JP6025246B2 - Wing ribs - Google Patents

Description

  The present invention relates to a wing rib.

  Aircraft fuel tanks are installed in the main wing. The main wing has a built-in rib for holding the wing shape. The resistance against the external force received by the main wing depends on the strength of the rib, for example. Therefore, the main wing rib is strongly required to have high strength in addition to lightness. Furthermore, it is also required to be low cost. For example, the structure of the main wing rib is required to be simple.

  An example of a conventional metal main wing rib is shown in FIG. In FIG. 4, 11 is a web and 12 is a flange (shear tie). Reference numeral 13 denotes a cord (strengthening cord) provided at the boundary between the web 11 and the flange 12. 14 is a stiffener. The flange 12 and the stiffener 14 are attached to the web 11 by, for example, fasteners (not shown). That is, in the conventional main wing rib, each part (web 11, flange 12, cord 13, stiffener 14) produced separately is connected by a fastener. For this reason, the cost is high. There is also concern about the strength of the joints by fasteners.

JP 2002-302097 A JP 2003-72691 A JP 2009-227166 A

  The problem to be solved by the present invention is to provide a blade rib excellent in lightness, high strength, and low cost (structural simplicity).

The above issues are
A wing rib comprising a web with a built-in core and a flange provided at an end of the web,
The core is composed of a honeycomb core or a foam core,
The surface layer portion of the web covering the core and the flange are made of the same kind of fiber-reinforced composite material, without a joint, and integrally formed.
(Thickness of the surface layer portion covering the core at the end position of the built-in core)> Ri Der (thickness of the surface layer portion covering the core at the center position of the built-in core)
(The thickness of the web at the central position of the built-in core)> (the thickness of the web at the boundary between the web and the flange) Is done.

Preferably, a said wing ribs, a (thickness of the core at the end position of the core) ≒ (thickness of the core at the center position of the core), (wherein the end position of the core The thickness of the surface layer portion covering the core )> (thickness of the surface layer portion covering the core at the center position of the core ) is solved by the blade rib. Preferably, a said wing rib, and characterized by a (thickness of the web at the end position of the built-in core)> (thickness of the web at the center position of the built-in core) Solved by the wing ribs.

Preferably, a said wing ribs, a (thickness of the core at the end position of the built-in core) <(thickness of the core at the center position of the built-in core), (the built wing rib, characterized in that the thickness of the surface layer portion covering the core) is> (thickness of the surface layer portion covering the core at the center position of the built-in core) in cores end position of the Solved by. Preferably, the a wing rib, the thickness of the core at the end position of the built-in core is solved by the wing rib, characterized by comprising substantially uniform thin from both sides. Preferably, a said wing rib, and characterized by a (thickness of the web at the center position of the built-in core) ≧ (the thickness of the web at the end position of the built-in core) Solved by the wing ribs.

  Preferably, the rib for the wing, wherein the fiber reinforced composite material is a carbon fiber reinforced composite material, a glass fiber reinforced composite material, a ceramic fiber reinforced composite material, an organic fiber reinforced composite material, or a metal fiber reinforced composite material. It is solved by a wing rib characterized by being one or more selected from the inside.

  Preferably, the blade rib is solved by the blade rib, wherein the core exists up to a position near the web end.

  Preferably, the above-mentioned wing rib is solved by a wing rib characterized by not having a stiffener.

  Preferably, the wing rib is solved by the wing rib characterized by not having a cord.

The above issues are
A method of manufacturing the wing rib,
The core, the surface layer of the web covering the core, and the fibers constituting the fiber reinforced composite material constituting the flange are set in a mold, and then impregnated and cured with resin by vacuum suction or pressurization with a pump This is solved by a method for manufacturing a rib for a blade.

  A wing rib with high lightness and mechanical strength can be obtained at low cost.

The schematic plan view of the rib for main wings which becomes 1st Embodiment of this invention. Schematic sectional view of the main wing rib according to the first embodiment of the present invention. Schematic sectional view of a main wing rib according to a second embodiment of the present invention Schematic cross-sectional view of a conventional main wing rib

  The first aspect of the present invention is a wing rib. In particular, it is a main wing rib (insper rib). The rib comprises a web. The rib includes a flange (shear tie). The said flange is provided in the edge part (especially both ends) of the said web. The web and the flange are integrally formed. The rib does not have a so-called stiffener. The rib does not include a so-called cord. The web contains a core. The core is provided for the purpose of improving the strength of the rib. The core is made of, for example, a foam core. Alternatively, it is composed of a honeycomb core. The core is provided up to a position near the web end. The rib satisfies the condition A [(thickness of the surface layer portion covering the internal core at the internal core end position)> (thickness of the surface layer portion covering the internal core at the internal core central position)]. .

  Satisfaction of the condition A is that the condition B1 [(core thickness at the core end position) ≈ (core thickness at the core center position)] and condition B2 [(thickness of the surface layer at the core end position). )> (Thickness of the surface layer portion at the central position of the core)] is satisfied. More preferably, the condition B3 [(the thickness of the web at the core end position)> (the thickness of the web at the core center position)] is satisfied.

More preferably, the following conditions are satisfied.
f / e = 1.1-2
g / e = 1.02-3
g> f
e is the thickness of the core. f is the thickness of the web at the core center position. g is the thickness of the web at the core end position.

More preferably, the following conditions are satisfied.
b / a = 1.02-2
c / a = 1.01-1.9
a is the length of the core. b is the distance between the flanges. c is the distance between the bulging portion (the bulging portion at the core end position) and the bulging portion.

More preferably, the following conditions are satisfied.
f / h = 1.01-5
h is the thickness of the thin portion at the flange front side.

  Satisfaction of the condition A is that the condition C1 [(core thickness at the core end position) <(core thickness at the core center position)] and condition C2 [(thickness of the surface layer portion at the core end position). )> (Thickness of the surface layer portion at the central position of the core)] is satisfied. More preferably, the condition C3 [(the thickness of the web at the core end position) ≧ (the thickness of the web at the core center position)] is satisfied. The core thickness at the end position of the core is preferably a case where the core thickness is reduced substantially uniformly from both sides.

  The core surface layer portion is preferably made of a fiber reinforced composite material. More preferably, the flange is also made of a fiber reinforced composite material. Particularly preferably, both the core surface layer portion and the flange are made of the same kind of fiber-reinforced composite material. This can be easily understood from the fact that the web (core surface layer portion) and the flange are integrally formed. The fiber reinforced composite material is, for example, one or more selected from the group of carbon fiber reinforced composite materials, glass fiber reinforced composite materials, ceramic fiber reinforced composite materials, organic fiber reinforced composite materials, and metal fiber reinforced composite materials. Particularly preferred fiber reinforced composite materials are organic fiber reinforced plastics such as carbon fiber reinforced plastic (CFRP) or aramid fiber reinforced plastic (AFRP) from the viewpoint of lightness and strength.

  2nd this invention is a manufacturing method of the said rib for blades. The manufacturing method includes a step of setting the fiber and the core in a mold. The manufacturing method includes a step of impregnating and curing the resin by vacuum suction or pressurization with a pump after the above step.

  Hereinafter, the present invention will be specifically described. However, the following description is only one embodiment of the present invention, and the present invention is not limited to this. That is, the present invention includes modifications and applications that do not greatly impair the features of the present invention.

  1 and 2 are explanatory views of a main wing rib according to the present invention. FIG. 1 is a schematic plan view of a main wing rib. FIG. 2 is a schematic cross-sectional view taken along the line II of FIG.

  In each figure, R is a rib. The rib R is roughly composed of a web 1 and a flange (shear tie) 2. The rib R does not have a cord or a stiffener that a conventional rib has.

  The web 1 has a core 3 made of foamed resin. The core 3 has a flat plate shape. The surface layer portion 4 covering the core 3 is made of carbon fiber reinforced plastic (CFRP). The web 1 has a sandwich structure.

  Reference numeral 5 denotes a core end. 6 is a core central part. The thickness of the surface layer portion 4 at the position of the core end portion 5 is thicker than the thickness of the surface layer portion 4 at the position of the core center portion 6. That is, the web 1 has a bulged shape at the core end 5 position. Reference numeral 7 denotes a thin portion formed in the middle from the bulging portion 8 to the flange 2 at the core end portion 5 position.

  As can be seen from FIG. 2, the cross-sectional shape of the rib R is symmetrical at least at the location of the web 1. In this embodiment, including the location of the flange 2, it is symmetrical. In some cases, the flange 2 may be on one side only. The overall shape is very simple as can be seen from FIGS.

  The rib R is obtained by placing carbon fibers around the core 3 so as to have the shape of FIGS. 1 and 2 and then impregnating the carbon fibers with a resin. That is, after the carbon fiber and the core were set in a mold, the carbon fiber was impregnated with resin by vacuum suction (or pressurization with a pump). The impregnating resin was cured. Therefore, each part is integrally configured. Since each part is integrally formed, it is not necessary to connect each part by a fastener or the like. Since it is an integral structure, the flange 2 is also made of CFRP. The rib R of the present invention is not a form in which each separately manufactured part is connected by a fastener like a conventional rib. The cost is low because it can be obtained easily.

The web 1 (surface layer part 4) and the core 3 satisfy the following conditions.
b / a = 1.02-2.00
c / a = 1.01-1.90
d = 50 mm to 500 mm
f / e = 1.01-2.00
g / e = 1.02 to 3.00
g> f
g = 5mm-100mm
f / h = 1.01-5
a = the length of the core 3 b = the distance between the flange 2 and the flange 2 c = the distance between the bulging portion 8 and the bulging portion 8 d = the length of the bulging portion 8 e = the thickness of the core 3 F = the thickness of the web 1 at the position 6 of the core central portion g = the thickness of the web 1 at the bulging portion 8 h = the thickness of the thin portion 7

  The weight of the main wing rib in the above embodiment was compared with the weight of the conventional (FIG. 4 type) main wing rib. The main wing rib of the above embodiment was much lighter.

  The main wing rib of the above embodiment is disposed in the main wing. For comparison, a conventional (FIG. 4 type) main wing rib was disposed in the main wing. Power was applied to each wing. The durability of each wing rib was examined. As a result, the main wing rib of the present embodiment was superior or inferior to the main wing rib of FIG.

  For comparison, a rib for a main wing having the shape of FIG. 4 was made of CFRP. However, the main wing ribs were inferior in mechanical strength. This indicates that satisfactory wing ribs cannot be obtained simply by replacing the constituent materials.

  FIG. 3 is a schematic cross-sectional view of a main wing rib according to a second embodiment of the present invention.

  The core 3 of the main wing rib of the first embodiment has a square cross section.

  In contrast, in the core 3 of the main wing rib of the second embodiment, the cross-sectional shape of the core end portion 5 is an isosceles triangle, as can be seen from FIG. That is, the thickness of the core 3 is thinner on the tip side closer to the flange 2. Moreover, the thickness of the web 1 at the core end portion (isosceles triangular portion) 5 position is substantially the same as the thickness of the web 1 at the core center portion 6 position. In the case of this embodiment, the thickness of the surface layer portion 4 at the core end portion 5 position is thicker than the thickness of the surface layer portion 4 at the core center portion 6 position. In the second embodiment, although there is no bulging form at the core end portion 5 position, the mechanical strength is ensured. The other basic configuration of the main wing rib of the second embodiment is the same as the other basic configuration of the main wing rib of the first embodiment. Therefore, details are omitted.

R-rib (wing rib)
1 Web 2 Flange (shear tie)
3 Core 4 Surface layer part 5 Core end part 6 Core center part 7 Thin part 8 Swelling part

Claims (14)

A wing rib comprising a web with a built-in core and a flange provided at an end of the web,
The core is composed of a honeycomb core or a foam core,
The surface layer portion of the web covering the core and the flange are made of the same kind of fiber-reinforced composite material, without a joint, and integrally formed.
(Thickness of the surface layer portion covering the core at the end position of the built-in core)> Ri Der (thickness of the surface layer portion covering the core at the center position of the built-in core)
The blade rib according to the following formula : (the thickness of the web at the center position of the built-in core)> (the thickness of the web at the boundary position between the web and the flange) . (Thickness of the core at the end position of the core) and ≒ (thickness of the core at the center position of the core),
The thickness of the surface layer portion covering the core at the end position of the core >> (the thickness of the surface layer portion covering the core at the center position of the core ). rib. (Thickness of the web at the end position of the built-in core)> wing rib as claimed in claim 2, characterized in that the (thickness of the web at the center position of the built-in core). (Thickness of the core at the end position of the built-in core) is <(thickness of the core at the center position of the built-in core)
Characterized in that (the thickness of the surface layer portion covering the core in the built-in core end position of) a> (thickness of the surface layer portion covering the core at the center position of the built-in core) The wing rib according to claim 1. Wing rib as claimed in claim 4 the thickness of the core at the end position of the built-in core characterized by comprising substantially uniform thin from both sides. (Thickness of the web at the center position of the built-in core) ≧ wing rib as claimed in claim 5, characterized in that the (thickness of the web at the end position of the built-in core). f / e = 1.02-2, g / e = 1.02-3, g> f (where e is the thickness of the core, f is the thickness of the web at the center position of the core, g: The blade rib according to any one of claims 1 to 6, wherein a thickness of the web at an end position of the core) . b / a = 1.02-2, c / a = 1.01-1.9 (where a is the length of the core, b is the distance between the flange and the flange, c is the bulging part) The blade rib according to any one of claims 1 to 7 , characterized in that ( a distance between the bulging portion at the end position of the core) and the bulging portion) . f / h = 1.01~5 (where, h: thickness of the web at the boundary position between the web and the flange) in any one of claims 1 to claim 8, characterized in <br/> be Wing ribs. The fiber reinforced composite material is at least one selected from the group consisting of a carbon fiber reinforced composite material, a glass fiber reinforced composite material, a ceramic fiber reinforced composite material, an organic fiber reinforced composite material, and a metal fiber reinforced composite material <br / > The wing rib according to any one of claims 1 to 9, wherein: The wing rib according to any one of claims 1 to 10, wherein the core exists up to a position near the end of the web.   The wing rib according to any one of claims 1 to 11, wherein the rib is not provided with a stiffener. The wing rib according to any one of claims 1 to 12, wherein the rib is not provided with a cord. A method for manufacturing a blade rib according to any one of claims 1 to 13,
The core, the surface layer of the web covering the core, and the fibers constituting the fiber reinforced composite material constituting the flange are set in a mold, and then impregnated and cured with resin by vacuum suction or pressurization with a pump A method for manufacturing a wing rib, characterized by comprising:

Images