korea since 1991 as a building insulation material that blocks heat and noise without burning well. Sandwich panel cores with styrofoam or urethane foam have the advantages of being light and inexpensive, but the demand for glass wool is greatly increasing due to the vulnerability to fire and the generation of toxic gases. Glass wool is known to be a flame retardant material that can minimize human life and property damage because it is advantageous for the early evolution of fire. There are also panels that contain glass wool and mineral wool at a certain ratio.

The sandwich panel is light and strong, so it can be used as an excellent self-supporting structure. The design and construction are simple, and the panel itself is flame retardant. 49 times of creek and 42 times of cement brick) It saves more than 30% of energy compared to general building materials by saving air-conditioning maintenance cost. In addition, since it does not absorb moisture, the waterproof and moisture-proof effects are high, and the joints are completely blocked during construction, so the secret of personal privacy can be maintained. In addition, various textures and colors of the surface can be chosen at will, and the shape can be freely created to create a beautiful environment according to one's personality.The construction period is completed by assembling on a frame made of simple subsidiary materials. This drastically shortens the construction cost. Because of these advantages, the demand for prefabricated buildings using sandwich panels is gradually increasing. Sandwich panels are also widely used in structures that require lightweight, such as aerospace vehicles.

BACKGROUND ART When a sandwich panel is used to connect a payload or an external component, a technique for installing an insert in a sandwich panel in advance is widely known. 1 is a cross-sectional view showing a state in which such a conventional insert is installed in the position panel. The insert 100 is installed on the sandwich panel 200 as follows. First, the insertion hole for inserting the insert 100 is drilled into the sand position panel 200 in which the core material 220 is sandwiched between two face members 210. The insert 100 has a flange 130 above and below the main body 110 in which the fastening part 120 is formed. In particular, the flange 130 on one side or both sides may have an adhesive material such as epoxy (hereinafter, briefly described). In general, the injection hole 140 for injecting epoxy is formed. In this case, the fastening part 120 is a part used when the sandwich panel 200 is coupled to another part by using the insert 100, and is generally formed in the form of a through hole or a screw. The insertion hole formed in the sandwich panel 200 has the same size as the flange 130 of the insert 100. After inserting the insert 100 into the sandwich panel 200 insertion hole, and injecting epoxy through the injection hole 140 formed in the flange 100 of the insert 100, the epoxy is the core material 220 of the sandwich panel 200. The insert 100 is fixedly fastened to the sandwich panel 200 by being bonded to the sandwich panel 200.

In the conventional insert structure, the fastening strength of the insert 100 and the sandwich panel 200 is proportional to the contact area between the epoxy 300-the body 110 and the epoxy 300-the core 220. . In other words, the thicker the sandwich panel 200 is, the more the surface in contact with the epoxy 300 and the main body 110 and the epoxy 300 and the core material 220 increases, thereby increasing the fastening strength. According to this prior art, the fastening strength between the insert 100 and the sandwich panel 200 is limited by the thickness of the sandwich panel 200. When used in a general building, the surrounding environment, especially the dynamic environment, does not change significantly in the building, so the problem of limiting the tightening strength is overcome to some extent, such as by appropriately increasing the number of inserts and distributing the load when designing. can do. However, in the case of non-building structures, for example, structures mounted on an aircraft, the dynamic environment changes rapidly in a very wide range. In such a case, the simple solution as described above cannot sufficiently increase the stability. In particular, the possibility that the insert 100 may be broken and separated from the sandwich panel 200 due to strong external force and vibration or a severe pressure or temperature change cannot be excluded. Therefore, when the thickness of the sandwich panel 200 is fixed, there has been a constant demand among those skilled in the art for a technique that can improve the fastening strength.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, an object of the present invention is to provide a sandwich panel of the same thickness when connecting the mounting or external components to the sandwich panel through bolts It is to provide an insert structure for the mechanical fastening of the sandwich panel to obtain a high fastening strength.

Insert structure for mechanical fastening of the sandwich panel of the present invention for achieving the above object, the flange is formed on the upper and lower body, the fastener penetrating through the main body and the flange to connect the sandwich panel with other components is In the structure of the insert is formed, the inlet is formed in the flange and is coupled to the sandwich panel by injecting epoxy through the inlet, wherein the insert is separated into the upper and lower with a coupling portion to be separated and combined with each other It features. At this time, the coupling portion of the insert is characterized in that the male screw is formed at the top and the female screw in the lower portion, or the female screw and the lower portion is formed in the upper portion is screwed together. In addition, an outer flange having a larger diameter than the flange is further provided on the outside of the flange.

Hereinafter, an insert structure for mechanical fastening of a sandwich panel according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

Figure 2 is an exploded front and top view of the insert according to the present invention. As shown in Figure 2 (A), the insert 100 according to the present invention is separated into an upper portion (100a) and a lower portion (100b), and unlike the conventional insert structure further the outer flange (150a, 150b) Have. Coupling portion 160 is formed to the inner side of the lower portion and the lower portion (100b) of the upper portion (100a), as shown, the lower portion of the upper portion (100a) is a male screw type, the inner side of the lower portion (100b) It is desirable to be in the form of a female screw to be screwed together. At this time, as shown in FIG. 2B, the upper and lower parts 100a and 100b are formed at the lower end of the upper part 100a by the female screw type and the male screw type protruding from the lower part 100b. It may be screwed together.

3 is a cross-sectional view of the sandwich panel insert structure according to the present invention. Since the conventional insert was integral, the insert having the same size as the flange of the insert had to be drilled in order to insert the conventional insert into the sandwich panel 200. Therefore, the conventional insert was to be fixedly supported on the sandwich panel only by epoxy potting injected into the inlet. However, when the insert 100 is separated into the upper and lower parts 100a and 100b as in the present invention, it is possible to add a structure that can be supported unlike the conventional insert.

The outer flanges 150a and 150b shown in FIG. 3 are added for this purpose. The flanges 130a and 130b in the insert 100 according to the present invention are the same as the flanges in the conventional insert, and have the same size as the insertion hole formed in the sandwich panel 200. The outer flanges 150a and 150b are formed to have a larger size than the flanges 130a and 130b. As such, the outer flanges 150a and 150b are further provided, so that the insert 100 is further formed outside the insertion hole of the sandwich panel 200, as shown in FIG. Fastening strength of the 100 and the sandwich panel 200 can be stronger than before.

Method for assembling the insert according to the invention to the sandwich panel is as follows. First, an insertion hole having the same size as the flanges 130a and 130b of the insert 100 according to the present invention is formed in the sandwich panel 200. The insert upper portion 100a and the lower portion 100b are inserted into the upper and lower portions of the sandwich panel 200 having the insertion hole, and the insert upper portion 100a and the lower portion 100b are fastened to each other by the coupling portion 160. Thereafter, as in the prior art, the epoxy is injected through the injection hole 140 such that the main body 110 of the insert 100 and the core material 220 of the sandwich panel 200 are coupled to each other by the epoxy 300. . At this time, since the outer flange 150a of the insert upper portion 100a is supported on the upper surface of the sandwich panel 200, and the outer flange 150b of the insert lower portion 100b is closely supported on the lower surface of the sandwich panel 200, The insert structure according to the present invention can have a higher tightening strength than the conventional one by being able to obtain a bearing force by the outer flange (150a, 150b) in addition to the bonding force by the epoxy potting obtained in the conventional insert structure. In particular, the outer flanges 150a and 150b further increase the bonding force in the sandwich panel penetration direction.

The present invention is not limited to the above-described embodiments, and the scope of application of the present invention is not limited to those of ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications can be made.

As described above, according to the present invention, in addition to the bonding force obtained in the conventional insert structure, there is an effect of increasing the bonding force in the sandwich panel penetration direction by the external flange in the present invention, and consequently the insert and sandwich panel There is an effect of dramatically increasing the overall tightening strength of the liver. Particularly in an environment where vibration, external force, and other changes in external environment (pressure, temperature, etc.) are severe, it is possible to implement an insert structure having a stronger tightening strength under the same conditions. The sandwich panel structure adopted has the effect of being able to obtain higher safety.

Claims (3)

A flange is formed above and below the main body, and a fastener penetrating the main body and the flange is formed to connect the sandwich panel with other parts, and an injection hole is formed in the flange to inject epoxy through the injection hole, thereby joining the sandwich panel. In the structure of the insert being The insert structure of the insert for mechanical fastening of the sandwich panel, characterized in that separated into the upper and lower having a coupling portion to be separated and combined with each other. The method of claim 1, The insert portion of the insert, the insert structure for the mechanical fastening of the sandwich panel, characterized in that the male screw is formed at the top and the female thread at the bottom, or the female screw and the bottom is formed at the top and screwed together. The method of claim 2, Insert structure for mechanical fastening of the sandwich panel, characterized in that the outside of the flange is further provided with an outer flange having a larger diameter than the flange.

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