This invention refers to a new design of aircraft frames in a composite material, specifically for fuselages integrated into a single piece, as well as to a method for obtaining them.
The fuselage is the main assembly of an aircraft, given that the remaining elements that make up the aircraft are directly or indirectly joined to it. The skin of the fuselage is what gives it its shape, which varies with the main mission that the aircraft will have.
In addition to the skin (the one being considered is CFRP—Carbon Fiber Reinforced Plastic), the fuselage of an aircraft comprises some elements in the shape of a perpendicular framework with respect to the lengthwise axis of the aircraft, called frames (made of CFRP or metal, in the shape of a C, Z, etc.), which are responsible for giving shape and rigidity to the fuselage structure, with these frames being located at given intervals on the inside of the aircraft fuselage. In addition to the frames, the fuselage comprises other reinforcement elements, such as the stringers (generally in an omega shape, T or similar) to achieve optimization of load distribution and rigidity. The stringers are located lengthwise on the fuselage skin, allowing the optimization of the same, thus lightening the weight of the combined structure. In this manner, the entire grid of frames, stringers and skin are joined together to form a complete structure.
Traditionally, the fuselage of an aircraft was built-up in a segmented way, so that the skin was formed by several panels and sections which were later joined to form a typical fuselage in a cylindrical shape. The joints between these segments or panels were embodied through a series of joining parts designed for this purpose, which generally were joined with fasteners. The frames in the case of these fuselages were adjusted manually on the previous structure. This procedure of arrangement and placing the frames is an easy assembly, since the parts that make up the fuselage skin are opened on the inside in such a manner that it allows a simple and correct adjustment of the frames by segments. However, this procedure forces a very high number of segments or partitions of the frames, which involves also having to use a large number of joining parts between the frames and the skin that make up the fuselage. This causes the procedure of assembling the frames to be very long and expensive, using a large amount of assembly labor.
Today, it is becoming increasingly common in the manufacturing of the skin that makes up the fuselage of an aircraft to be obtained in one whole piece, called 360°, full-barrel or one-shot fuselage. The skin that forms the fuselage is formed integrally into a single closed piece from a single mould. With these integral skins, the segmenting of frames has to be approached differently from the segmenting used until now, as it is necessary to pay attention to the different tolerances that are involved in the manufacturing and assembly processes and also to access limitations for the arrangement of these segmented frames.
The present invention offers a solution to the aforementioned limitations.
Thus, according to a first aspect, the invention refers to a new design of an aircraft frame or frames made of composite material, those frames being made in partitions or segments with a determined length, which will be arranged on the interior of the skin that forms the aircraft fuselage. The fuselage will be integrally manufactured in a single piece (called full-barrel or one-shot fuselage). This fuselage may comprise integrated stringers from the same manufacturing process of the aforementioned fuselage. The length of the partitions or segments of the frames will be the maximum possible (which will lead to the minimum number of partitions per diameter of fuselage section), so that the maximum gap between these frame segments and the skin, with this gap being measured from the interior of the skin, allows the use of a liquid sealant for joining the frame segment to the skin. The use of this type of sealant simplifies the operations and decreases the assembly times, which allows recurring costs to decrease in this regard. The maximum length of the frame segments will be calculated based upon the manufacturing limitations given by the manufacturing tolerances of the skin and of the same frame segments.
Furthermore, in the design of the partitions or segments of these frames, the following considerations must be taken into account:
According to a second aspect, the invention refers to a method for obtaining the design of an aircraft frame or frames, which are made of composite material, and comprising partitions or segments of a given length, in such a manner that the calculated frame segments maintain a maximum separation with respect to the interior of the skin, which is such that the method will allow the use of a liquid sealant for joining the frame segment to the skin that forms the fuselage.
Thus, the method of the invention comprises the following stages:
Other characteristics and advantages of this invention will come from the detailed description that follows of an embodiment illustrating its purpose in relation to the attached figures.
Accordingly, the invention refers to a new design of an aircraft frame or frames made of composite material, which are being made in partitions or segments 1 with a determined length 2, which will be arranged on the interior of the skin 3 that forms the aircraft fuselage. The fuselage will be manufactured in a single piece (called full-barrel or one-shot fuselage), so that the length 2 of the partitions or segments 1 of the aforementioned frames will be the maximum possible (which will lead to the minimum number of partitions 1 per diameter of fuselage section), so that the maximum gap 5 between each frame section 1 and the skin 3, with this distance or gap 5 being measured by the interior of the fuselage, is lower than the permitted limit for the application of a liquid sealant. This maximum gap 5 will be calculated based upon the manufacturing limitations given by the manufacturing tolerances of skin 3 and of the frames. Typically, the value of the maximum gap 5 for the application of a liquid sealant is around 0.5 mm. Another type of sealant must be applied when above this separation value 5 (typically solid sealant), which increases the assembly time and decreases the mechanical properties of the assembly.
Furthermore, the design of the partitions 20 in segments 1 of the aforementioned frames, as per the invention, is also determined on the basis of:
In this manner, and based upon the foregoing, the length 2 of the frame section 1 will be such that the lowest possible number of sections 1 or partitions 20 will be obtained, i.e. the length 2 will be the highest possible. In this manner savings are achieved in the number of joining parts and elements used in the traditional designs, as well as in assembly time, by avoiding the use of sealants in a solid state, which leads to savings in assembly time and labor, thus avoiding problems in the riveting operation, without this involving a loss of mechanical characteristics of the joint.
Taking into consideration the manufacturing tolerances of skin 3 (aerodynamic tolerance that causes skin 3 to have an effective external value 11 and thickness tolerance of the skin 3 that causes the skin 3 to have an effective internal value 12) and of frame section 1 (manufacturing tolerance of frame section 1, which causes the aforementioned frame to have an effective external value 13), as well as the limitations imposed by the maximum admissible gap 5 in assembly under which it is possible to apply liquid sealant, the number and optimal position of frame sections 1 of the invention are defined, i.e. the number of partitions 20 of which the complete frame of the invention is composed.
Two extreme cases are considered for the calculation of the maximum length 2 of the partitions or segments 1 of the aforementioned frames, which will determine the number of partitions 20 of which the frame is composed in its entirety, based upon the calculation of the maximum gap 5. This is embodied by taking into consideration the manufacturing limitations given by the manufacturing tolerances of skin 3 (aerodynamic tolerance that causes skin 3 to have an effective external value 11 and thickness tolerance of the skin 3 that causes the skin 3 to have an effective internal value 12) and of frame section 1 (manufacturing tolerance of frame section 1, which causes the aforementioned frame to have an effective external value 13).
Case 1 (
Case 2 (
Therefore, based upon cases 1 and 2 mentioned above, the maximum gap 5 is systematically obtained for each possible frame section 1, as per the invention. Once the areas are known in which the gap between skin 3 and the frame segments 1 is the maximum and lower than the application limit of the defined liquid sealant, and in accordance with the remaining stated considerations, the frame partitions 20 are defined between two consecutive stringers 4, independently of the fact that the stringers 4 are already integrated from the same manufacturing process of the aforementioned fuselage, or manufactured independently and then arranged on the aircraft fuselage, generally through rivets.
According to a second aspect, the invention develops a method for obtaining this aircraft frame or frame made of composite material, with those frames being embodied in partitions or segments 1 of a given length 2, which will be arranged on the inside of skin 3 that forms the aircraft fuselage. The method of the invention comprises the following stages:
For the best and fastest attainment of the method described above, it is desirable to prepare tabulations to which one may turn for carrying out the stages d), e), i), j) and k) above. It is also possible to carry out stages d), e), i), j) and k) above through any computer calculation program.
The aircraft fuselage, and therefore the skin that forms the same can have a cylindrical section, or a conical section. In addition, the fuselage can have certain section changes throughout its length, according to the lengthwise axis of the aircraft. In any of these cases, the method of the invention and the design of the frames obtained by the method of the invention, are perfectly valid.
In the case where the fuselage, and therefore the skin 3 is cylindrical, in the above stage c), the points on which it occurs that the maximum gap 5 between the skin 3 and frame segment 1 is such that it allows the use of a liquid type sealant, are found on ends 6 of the calculated frame segment 1. For the case of stage h) above, the point on which the maximum gap 5 between the skin 3 and the frame section 1 appears is found in an area 7 close to the center of the frame section 1.
In the preferred embodiments that we have just described, those modifications can be introduced that are included within the scope defined by the following claims.
Number | Date | Country | Kind |
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200930757 | Sep 2009 | ES | national |