KR102129997B1 - A panel comprising a distributed pattern structure on load transfer path for stress concentration avoidance - Google Patents

Abstract

The present invention relates to a plate-shaped member including at least one cutting unit, and more particularly, to a panel including a distributed pattern structure of a load transmission path for avoiding stress concentration, which comprises a reinforcement unit provided along a plate-shaped member to distribute external force acting on the plate-shaped member. The reinforcement unit includes: a pair of first reinforcement units in which one side extends in parallel with a direction away from the cutting unit from a predetermined separated point to both sides from the cutting unit; a pair of second reinforcement units in which one side separately extends from the other side of the first reinforcement units, and connected to each other at the other side thereof; and a third reinforcement unit formed by extending from the other side of the second reinforcement units by a predetermined length. According to the present invention, stress concentration can be fundamentally avoided while achieving an original purpose of a reinforcement structure.

Description

A panel comprising a distributed pattern structure on load transfer path for stress concentration avoidance}

The present invention relates to a panel including a load transmission path dispersion pattern structure for stress concentration avoidance, and more particularly, to a reinforcing structure for avoiding stress concentration applied to a plate-shaped member.

Plate-like members used in aircraft are generally constructed very thinly for weight reduction. Therefore, when the load is applied due to structural weakness, a reinforcement structure is installed to prevent buckling. 1 shows an example of an aircraft panel having a reinforcing structure as a prior art. On the other hand, unintended stress concentration may occur due to the reinforcement structure due to shape constraints when manufacturing an aircraft panel. It is a well-known fact that stress concentration is preferably not generated because it has a fatal adverse effect on the life of the structure when stress concentration occurs. Previously, methods to increase the thickness of the stress concentration section or to increase the fillet radius at the end of the reinforcement structure were used to alleviate the degree of stress concentration.

On the other hand, Korean Patent Registration No. 1837217 is disclosed in connection with the prior art. However, since these methods are not fundamental solutions, they may eventually exhibit the same type of stress concentration and pose a potential risk of destruction.

Republic of Korea Registered Patent No. 1837217 (Registration on April 19, 2018)

An object of the present invention is to provide a decentralized aircraft reinforcement structure pattern that can prevent breakage and achieve light weight when reinforcing a panel applied to a conventional aircraft.

As a solution for solving the above problems, in a plate-shaped member including at least one cutting portion, the plate includes a reinforcing portion provided along the plate-shaped member to disperse an external force acting on the plate-shaped member, and the reinforcing portion includes: A pair of first reinforcing portions that are formed to extend in parallel in a direction away from the cutting portion from a point spaced apart by a predetermined distance, one side is formed to extend from the other side of the pair of first reinforcing portions, respectively, as long as they are connected to each other at the other side A panel including a load transmission path dispersion pattern structure for avoiding stress concentration may be provided, including a pair of second reinforcing portions and a third reinforcing portion formed to extend a predetermined length from the other side of the pair of second reinforcing portions.

Here, the third reinforcement portion may be configured to be thicker than the second reinforcement portion.

Meanwhile, the first reinforcing part and the third reinforcing part are configured to be parallel to each other, and the second reinforcing part may extend at an angle of 30 degrees or less with the first and third reinforcing parts.

In addition, the first reinforcement portion and the second reinforcement portion may be configured to be symmetrical with respect to a virtual axis in a direction in which the third reinforcement portion extends.

Meanwhile, the first reinforcement portion, the second reinforcement portion, and the third reinforcement portion may be formed to protrude at a predetermined height from the plate-shaped member.

On the other hand, when the cutting portion is provided in plural, the first reinforcing portion and the second reinforcing portion are composed of a plurality and are formed to correspond to the positions of the respective cutting portions. Can be.

The panel including the load transmission path dispersion pattern structure for stress concentration avoidance according to the present invention achieves the purpose of the reinforcement structure and fundamentally avoids stress concentration while simultaneously installing various equipment provided adjacent to the pattern. It has the effect of expanding the space.

1 is an example of a reinforcing structure applied to a conventional panel.
2 is a conceptual diagram of an embodiment according to the present invention.
3 is a conceptual diagram of another embodiment according to the present invention.
4 is a conceptual diagram of another embodiment according to the present invention.

Hereinafter, a panel including a load transmission path dispersion pattern structure for avoiding stress concentration according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. And in the description of the following embodiments, the names of each component may be referred to as other names in the art. However, if they have functional similarity and identity, even if a modified embodiment is employed, it can be regarded as an even configuration. In addition, symbols added to each component are described for convenience of description. However, the illustrated contents on the drawings in which these codes are described do not limit each component to the range in the drawing. Similarly, even if an embodiment in which some modifications of the configuration on the drawing is employed, it can be regarded as an equivalent configuration if there is functional similarity and identity. In addition, in light of the level of general skill in the art, if it is recognized as a component to be included, description of it will be omitted.

Hereinafter, a panel according to an embodiment of the present invention will be described in detail with reference to FIGS. 2 to 5.

2 is a conceptual diagram of an embodiment according to the present invention. As shown, the panel structure according to the present invention may be configured to include a reinforcing structure added to the panel 1 which is a plate-like member including a structure in which stress concentration can occur. The plate-shaped panel 1 may be, for example, a flat panel 1. One side of the panel (right side in FIG. 2) may include a cutting part 2. The cutting portion 2 of the panel may be formed for the purpose of mechanically joining a plurality of panels, such as joining an external structure. The cutting part 2 of the panel may be a notch structure, for example, as shown in FIG. 2.

The reinforcing structure is configured to disperse the load when an external force is applied to the panel to prevent the stress from being concentrated in the cutting part 2. The reinforcement 3 may be attached to one side of the panel or may be integrally formed with the panel.

The reinforcement part 3 may be configured to form a constant pattern including the first reinforcement part 31, the second reinforcement part 32, and the third reinforcement part 33.

The first reinforcing part 31 is configured to disperse the load transmitted to the cutting part 2 from the outside. The first reinforcement portion 31 is formed to be spaced a predetermined distance from the cutting portion 2 and is provided along the panel in a direction away from the cutting portion 2 on both sides of the cutting portion 2. The first reinforcing portion 31 is composed of a pair and may be formed to extend parallel to each other. One end of the first reinforcing portion 31 is formed to extend to the end of the panel, the other end may be configured to have a length beyond the position where the cutting portion 2 is formed.

The second reinforcement parts 32 are formed to extend from the pair of first reinforcement parts 31, respectively. One end of the second reinforcing portion 32 extends from the other end of the first reinforcing portion 31, and while extending, the first reinforcing portion 31 is extended so that a pair of second reinforcing portions 32 can be connected to each other. It may be formed by placing a direction and a predetermined angle. The second reinforcing parts 32 are connected to each other so that external loads transmitted from the first reinforcing parts 31 are connected to one another and transmitted to each other. Therefore, even if the external force is concentrated around the cutting portion 2, the external force can be distributed by connecting the panel itself and the second reinforcement portion 32 between the first reinforcement portion 31.

The third reinforcing portion 33 is formed to extend from the second reinforcing portion 32 and is configured to distribute the load acting on the panel. The third reinforcing part 33 is formed to extend from the other side of the second reinforcing part 32. The extending direction may be a direction parallel to the extending direction of the first reinforcement part 31.

On the other hand, the first reinforcing part 31 and the second reinforcing part 32 may constitute one load transmission path, and a pair of load transfer paths are combined in the third reinforcing portion 33 to form one load transfer path. Can be as In other words, the third reinforcing portion 33 may be configured symmetrically in the vertical direction based on the virtual axis in the direction in which it extends.

The thickness of the reinforcing portion 3 may be configured to have the same overall thickness so that the stress is not concentrated in any part of the reinforcing portion 3 and the load can be distributed. For example, when the thickness of the third reinforcing portion 33 where two load transmission paths are combined is t, the first reinforcing portion 31 and the second reinforcing portion 32 are formed to a thickness of t/2 or less. It can be composed of a pair of load transmission paths. Specifically, the thickness of the first reinforcement part 31 and the second reinforcement part 32 constituting one load distribution path is preferably composed of 30% to 50% of the thickness of the third reinforcement part 33.

3 is a conceptual diagram of another embodiment according to the present invention. 3 shows an example in which cutting portions 2 are provided on both sides of the plate-shaped panel 1. When configured as described above, the shape of the reinforcing portion may be differently applied to avoid concentration of stress in each of the cutting portions 2 provided on both sides.

In this embodiment, the reinforcing part 3 is provided in a form that wraps each cutting part 2 on a plane, that is, the first reinforcing part 31 and the second reinforcing part 32 are provided corresponding to each of the cutting parts 2. Can be. Meanwhile, the third reinforcing portions 33 may be connected to the second reinforcing portions 32 on both sides so that loads generated on both sides can be transmitted by the reinforcing portions. As shown, when the cutting parts 2 are provided on both sides, the reinforcement parts may be symmetrically left and right.

Meanwhile, the angle at which the second reinforcement part 32 extends may be configured to maintain a certain angle with the first reinforcement part 31 and the third reinforcement part 33. The arrangement angle of the second reinforcing parts 32 may be arranged at 60-degree intervals to each other so that the load can be most stably and efficiently distributed by external forces generated in the plane direction. In addition, the first reinforcing portion 31 and the third reinforcing portion 33 are disposed at 30-degree intervals to achieve structural stability. However, this is only an example, and the second reinforcing portion 32 is formed at an angle of 30 degrees or less with the first reinforcing portion 31 or 30 degrees or more in consideration of the direction of the load with high frequency. 2 The angle of the reinforcing part 32 may be changed and applied differently.

The reinforcing part 3 may be formed by being combined into a single member in the third reinforcing part 33, so that the area where the reinforcing member does not exist can be geometrically determined. Therefore, as shown in FIG. 1, the dead volume can be minimized while having an equal or greater load distribution effect than when the parallel reinforcement part is provided.

On the other hand, the reinforcing part 3 according to the present invention is additionally attached to the top surface or the slope, which is the widest surface of the plate-shaped panel 1, to reinforce the structure, or may be formed of a plate-shaped panel 1 and an integral member. It may be provided in the plate-shaped panel 1 in various ways, such as being formed in a single member by being laminated in the thickness direction of the upper surface or the lower surface.

4 is another embodiment according to the present invention. 4 shows holes and notches formed in the panel. In this embodiment, the panel is composed of curved surfaces. Here, the first reinforcing part 31 and the second reinforcing part 32 are configured to cover the hole in a plane. One side of the second reinforcing portion 32 is connected to each other at one point, and extends in the form of being joined to each other, so that the third reinforcing portion 33 can be configured. In this case, the load transmitted to the hole can be distributed to the reinforcing member in the same manner as in the above-described embodiment, so that the stress concentration can be prevented structurally.

As described above, the panel including the load transmission path dispersion pattern structure for stress concentration avoidance according to the present invention is provided adjacent to the pattern while simultaneously achieving the purpose of the reinforcement structure and fundamentally avoiding stress concentration. It has the effect of expanding the space where various equipment is installed.

1: Plate type panel
2: cutting part
3: Reinforcement
31: first reinforcement
32: second reinforcement
33: third reinforcement

Claims (6)

In the panel comprising at least one cutting portion,
It includes a reinforcement provided along at least one of the top or bottom surface of the panel to disperse the external force acting on the panel,
The reinforcement,
A pair of first reinforcing portions formed by extending in parallel in a direction away from the cutting portion from a point where one side is spaced a predetermined distance from both sides of the cutting portion;
A pair of second reinforcing portions formed on one side extending from the other side of the pair of first reinforcing portions, and connected to each other on the other side; And
A panel including a load transmission path dispersion pattern structure for avoiding concentration of stress including a third reinforcement formed by extending a predetermined length from the other side of the pair of second reinforcement portions. According to claim 1,
The third reinforcing portion is a panel including a load transmission path dispersion pattern structure for stress concentration avoidance, characterized in that thicker than the second reinforcing portion. According to claim 2,
The first reinforcement and the third reinforcement are configured to be parallel to each other,
The second reinforcing part is a panel including a load transmission path dispersion pattern structure for avoiding stress concentration, characterized in that the first reinforcing part and the third reinforcing part extend at an angle of 30 degrees or less. According to claim 3,
The first reinforcement and the second reinforcement,
A panel including a load transmission path dispersion pattern structure for avoiding stress concentration, characterized in that the third reinforcing portion is symmetrical based on an imaginary axis in the extending direction. According to claim 3,
The first reinforcing portion, the second reinforcing portion and the third reinforcing portion is a panel including a load transmission path dispersion pattern structure for stress concentration avoidance, characterized in that formed to protrude to a predetermined height from the panel. The method of claim 5,
When the plurality of cutting parts are provided,
The first reinforcing part and the second reinforcing part are composed of a plurality and are formed in correspondence with the positions of the respective cutting parts,
The third reinforcing part is a panel including a load transmission path dispersion pattern structure for stress concentration avoidance, characterized in that each of a plurality of second reinforcing parts are connected to each side.

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