KR20190070678A - Rubber seal plate connecting structure of aircraft - Google Patents

Abstract

The present invention relates to a rubber seal plate connection structure of an aircraft. According to the present invention, the rubber seal plate connection structure of an aircraft comprises: a panel placed adjacent to a control surface placed on a wing of the aircraft; a rubber seal plate placed to cover a space between the control surface on the wing and the panel; and a fastening unit which is penetrated by a penetrating hole of the panel and the rubber seal plate to be fastened to the panel overlapped with the rubber seal plate. The fastening unit comprises an insert which limits a fastening volume to be able to fasten by compressing the rubber seal plate into a certain range. According to the present invention, the rubber seal plate connection structure of an aircraft is able to provide a proper fastening force of the rubber seal plate or the panel even when a rubber seal is over-fastened, to improve precision, and to prevent the rubber seal plate and the panel from being damaged even when they are over-tightened.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a rubber-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rubber seal plate connection structure for an aircraft, and more particularly to a connection structure for coupling a rubber seal plate, which is installed adjacent to a steering surface, to a wing panel.

The aircraft has a control surface connected to the wing and the wing, and controls the maneuvering of the aircraft by adjusting the rotation angle of the control surface. Between the wing of the aircraft and the steering surface, a rubber seal plate is provided so that the shape changes according to the rotation angle of the steering surface to change the flow of the air.

The rubber seal plate is connected to the panel of the aircraft wing and is connected by different materials and fastened with bolts and nuts for ease of replacement. EP2923943 is disclosed for such a rubber seal fastening structure. However, when the bolts and nuts are fastened with an excessive amount of fastening, the panel or the rubber seal plate is damaged. Particularly, when the bolt and nut are not recognized, breakage may occur during the flight.

EP2923943 (Released on September 30, 2015)

It is an object of the present invention to provide a rubber seal plate connection structure for an aircraft which can prevent excessive tightening of a rubber seal plate structure of a conventional aircraft wing and prevent breakage of the rubber seal or panel upon excessive tightening.

As a means for solving the above-mentioned problems, there is proposed a vehicle equipped with a panel provided adjacent to a steering surface provided on a wing of an aircraft, a rubber seal plate provided to cover a space between the steering surface and a panel provided on the wing, And a fastening portion penetrating through the through hole of the panel and the rubber seal plate in the state of the rubber seal plate in a state that the rubber seal plate is in a predetermined range, and the fastening portion includes an insert which restricts the fastening amount so as to compress the rubber seal plate into a predetermined range, A rubber seal plate connection structure of the aircraft can be provided.

Here, the insert includes a cylindrical body portion, the fastening portion includes a bolt and a nut, and the bolt is configured to be inserted into the body portion of the insert, and the panel is formed with a through hole having a size allowing the bolt to pass therethrough , The rubber seal plate may be formed with a through hole having a size allowing the bolt and the insert to pass through.

The insert may include a rim protruding in an outer radial direction so as to support the rubber seal plate side in the thickness direction of the rubber seal plate when the bolt and the nut are fastened.

The body portion may be configured to have a length shorter than the thickness of the rubber seal so as to prevent the rubber seal plate from being compressed beyond a predetermined range when the bolt and nut are tightened and to support the rubber seal.

On the other hand, the through hole of the panel is formed in a tapered shape in contact with the bolt head, and the bolt head can be constituted of a tapered head corresponding to the tapered shape of the through hole.

And, the insert can be configured so that the compressive strength is lower than the panel and rubber seal plate so that the bolt and nut can be broken before the panel and rubber seal plate when tightened to above the critical range.

Further, the panel may be made of a composite material, and the insert may be made of plastic.

The connecting structure of the rubber seal plate of the aircraft according to the present invention can provide an appropriate fastening force of the rubber seal plate or the panel even when the rubber seal is fastened, thereby improving the accuracy and preventing damage to the rubber seal plate or the panel There is an effect that can be.

Figure 1 is a partial perspective view of a portion of an aircraft wing.
2 is a partial cross-sectional view of I-I 'of Fig.
FIG. 3 is a cross-sectional view of a conventional assembly and an assembled portion when fastened. FIG.
4 is a partial cross-sectional view of I-I 'to which a connection structure according to the present invention is applied.
5 is an exploded perspective view of a connection structure according to the present invention.
6 is a view showing the function of the insert when over-tightening the connection structure according to the present invention.
7 is a cross-sectional view of another embodiment according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a connection structure of a rubber seal plate of an aircraft according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the embodiments, the names of the respective components may be referred to as other names in the art. However, if there is a functional similarity and an equivalence thereof, the modified structure can be regarded as an equivalent structure. In addition, reference numerals added to respective components are described for convenience of explanation. However, the contents of the drawings in the drawings in which these symbols are described do not limit the respective components to the ranges within the drawings. Likewise, even if the embodiment in which the structure on the drawing is partially modified is employed, it can be regarded as an equivalent structure if there is functional similarity and uniformity. Further, in view of the level of ordinary skill in the art, if it is recognized as a component to be included, a description thereof will be omitted.

It is to be understood that the present invention is not limited to the configurations shown in the following drawings, and some or all of them may be exaggerated for convenience of explanation.

Figure 1 is a partial perspective view of a portion of an aircraft wing. The connection structure of the rubber seal plate 30 of the aircraft according to the present invention may be configured to connect the rubber seal plate 30 connecting the panel 10, which is a part of the wing, with the steering surface 20. [ The rotation of the control surface 20 of the aircraft causes the rotation of the rotation axis, and the air resistance of the control surface 20 changes according to the rotation angle of the control surface 20, thereby determining the operation of the aircraft. At this time, a discontinuous surface is generated on the outer surface between the wing panel 10 and the steering surface 20 according to the rotation angle of the steering surface 20. If there is a discontinuous surface, the control stability is affected, So as to have a smooth outer surface continuously. Here, the rubber seal plate 30 is made of a rubber material and is made of a highly elastic material so that its shape changes according to an external force. One end of the rubber seal plate 30 is fixed to the panel 10 of the wing and the other end is closely attached to one side of the steering surface 20. [ Accordingly, one side of the rubber seal flake is pressed and changed in shape by the operation of the control surface 20 to cover the discontinuous surface with a smooth outer surface.

2 is a partial cross-sectional view of I-I 'of Fig. Figure 2 shows a cross section of a conventional assembly. The panel 10 and the rubber seal structure are fastened with bolts 41 and nuts 42. At this time, the step can be minimized so that the outer surface of the assembled structure can be smoothly formed.

The panel 10 constituting the outer surface of the wing may be constructed of a composite material, for example, and a part of the panel 10 may be fixed to the frame of the wing although not shown. When the surface of the panel 10 that comes into contact with air is referred to as an upper surface, the rubber seal plate 30 is fixedly attached to the lower surface of the panel 10.

The rubber seal plate 30 is configured such that the connection portion with the panel 10 is stepped in the same manner as the thickness of the panel 10 so that the upper surface can be smoothly connected when the panel 10 and the rubber seal plate 30 are connected. .

The bolt 41 is configured to penetrate the panel 10 and the rubber seal. The panel 10 and the rubber seal plate 30 may be formed with through holes so that the bolts 41 can pass through. The bolt 41 may be configured as a tapered head so as to minimize the clearance at the time of engagement and to minimize the external protrusion. The panel 10 may have an inclined entrance at the through hole corresponding to the tapered head.

The washer 43 is tightly attached to the rubber seal plate 30 side, and the nut 42 is fastened and finally the fastening can be completed.

FIG. 3 is a cross-sectional view of a conventional assembly and an assembled portion when fastened. FIG. As shown in the figure, when the nut 42 is excessively fastened, there is a problem that the rubber seal plate 30 is crushed.

Since the rubber seal plate 30 is made of elastic material and has a relatively high strength, when the nut 42 is excessively fastened, a dimpling phenomenon (arrow) is generated in the rubber seal. The dimpling phenomenon to some degree at the time of tightening helps to secure the tightening but excessive dimpling causes deformation of the rubber seal plate 30 and extremely damage of the rubber seal plate 30. [ Further, when the rubber seal plate 30 is excessively deformed (indicated by the arrows), there is no problem at the time of tightening, but when the rubber seal plate 30 is broken at the time of flight, a very dangerous situation may occur. In general, when the bolts 41 and the nuts 42 of the aircraft are tightened by a worker, the parts are excessively fastened by the deviation of the rubber seal plate 30 even if they are tightened with the same torque, May be loosely fastened. Even when the nut 42 is excessively fastened, when the contact portion between the nut 42 and the rubber seal plate 30 is broken or deformed, proper torque resistance is not generated and the nut 42 is continuously tightened. Such a case may occur when the connecting portion of the rubber seal plate 30 is broken even if it is tightened to an appropriate torque by using a torque wrench.

3 (b) and 3 (c), the dimpling phenomenon of the panel 10, which is one of the existing problems, is shown. When the nut 42 is excessively tightened, the inlet of the through hole of the panel 10 is deformed and a phenomenon (a portion indicated by an arrow) in which the bolt 41 is recessed occurs. This can potentially result in permanent damage or residual stress of the panel 10, which presents a risk of breakage, which is very dangerous.

FIG. 4 is a partial cross-sectional view taken along line I-I 'of FIG. 5, and FIG. 5 is an exploded perspective view of a connection structure according to the present invention.

As shown, the panel 10 according to the present invention. The rubber seal plate 30 fastening structure may include a panel 10, a rubber seal plate 30, and a fastening portion. The panel 10 may be a structure forming the outer surface of the wing of the aircraft as described above. The rubber seal plate 30 is configured to cover the space between the panel 10 of the wing and the steering surface 20 as described above.

The fastening portion may include a bolt 41, a nut 42, a washer 43, and an insert 44. Here, the functions of the bolts 41, the nuts 42 and the washers 43 are generally used. Therefore, the function of the insert 44 will be described in detail below.

The insert 44 is configured so that the bolt 41 and the nut 42 can be compressed and tightened within a predetermined range when fastened. Here, the predetermined range means a range that prevents the bolt 41 and the nut 42 from being excessively tightened by a predetermined distance or less.

The insert 44 may comprise a body portion 441 and a rim 442.

The body portion 441 is formed in a cylindrical shape, and the bolt 41 can be inserted inward. One end of the body part 441 may be configured to be supported by the panel 10 and the other end may be configured to be supported by the washer 43 and the nut 42.

The length of the body portion 441 is configured to be inserted through the rubber seal plate 30. The length of the body portion 441 may be determined in relation to the thickness of the rubber seal plate 30 and may be shorter than the thickness of the rubber seal plate 30. [ Specifically, the length of the body portion 441 may be 50% to 95% of the length of the rubber seal plate 30. The distance between the bolt 41 and the nut 42 is limited to the length of the insert 44 by 50% to 95% of the length of the rubber seal plate 30 at the position where the fastener is finally fastened, (30) can also be compressed to 5% to 50%. Here, 50% refers to a critical thickness at which the rubber seal plate 30 is not broken even when it is compressed, and 95% refers to a minimum compressive force to prevent the rubber seal plate 30 from being separated by an external force during flight. However, the present invention is not limited to this example. However, the body portion 441 of the insert 44 may be configured to be shorter than the thickness of the rubber seal plate 30 so that a minimum compressive force can be provided. Here, the through hole of the rubber seal plate 30 may be formed to have the same inner diameter as the through hole of the panel 10 because the through hole of the rubber seal plate 30 can be extended by the elasticity of the rubber seal plate 30 itself. However, the inner diameter of the through hole is not limited thereto. The through hole may be formed in a different size than the through hole of the panel 10, and may have different inner diameters.

 The rim 442 is protruded outwardly at one end of the insert 44 and is configured to support the rubber seal plate 30 when the fastener is fastened. The rim 442 is formed by extending the rubber seal plate 30 in the longitudinal direction of the body portion 441 and extending to the opposite side by a predetermined length in the outward direction so as to be supported by the washer 43 and the nut 42 .

Fig. 6 is a view showing the function of the insert 44 during over-tightening of the connection structure according to the present invention. The insert 44 is configured to prevent damage to the panel 10 or the rubber seal plate 30 when the bolts 41 and the nut 42 are fastened to each other over the critical range.

The insert 44 is provided to prevent the bolt 41 and the nut 42 from being further tightened when the nut 42 is tightened to the critical distance but the rubber seal plate 30 or the panel 10 can be prevented from being damaged. Specifically, it can be broken more quickly than the panel (10) and the rubber seal plate (30). The insert 44 may be made of a plastic material and may have a breaking strength lower than that of the panel 10 and the rubber seal plate 30. [

The insert 44 is configured such that when the operator tightens the fastening range of the bolt 41 and the nut 42 beyond the predetermined range and exceeds the critical range, the insert 44 is broken and the worker can know it. Therefore, if the fastening amount exceeding the critical range is applied before the problem as shown in FIG. 3 occurs, which is caused by the excessive fastening of the fastener, it is possible to prevent the insert 44 from being broken first and the expensive parts to be damaged.

Even if the insert 44 is broken due to the application of the amount of the fastening exceeding the critical range, the operator can replace the insert 44 only and assemble the fastener again. Thus, the panel 10 and the rubber seal plate 30 are prevented from being damaged, The assembly will be done correctly.

7 is a cross-sectional view of another embodiment according to the present invention. As shown, the rubber seal plate 30 of the present invention can be applied in a polygonal shape. The insert 44 is formed to have a length slightly smaller than the thickness of the fastening portion of the rubber seal plate 30 so as to press the rubber seal plate 30 at the time of fastening. The rim 442 of the insert 44 is pressed by the bolt 41 but the rim 442 is pressed against the bolt 41, the nut 42 or the washer 43 .

As described above, the connecting structure of the rubber seal plate 30 of the aircraft according to the present invention can provide an appropriate fastening force of the rubber seal plate 30 or the panel 10 even when the rubber seal is fastened, It is possible to prevent breakage of the rubber seal plate 30 or the panel 10 even when excessive tightening is performed.

10: Panel
20: Control plane
30: Rubber seal plate
41: Bolt
42: Nuts
43: Washer
44: insert
441: Body part
442: rim

Claims (7)

A panel provided adjacent to the steering surface provided on the wing of the aircraft;
A rubber seal plate provided to cover a space between the control surface and the panel provided on the vane; And
And a fastening part penetrating through the through hole of the panel and the rubber seal plate in a state where the panel and the rubber seal plate are overlapped,
Wherein the fastening portion includes an insert for restricting an amount of fastening so that the rubber seal plate can be compressed and clamped within a predetermined range. The method according to claim 1,
Wherein the insert comprises a cylindrical body portion,
The fastening portion includes a bolt and a nut,
The bolt being adapted to be inserted into the body of the insert,
Wherein the panel is formed with a through hole having a size allowing the bolt to pass therethrough,
Wherein the rubber seal plate is formed with a through hole having a size allowing the bolt and the insert to pass therethrough. 3. The method of claim 2,
The insert
And a rim protruding in an outer radial direction to support the rubber seal plate side in a thickness direction of the rubber seal plate when the bolt and the nut are fastened. . The method of claim 3,
The body part
Wherein the rubber seal plate is configured to prevent the rubber seal plate from being compressed beyond a predetermined range when the bolt and the nut are tightened and to have a length shorter than the thickness of the rubber seal so as to support the rubber seal. Connection structure. 5. The method of claim 4,
Wherein the through hole of the panel is formed in a tapered shape in contact with the bolt head,
Wherein the bolt head comprises a tapered head corresponding to a tapered shape of the through hole. 6. The method of claim 5,
Wherein the insert has a compressive strength lower than that of the panel and the rubber seal plate so that the bolt and the nut can be broken before the panel and the rubber seal plate when the bolt and the nut are tightened beyond the critical range. Connection structure. The method according to claim 6,
Wherein the panel is made of a composite material, and the insert is made of plastic.

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