Central airfoil box comprising a connecting rod and an adjustable anchoring system

Abstract

A central airfoil box comprising two beams, each beam having a wall pierced with a first bore centered on a first axis, a connecting rod comprising, for each wall, a yoke joint having two flanks arranged on either side of the wall and pierced with a bore. Each yoke joint is fixed to the wall by a fixing system. The fixing system comprises a bearing lodging in the first bore, and being pierced with a second bore centered on a second axis parallel and offset to the first axis, a cylindrical shoulder, secured to and coaxial with the bearing and bearing against the wall, an outer perimeter of the shoulder having a plurality of splines, at least one block fixed to the wall around the first bore and configured to lodge in one of the splines, and a shaft lodging in the second bore and the yoke joint bores.

Claims

1. A central airfoil box comprising: two beams, each beam having a wall pierced with a first bore centered on a first axis, a connecting rod comprising, for each wall, a yoke joint having two flanks arranged on either side of the wall and pierced with a bore, and in which each yoke joint is fixed to the wall by a fixing system, at least one of the fixing systems comprising an anchoring system which comprises: a bearing lodging in the first bore, and being pierced with a second bore centered on a second axis parallel to said first axis and offset relative to said first axis, a cylindrical shoulder, secured to and coaxial with the bearing and configured to come to bear against the wall, an outer perimeter of the shoulder having a plurality of splines, at least one block fixed to the wall around the first bore and configured to lodge in one of the splines, and a shaft lodging in the second bore and the bores of the yoke joint.

2. The central airfoil box according to claim 1, wherein each spline is formed as an outwardly open half-cylinder whose axis is parallel to the first axis and wherein each block is formed as a cylinder whose diameter is equal to the diameter of the splines and whose axis is parallel to the first axis.

3. An aircraft comprising a central airfoil box according to claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The features of the invention mentioned above, and others, will emerge more clearly on reading the following description of an exemplary embodiment, the description being given in relation to the attached drawings, in which:

(2) FIG. 1 is a side view of an aircraft according to the invention,

(3) FIG. 2 is a cross-sectional view of a central airfoil box according to the invention,

(4) FIG. 3 is a perspective and exploded view of a connecting rod with an anchoring system according to the invention,

(5) FIG. 4 is a profile view of the connecting rod of FIG. 3 in an assembly phase, and

(6) FIG. 5 is a profile view of the connecting rod of FIG. 4 assembled.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(7) FIG. 1 shows an aircraft 100 which has a fuselage 102 and wings 104. The aircraft 100 also has a central airfoil box 106 which joins the two wings 104 with the fuselage 102.

(8) FIG. 2 shows a simplified example of the box 106 in cross section. The box 106 is composed here of four beams 202a-d, two of which are linked by a connecting rod 204. To this end, each beam 202a-b has a wall 206a-b pierced with a first bore and, for each wall 206a-b, the connecting rod 204 has a yoke joint 208a-b which has two flanks arranged on either side of the wall 206a-b and pierced with a bore 366, and in which each yoke joint 208a-b is fixed to the wall 206a-b by a fixing system.

(9) FIG. 3 shows the box 106 at the level of the wall 206b. The first bores 302 are centered on a first axis 304.

(10) In the embodiment of FIG. 3, the fixing system at the wall 206b comprises an anchoring system 300 described below.

(11) The fixing system at the wall 206a can also comprise an anchoring system 300, but it can take the conventional form of a shaft 210a which is fitted into the yoke joint 208a and the bore 302 of the wall 206a.

(12) Hereinafter in the description, the invention is described more particularly relative to one of the ends of the connecting rods 204 but it can be implemented also at the other end.

(13) The anchoring system 300 comprises a bearing 350 which lodges in the first bore 302 and which is pierced with a second bore 352 centered on a second axis 354 and in which a shaft 210b is fitted.

(14) The second axis 354 is parallel to the first axis 304 and offset relative to the latter. Thus, the rotation of the bearing 350 in the first bore 302 about the first axis 304 makes it possible to displace the second bore 352 and therefore the shaft 210b which is fitted into it.

(15) In order to block the bearing 350 in the chosen position, the anchoring system 300 comprises blocking means 356 which are designed to block the rotation of the bearing 350 in the first bore 302.

(16) The anchoring system 300 comprises a cylindrical shoulder 353, secured to and coaxial with the bearing 350. The shoulder 353 is designed to come to bear against the wall 206b and the blocking means 356 are composed of a plurality of splines 358 which are produced on the outer perimeter of the shoulder 353 and at least one block 360 fixed to the wall 206b around the first bore 302 and designed to lodge in one of the splines 358.

(17) The fact that the blocking means 356 are on the shoulder makes it possible to move their position away from the load transfer paths. Furthermore, the fact of distancing the splines 358 and the blocks 360 from the first axis 304 makes it possible to have a better adjustment accuracy because the angle between two successive splines 358 is smaller.

(18) The anchoring system 300 also comprises the shaft 210b which lodges in the second bore 352 and the bores 366 of the yoke joint 208b.

(19) Such an anchoring system 300 thus allows for an adjustment of the position of the shaft 210b relative to the first bore 302, and, in the case of the central airfoil box 106, it is then no longer necessary to have the connecting rods 204 custom-made whether for the first manufacture or upon the replacement of a connecting rod 204, which allows for a faster mounting. In effect, it is sufficient to pivot the bearing 350 into the appropriate position to obtain the desired center distance.

(20) Each spline 358 takes the form of an outwardly open half-cylinder whose axis is parallel to the first axis 304. Each block 360 takes the form of a cylinder whose diameter is equal to the diameter of the splines 358 and whose axis is parallel to the first axis 304.

(21) The centers of the splines 358 are distributed over a circle coaxial with the first axis 304 and the center of each block 360 is arranged on this same circle. When there are several blocks 360, they exhibit an angular distribution compatible with the angle that exists between two successive splines 358, that is to say, the angle between two blocks 360 is equal, to within a multiplying coefficient, to the angle between two successive splines 358. Thus, each block 360 can be positioned in one of the splines 358.

(22) The range of adjustment of the center distance increases with the offset of the second bore 352.

(23) FIG. 4 shows a step in the mounting of the anchoring system 300.

(24) The bearing 350 is partially driven into the first bore 302 leaving the shoulder 353 at a distance from the blocks 360 to allow the rotation of the bearing 350.

(25) The shaft 210b is fitted into a bore 366 of the yoke joint 208b.

(26) The bearing 350 is turned about the first axis 304 so as to bring the second bore 352 into line with the shaft 210b.

(27) When the desired position is reached, the bearing 350 is driven home into the first bore 302 so that the blocks 360 are positioned in the splines 358 in order to block the rotation.

(28) FIG. 5 shows the final assembly position.

(29) The bearing 350 is driven into the first bore 302 and the blocks cooperate with the splines 358.

(30) To prevent the displacement of the bearing 350, a washer 370 is arranged between the shoulder 353 and the facing wall of the yoke joint 208b.

(31) The shaft 210b is driven in to pass through the bores 366 of the yoke joint 208b, the second bore 352 of the bearing 350 and the washer 370.

(32) The shaft 210b is stopped in translation by any appropriate means such as, for example, nuts which are screwed onto the shaft 210b. The diameter of the bores 366 of the yoke joint 208b and the diameter of the second bore 352 are equal to the diameter of the shaft 210b to within the mounting tolerance.

(33) The diameter of the second bore 302 is equal to the diameter of the bearing 350 to within the mounting tolerance.

(34) While at least one exemplary embodiment of the present invention(s) is disclosed herein, it should be understood that modifications, substitutions and alternatives may be apparent to one of ordinary skill in the art and can be made without departing from the scope of this disclosure. This disclosure is intended to cover any adaptations or variations of the exemplary embodiment(s). In addition, in this disclosure, the terms “comprise” or “comprising” do not exclude other elements or steps, the terms “a” or “one” do not exclude a plural number, and the term “or” means either or both. Furthermore, characteristics or steps which have been described may also be used in combination with other characteristics or steps and in any order unless the disclosure or context suggests otherwise. This disclosure hereby incorporates by reference the complete disclosure of any patent or application from which it claims benefit or priority.