FITTINGS FOR ATTACHING THE VERTICAL TAIL STABILIZER OF AN AIRCRAFT

Abstract

The invention relates to fittings (41, 71) for fixing the vertical tail stabilizer of an aircraft in an area of its rear fuselage integrally manufactured with a composite material comprising: a) a first piece (43, 73) comprising lugs (45, 45′; 75, 75′) for fixing the vertical tail stabilizer and vertical walls (47, 47′; 77, 77′) for fixing the fitting (41, 71) to the frames (7); b) at least one pair of additional pieces (49, 49′; 79, 79′) comprising horizontal walls (51, 51′; 81, 81′) for fixing the fitting (41, 71) to the skin (5). The fitting (71) for fixing with an inclined load also comprises a second pair of pieces (90, 90′) having an angular shape comprising vertical walls (93, 93′) for the fixing with the lugs (75, 75′). The invention also relates to processes for assembling these fittings (41, 71).

Description

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit under 35 U.S.C. §119(e) of Spanish Patent Application No. ES 200901039, filed Apr. 21, 2009, which application is incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The present invention relates to fittings for attaching the vertical tail stabilizer of an aircraft and more particularly to fittings manufactured in composite.

BACKGROUND OF THE INVENTION

Despite the trend in recent years to implement the use of composites, such as the CFRP (Carbon Fiber Reinforced Plastic), in the largest possible number of components of an aircraft due to the weight savings that this material entails with respect to aluminum (the preferred metallic material used in aircraft), most aircraft manufacturers are hesitant to use carbon fiber to manufacture fittings, because their complexity makes them rather expensive to manufacture.

This is especially applicable to the fittings used for attaching vertical tail stabilizers which continue to be made with metallic materials.

The use of metal fittings as elements for attaching components made with composite materials in fuselage areas of the aircraft also made with composite materials brings forth several problems, such as their greater weight, and particularly those problems relating to the reduction of the effective skin area and to the assembly difficulties.

It is possible to manufacture fittings with composites having a shape similar to that of metallic fittings but, besides the cost resulting from the complex shape, they present, among others, the drawback that it is very difficult to achieve with this shape an optimized laminate structure able to perform the required load distribution.

The present invention aims to solve these drawbacks.

SUMMARY OF THE INVENTION

An object of the present invention is to provide fittings integrally manufactured with composite material for attaching the vertical tail stabilizer in the rear area of a structured aircraft fuselage based on a skin manufactured with composite material as a unitary piece, and on frames also manufactured with composite material.

It is another object of the present invention to provide fittings for fixing the vertical tail stabilizer in the rear area of an aircraft fuselage which can be easily assembled.

In a first step, these and other objects are achieved with a fitting comprising:

• • A first piece manufactured with composite material comprising lugs for fixing the vertical tail stabilizer and vertical walls for fixing the fitting to the fuselage frames.
  • At least one pair of additional pieces manufactured with composite material comprising horizontal walls for fixing the fitting to the fuselage skin.

In a first kind of fitting, these pair of additional pieces have an angular shape and are designed so that their horizontal walls are fixed to the skin by their inner face, and so that their vertical walls are fixed to the first piece. A suitable fitting for fixing the vertical tail stabilizer with a vertical load is thus achieved.

In another kind of fitting, the fitting also comprises a second pair of additional pieces, also manufactured with a composite material, with an angular shape, designed so that their horizontal walls are fixed to the skin by their upper face, being their vertical walls fixed to the lugs of the first piece. A suitable fitting for fixing the vertical tail stabilizer with an inclined load is thus achieved.

In a second step, these and other objects are achieved by providing assembly processes for these fittings.

In a preferred embodiment, the assembly of the fitting intended for fixing the vertical tail stabilizer with a vertical load comprises the following steps:

• • Assembling the first piece on the inner part of the skin, having previously incorporated the bushings in the boreholes of the lugs.
  • Assembling the pair of additional pieces fixing the horizontal walls to the skin by means of a mechanical attachment and fixing the vertical walls to the first piece by means of a mechanical attachment or a chemical attachment.

A very simple assembly process requiring no additional tasks in the final assembly line is thus achieved.

In another preferred embodiment, the assembly of the fitting intended for fixing the vertical tail stabilizer with an inclined load comprises the following steps:

• • Assembling the first piece on the inner part of the skin.
  • Assembling the first pair of additional pieces fixing the horizontal walls to the skin by means of a mechanical attachment and fixing the vertical walls to the first piece by means of a mechanical attachment or a chemical attachment.
  • Assembling the second pair of additional pieces fixing the horizontal walls to the skin by means of a mechanical attachment and fixing the vertical walls to the lugs by means of a chemical attachment or by means of installing the bushings which must be incorporated in the boreholes of both elements.

A simple assembly process for this type of fitting is thus achieved.

Other features and advantages of the present invention will become apparent from the following detailed description of illustrative embodiments of its object in relation to the attached drawings.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a fitting for fixing a vertical tail stabilizer fixed on an aircraft rear fuselage, according to the known art.

FIG. 2 is a perspective view of the fitting of FIG. 1.

FIGS. 3 a and 3b are, respectively, cross sections of FIG. 1 according to axes A-A and B-B.

FIGS. 4 a and 4b are perspective views of a fitting for fixing a vertical tail stabilizer with a vertical load according to the present invention.

FIG. 5 is a cross-section view of the fitting of FIGS. 4a and 4b.

FIGS. 6 a and 6b are perspective views of a fitting for fixing a vertical tail stabilizer with an inclined load according to the present invention.

FIG. 7 is a cross-section view of the fitting of FIGS. 6a and 6b.

DETAILED DESCRIPTION OF THE INVENTION

In order to better understand the invention, we will first describe a fitting for fixing a vertical tail stabilizer known in the art in relation to FIGS. 1-3.

It relates to a fitting 11 of a piece comprising lugs 15, 15′ to receive the load element of the vertical stabilizer, a pair of horizontal walls 21, 21′ which are fixed to the skin 5 and a pair of vertical walls 27, 27′ (continuous or segmented in two parts as shown in FIG. 2, depending on the location of the fitting) which are fixed to the frames 7 of the fuselage. FIGS. 3a and 3b show the corresponding attachments in detail.

As a person skilled in the art will understand, the terms “horizontal” and “vertical” must not be interpreted in a strict geometric sense, but rather as terms to merely identify the mentioned components of the fitting. In addition, the shape of the central body 13 of the fitting 11 can differ from some fittings to others depending on their location.

As previously indicated, the basic problems brought forth with metallic fittings having the shape of fitting 11, apart from their weight, are determined by their assembly conditions. Since it is a unitary machined piece, the adjustment for the assembly must be done in contact with the skin 5 and the boreholes 19, 19′ of the lugs 15, 15′ must be re-worked in situ in order to assure that their axis is located in the correct position, which requires an in situ installation of the bushings that must be assembled therein in order to adjust to the attachment bolt for fixing the element of the vertical tail stabilizer with the lugs 15, 15′ between which it is introduced.

These same types of problems will occur in the case of a fitting of composite material having a similar shape and, in addition, the problem relating to the difficulty of optimizing its laminates, since the conditioning factors of the load distribution would require high thickness in some components, particularly in the lugs 15, 15′, as suggested in the graphic depiction of FIG. 2.

In relation to the state of the art, the basic idea of the present invention is to configure the fitting in two or more parts which facilitate both the optimization of the laminates of its different components, together with its assembly.

In a preferred embodiment of the invention for fittings for fixing vertical tail stabilizers with a vertical load, the fitting 41, illustrated in FIGS. 4-5, comprises three pieces, all of which are manufactured in a composite material:

• • A first piece 43 comprises lugs 45, 45′ for fixing the vertical tail stabilizer and vertical walls 47, 47′ for the fixing to the fuselage frames. The unitary-piece configuration of this piece 43 facilitates its assembly.
  • A pair of pieces 49, 49′ (colored in black in FIG. 4a) having an angular shape, and having horizontal walls 51, 51′ for fixing the fitting 41 to the skin 5 of the fuselage, also having vertical walls 53, 53′ intended to be fixed to the central body 44 of the first piece 43.

Piece 43 is fixed on the inner part of the skin 5 of the fuselage (requiring a smaller cavity), having a configuration allowing it to be easily placed in its correct position whereby the boreholes 48, 48′ of the lugs 45, 45′ can incorporate the aforementioned bushings 50, 50′, preventing having to assembly them in situ.

Next, the pieces 49, 49′ are fixed to the central body 44 of the piece 43 in the final assembly line, whereby their correct positioning is assured, preferably by mechanical means and particularly by means of rivets, although in the case of the vertical walls 53, 53′ they can also be attached by chemical means and particularly by means of adhesives. The possible gap between the horizontal walls 51, 51′ and the skin 5 of the fuselage can be covered with a suitable filling layer.

This partition of the fitting 41 into pieces 43, 49, 49′ allows optimizing its corresponding laminates depending on the loads each of them has to support. Piece 43 needs a high percentage of plies in the same direction as the leading load whereas pieces 49, 49′ need a stacking that is more oriented towards passing the shear loads to the skin 5 of the fuselage.

In another preferred embodiment for fittings for fixing vertical tail stabilizers with an inclined load, the fitting 71, illustrated in FIGS. 6-7, comprises five pieces, all of which are manufactured with composite material:

• • A first piece 73 comprises the lugs 75, 75′ for fixing the vertical tail stabilizer and vertical walls 77, 77′ for the attachment to the fuselage frames.
  • A pair of pieces 79, 79′ (colored in black in FIG. 6a) having an angular shape, having horizontal walls 81, 81′ for fixing the fitting to the skin of the fuselage, being their vertical walls 83, 83′ intended for being attached to the central body 74 of the first piece 73.
  • A second pair of additional pieces 90, 90′ (colored in black in FIG. 6a) having an angular shape, designed so that in the operation for fixing the fitting, their horizontal walls 91, 91′ are fixed to the skin by their upper face, being their vertical walls 93, 93′ fixed to the lugs 75, 75′ of the first piece 73.

The first piece 73 of the fitting 71 is fixed on the inner part of the skin 5 of the fuselage like in the previous case and, in a similar way, can be easily placed in its correct position whereby the boreholes 78, 78′ of the lugs 75, 75′ are located in their final position, without the need of being reworked.

The pieces 79, 79′ are fixed, like in the previous case, to the central body 74 of the piece 73 in the final assembly line, whereby their correct positioning is assured, preferably by mechanical means and particularly by means of rivets, although in the case of the vertical walls 83, 83′ they can also be attached by chemical means and particularly by means of adhesives. The possible gap between the horizontal walls 81, 81′ and the skin 5 of the fuselage can be covered with a suitable filling layer.

For their part, pieces 90, 90′ are fixed on the outer part of the skin 5 in the final assembly line, whereby their correct positioning is assured. Their vertical walls 93, 93′ are fixed to the lugs 75, 75′ by means of adhesives or simply by means of the bushings 80, 80′ which are introduced in the boreholes 78, 78′ of both pieces, being their horizontal walls 91, 91′ fixed to the skin 5 by means of rivets. The possible gap between the horizontal walls 91, 91′ and the skin 5 of the fuselage can be covered with a suitable filling layer.

This partition of the fitting 71 into pieces 73, 79, 79′, 90, 90′ allows optimizing its corresponding laminates depending on the loads each of them has to support.

The complementary function provided by the vertical walls 93, 93′ of pieces 90, 90′ for the lugs 75, 75 for withstanding the inclined load of the stabilizer can be observed in this sense. In fact, and as it is shown in FIGS. 6a and 6b, the surface of these vertical walls 93, 93′ is larger than that of the lugs 75, 75′.

It must be taken into account to that respect that when the load acting on the fitting 71 does not vertically comes into contact with the lugs 75, 75′, the direction of the load does not coincide with the direction of 0° of its laminates, which is the main one, which would force, when using the conventional configuration, to a very high thickness of the lugs 75, 75′, causing the length of the bushings 80, 80′ to possibly be greater than the distance between said lugs 75, 75′.

The modifications comprised within the scope defined by the following claims can be introduced in the embodiments described above.

Claims

1. A fitting (41, 71) for fixing the vertical tail stabilizer of an aircraft in an area of its structured rear fuselage based on a skin (5) manufactured with a composite material as a unitary piece and frames (7) manufactured with a composite material, characterized in that it comprises: a) a first piece (43, 73) manufactured with a composite material comprising lugs (45, 45′; 75, 75′) for fixing the vertical tail stabilizer and vertical walls (47, 47′; 77, 77′) for fixing the fitting (41, 71) to the fuselage frames (7);b) at least one pair of additional pieces (49, 49; 79, 79′) manufactured with a composite material comprising horizontal walls (51, 51′; 81, 81′) for fixing the fitting (41, 71) to the skin (5) of the fuselage.

2. The fitting (41) according to claim 1 for fixing the vertical tail stabilizer with a vertical load, characterized in that said pair of additional pieces (49, 49′) have an angular shape and are designed so that, in the operation for fixing the fitting (41), their horizontal walls (51, 51′) are fixed to the coating (5) by their inner face, and so that their vertical walls (53, 53′) are fixed to the first piece (43).

3. The fitting (71) according to claim 1 for fixing the vertical tail stabilizer with an inclined load, characterized in that these pair of additional pieces (79, 79′) have an angular shape and are designed so that in the operation for fixing the fitting (71), their horizontal walls (81, 81′) are fixed to the skin (5) by their inner face, being their vertical walls (83, 83′) fixed to the first piece (73), and also in that it comprises a second pair of additional pieces (90, 90′) having an angular shape which are designed so that, in the operation for fixing the fitting (71), their horizontal walls (91, 91′) are fixed to the skin by their upper face, being their vertical walls (93, 93′) fixed to the lugs (75, 75′) of the first piece (73).

4. The fitting (71) according to claim 3, characterized in that the surface of the vertical walls (93, 93′) of the second pair of additional pieces (90, 90′) is larger than the surface of the lugs (75, 75′).

5. A process for assembling the fitting (41) object of claim 2, characterized in that it comprises the following steps: a) assembling the first piece (43) with the bushings (50, 50′) incorporated in the boreholes (48, 48′) of the lugs (45, 45′) on the inner part of the skin (5);b) assembling the pair of additional pieces (49, 49′) fixing the horizontal walls (51, 51′) to the skin (5) by means of a mechanical attachment and fixing the vertical walls (53, 53′) to the first piece (43) by means of a mechanical attachment or a chemical attachment.

6. A process for assembling the fitting (41) object of claims 3-4, characterized in that it comprises the following steps: a) assembling the first piece (73) on the inner part of the skin (5);b) assembling the pair of additional pieces (79, 79′) attaching the horizontal walls (81, 81′) to the skin (5) by means of a mechanical attachment and fixing the vertical walls (83, 83′) to the first piece (73) by means of a mechanical attachment or a chemical attachment;c) assembling the second pair of additional pieces (90, 90′) fixing the horizontal walls (91, 91′) to the skin (5) by means of a mechanical attachment and fixing the vertical walls (93, 93′) to the lugs (75, 75′) by means of the first piece (73), by means of a chemical attachment or by means of installing the bushings (80, 80′) through the boreholes (78, 78′) of both elements.