METHODS OF MAKING AND STRUCTURES CONTAINING STIFFENERS HAVING TRANSITION PORTIONS
A stiffener 100 comprises a first stiffener portion (102), having a first cross-sectional profile (104) that is constant along the first stiffener portion (102). The stiffener 100 also comprises a second stiffener portion (106), having a second cross-sectional profile (108) that is constant along the second stiffener portion (106). The second cross-sectional profile (108) of the second stiffener portion (106) is different from the first cross-sectional profile (104) of the first stiffener portion (102). The stiffener 100 additionally comprises a transition stiffener portion (110) tapering from the second stiffener portion (106) to the first stiffener portion (102).
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This application is a divisional of U.S. Ser. No. 14/835,829 filed on Aug. 26, 2015.
BACKGROUNDAerodynamic loads experienced by aircraft structures, such as an aircraft wing, include, e.g., bending loads. Tough and lightweight composite materials are increasingly used in the construction of aircraft wings because they are capable of supporting the loads encountered during flight while enabling a decrease in weight of the aircraft. A common type of composite material used in aircraft construction is carbon fiber composite.
Generally, a wingbox structure of the aircraft wing includes a stiffened upper panel (or skin), a stiffened lower panel (or skin), opposed spars that connect to leading and trailing edges of the panels, and internal ribs that provide shape and support to the wingbox structure and connect the panels. It is desirable to decrease the thickness of the wing, particularly an outboard portion of the wing, as much as possible to improve the aerodynamic efficiency of the aircraft (e.g., a thicker wing encounters more drag). However, decreasing wing thickness continues to be a structural challenge because the height of the stiffeners limits how thin the wing can be constructed in view of the fact that the use of stiffeners having a reduced height to decrease wing thickness is limited. Low-profile stiffeners may be used to stiffen the lower panel since the lower panel is primarily in tension during flight. However, low profile-stiffeners are not suitable for the upper panel. High-profile stiffeners (e.g., stiffeners having a taller cross-sectional profile), such as I-shaped or T-shaped stiffeners, are needed to stiffen at least the majority of the upper panel since the upper panel is primary in compression during flight.
SUMMARYAccordingly, apparatuses and methods, intended to address at least the above-identified concerns, would find utility.
The following is a non-exhaustive list of examples, which may or may not be claimed, of the subject matter according the present disclosure.
One example of the present disclosure relates to a stiffener. The stiffener comprises a first stiffener portion having a first cross-sectional profile that is constant along the first stiffener portion. The stiffener also comprises a second stiffener portion having a second cross-sectional profile that is constant along the second stiffener portion. The second cross-sectional profile of the second stiffener portion is different from the first cross-sectional profile of the first stiffener portion. The stiffener further comprises a transition stiffener portion tapering from the second stiffener portion to the first stiffener portion.
Another example of the present disclosure relates to a structure. The structure comprises a skin, comprising surface, and a stiffener, coupled to the surface of the skin. The stiffener comprises a first stiffener portion, having a first cross-sectional profile that is constant along the first stiffener portion. The stiffener also comprises a second stiffener portion, having a second cross-sectional profile that is constant along the second stiffener portion. The second cross-sectional profile of the second stiffener portion is different from the first cross-sectional profile of the first stiffener portion. The stiffener further comprises a transition stiffener portion, tapering from the second stiffener portion to the first stiffener portion.
Yet another example of the present disclosure relates to a method of making a stiffener. The method comprises laying up a base charge to form a part of a first stiffener portion of the stiffener from a first base-charge portion of the base charge, to form a part of a second stiffener portion of the stiffener from a second base-charge portion of the base charge, and to form a part of a transition stiffener portion of the stiffener from a transition base-charge portion of the base charge. The transition base-charge portion tapers from the second base-charge portion to the first base-charge portion. The method also comprises laminating an initial charge onto the base charge to form a part of the first stiffener portion of the stiffener from a first initial-charge portion of the initial charge and to form a part of the transition stiffener portion of the stiffener from a transition initial-charge portion of the initial charge. The first initial-charge portion of the initial charge is shaped identically to the first base-charge portion of the base charge, and the transition initial-charge portion of initial charge is shaped identically to at least a portion of the transition base-charge portion of the base charge. The method further comprises laminating a subsequent charge A onto the initial charge to form a part of the first stiffener portion of the stiffener from a first subsequent-charge-A portion of the subsequent charge A and to form a part of the transition stiffener portion of the stiffener from a transition subsequent-charge-A portion of the subsequent charge A. The first subsequent-charge-A portion of the subsequent charge A is shaped identically to the first initial-charge portion of the initial charge, and the transition subsequent-charge-A portion of the subsequent charge A is smaller than the transition initial-charge portion of the initial charge and is shaped identically to a portion of the transition initial-charge portion.
Having thus described examples of the present disclosure in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein like reference characters designate the same or similar parts throughout the several views, and wherein:
In
In
In the following description, numerous specific details are set forth to provide a thorough understanding of the disclosed concepts, which may be practiced without some or all of these particulars. In other instances, details of known devices and/or processes have been omitted to avoid unnecessarily obscuring the disclosure. While some concepts will be described in conjunction with specific examples, it will be understood that these examples are not intended to be limiting.
Unless otherwise indicated, the terms “first,” “second,” etc. are used herein merely as labels, and are not intended to impose ordinal, positional, or hierarchical requirements on the items to which these terms refer. Moreover, reference to, e.g., a “second” item does not require or preclude the existence of, e.g., a “first” or lower-numbered item, and/or, e.g., a “third” or higher-numbered item.
Reference herein to “one example” means that one or more feature, structure, or characteristic described in connection with the example is included in at least one implementation. The phrase “one example” in various places in the specification may or may not be referring to the same example.
Illustrative, non-exhaustive examples, which may or may not be claimed, of the subject matter according the present disclosure are provided below.
Referring, e.g., to
First stiffener portion 102 and second stiffener portion 106 enable a single continuous stiffener 100 to have different cross-sectional profiles and/or dimensions, which provide different structural characteristics, for example, size, shape and/or load bearing characteristics. Transition stiffener portion 110 effectively transfers a load between first stiffer portion 102 and second stiffener portion 106.
Gradually shifting (e.g., tapering) from first cross-sectional profile 104 of first stiffener portion 102 to second cross-sectional profile 108 of second stiffener portion 106 along transition stiffener portion 110 provides a more effective load transfer as compared to abutting, splicing or otherwise coupling two different stiffeners each having a different cross-sectional profile.
First cross-sectional profile 104 may have any suitable shape depending upon the particular structural application of stiffener 100, for example, when used to construct structure 200 (e.g.,
Similarly, second cross-sectional profile 108 may have any suitable shape (e.g., different than the shape of first cross-sectional profile 104) depending upon the particular structural application of stiffener 100, for example, when used to construct structure 200. As one example, second cross-sectional 108 of second stiffener portion 106 may be designed to react to bending loads, such as wing bending loads experienced during flight. As one example, the bending loads are primarily compression-driven loads.
As will be described in more detail below, as one example, stiffener 100 enables construction of aircraft wing 206 (e.g.,
Referring generally to
A trapezoidally shaped first cross-sectional profile 104 of first stiffener portion 102 of stiffener 100 enables first stiffener portion 102 to suitably react to bending loads primarily due to tension loading, while also providing a relatively short profile height.
When stiffener 100 is used to construct structure 200 (e.g., wing 206) (
When used in the construction of wing 206 of aircraft 208 (e.g.,
Referring generally to
A T-shaped second-cross sectional profile 108 of second stiffener portion 106 of stiffener 100 enables second stiffener portion 106 to suitably react to bending loads primarily due to compression loading, while also providing a relatively tall profile height and/or a high cross-sectional moment of inertia.
As used herein, the term “T-shaped” refers to a shaped member having a first (e.g., substantially vertical) portion and a second (e.g., substantially horizontal) portion substantially perpendicularly coupled to an end of the first portion. The second portion extends laterally outward in opposite directions, for example, equidistantly, from the end of the first portion.
When used in the construction of wing 206 of aircraft 208 (e.g.,
Referring generally to
An I-shaped second cross-sectional profile 108 of second stiffener portion 106 of stiffener 100 enables second stiffener portion 106 to suitably react to bending loads primarily due to compression loading, while also providing a relatively tall profile height and/or a high cross-section moment of inertia.
As used herein, the term “I-shaped” refers to a shaped member having a first (e.g., substantially vertical) portion, a second (e.g., substantially horizontal) portion substantially perpendicularly coupled to a first end of the first portion, and a third (e.g., substantially horizontal) portion substantially perpendicularly coupled to a second end (opposite the first end) of the first portion. The second portion extends laterally outward in opposite directions, for example, equidistantly, from the first end of the first portion. The third portion extends laterally outward in opposite directions, for example, equidistantly, from the second end of the first portion.
When used in the construction of wing 206 of aircraft 208 (e.g.,
Referring generally to
Transition cross-sectional profiles 112 of transition stiffener portion 110 gradually shifting (e.g., transitioning) from first cross-sectional profile 104 of first stiffener portion 102 to second cross-sectional profile 108 of second stiffener portion 106 to provides effective load transfer between first stiffener portion 102 and second stiffener portion 106 through transition stiffener portion 110.
Each one of transition cross-sectional profiles 112 of transition stiffener portion 110 has a shape representing a transformation between first cross-sectional profile 104 of first stiffener portion 102 and second cross-sectional profile 108 of second stiffener portion 106. Transition cross-sectional profiles 112 proximate (e.g., at or near) first stiffener portion 102 have shapes approximating first cross-sectional profile 104. Similarly, transition cross-sectional profiles 112 proximate (e.g., at or near) second stiffener portion 106 have shapes approximating second cross-sectional profile 108.
As one example, and as best illustrated in
Referring generally to
All of transition cross-sectional profiles 112 of transition stiffener portion 110 being different provide a consistent and continual transition (e.g., ramp rate) between first cross-sectional profile 104 of first stiffener portion 102 and second cross-sectional profile 108 of second stiffener portion 106 (e.g., from second cross-sectional profile 108 of second stiffener portion 106 to first cross-sectional profile 104 of first stiffener portion 102 or from first cross-sectional profile 104 of first stiffener portion 102 to second cross-sectional profile 108 of second stiffener portion 106).
Referring generally to
A smooth transition between first cross-sectional profile 104 and second cross-sectional profile 108 along transition cross-sectional profiles 112 gradually changes the centroid of stiffener 100 and reduces the potential of stiffener 100 pulling off of a panel to which it is coupled.
Abrupt changes to the centroid of stiffener 100 may increase the potential of stiffener 100 pulling away from the panel to which it is coupled. The smooth transition of transition cross-sectional profiles 112 of transition stiffener portion 110 between first cross-sectional profile 104 of first stiffener portion 102 and second cross-sectional profile 108 of second stiffener portion 106 (e.g., from second cross-sectional profile 108 of second stiffener portion 106 to first cross-sectional profile 104 of first stiffener portion 102 or from first cross-sectional profile 104 of first stiffener portion 102 to second cross-sectional profile 108 of second stiffener portion 106) more effectively transfers loads between first stiffener portion 102 and second stiffener portion 106.
Referring generally to
Charges 160 that are stacked and laminated together form an integral, continuous part of stiffener 100 capable of effectively transferring loads between first stiffener portion 102 and second stiffener portion 106 along transition stiffener portion 110.
Charges 160 may be formed from a composite material. For example, the composite material may include reinforcing fibers and resins. As one example, each of charges 160 may be a carbon fiber composite. Types of carbon fiber composites used to form charges 100 include pre-impregnated (“prepreg”) thermoset composite, dry fiber thermoset composite, and thermoplastic composite. The laminated stack of charges 160 may be cured (e.g., co-cured) to form first stiffener portion 102, the part of second stiffener portion 106, and the part of transition stiffener portion 110.
As used herein, the terms laminated, laminating, etc. generally refer to overlaying, stacking, bundling, arranging, placing or otherwise positioning one or more layers relative to one or more additional layers and, optionally, securing those layers together.
As one example, and as best illustrated in
A different number of charges 160 are used to form each of first stiffener portion 102, second stiffener portion 106, and transition stiffener portion 110. As one example, a fewer number of charges 160 are used to form the part of second stiffener portion 106 and a greater number of charges 160 are used to form first stiffener portion 102. The number of charges 160 used to from the part of transition stiffener portion 110 increases from the fewer number (e.g., of the second stiffener portion 106) to the greater number (e.g., of the first stiffener portion 102).
Any suitable number of charges 160 may be used to form first stiffener portion 102, the part of second stiffener portion 106, and the part of transition stiffener portion 110. As one example, and as best illustrated in
As one specific example, and as best illustrated in
Referring to
Varying and/or alternating the orientation of reinforcing fibers 240 among prepreg composite plies 126, with respect to a longitudinal axis of each one of charges 160, at a plurality of different angles, such as approximate angles of 0-degrees, −45-degrees, 90-degrees, and 45-degrees, produces optimum mechanical properties (e.g., strength and/or stiffness) in charges 160 and stiffener 100 formed from charges 160.
Prepreg composite plies 126 may correspond to an uncured configuration of plies forming each one of charges 160, which when cured may form first stiffener portion 102, part of second stiffener portion 106, and part of transition stiffener portion 110. For example, prepreg composite plies 126 may correspond to a plurality of generally planar carbon fiber prepreg plies with various angular orientations. Each of prepreg composite plies 126 is stronger along the direction of orientation of reinforcing fibers 240 and weaker in a direction perpendicular to reinforcing fibers 240.
As described above, a stacked and laminated plurality of prepreg composite plies 126 forms each one of charges 160 and a stacked and laminated plurality of charges 160 form a part of stiffener 110 (e.g., first stiffener portion 102, the part of second stiffener portion 106, and the part of transition stiffener portion 110). As one example, each one of charges 160 may include twenty-two (22) prepreg composite plies 126. Prepreg composite plies 126 may have various angular orientations of reinforcing fibers 240.
Listed below in Table 1 is one example of a configuration of prepreg composite plies 126 (identified as P1 through P22) used to form a first group of charges 160 used to form the part of stiffener 100 and Table 2 is one example of a configuration of prepreg composite plies (identified as P1 through P22) used to form a second group of charges 160 used to form the part of stiffener 100.
As one example, seven charges 160 may be used to form the part of stiffener 100. Table 1 illustrates the orientation of reinforcing fibers 240 of prepreg composite plies 126 used for a first (e.g., lowermost) one of charges 160, a third one of charges 160, a fifth one of charges 160, and a seventh (e.g., uppermost) one of charges 160. Table 2 illustrates the orientation of reinforcing fibers 240 of prepreg composite plies 126 used for a second one of charges 160, a fourth one of charges 160, and a sixth one of charges 160. As illustrated, the orientation of reinforcing fibers 240 of prepreg composite plies 126 may alternate between each one of charges 160.
It should be understood that ply counts and orientations in Table 1 and Table 2 are merely exemplary and that other configurations, numbers of prepreg composite plies, and/or other orientations are contemplated. As one example, more or less than twenty-two prepreg composite plies 126 may be used. As one example, the orientations of the reinforcing fibers 240 of prepreg composite plies 126 may vary.
It should also be understood that the number of charges 160 are merely exemplary and that other numbers of charges are also contemplated. As one example, more or less than seven charges 160 may be used to form the part of stiffener 100.
Referring generally to
Base 122 and rib 168 of web 120 enables second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads due to compression and provides the majority of the height and a part of the shape of second cross-sectional profile 108 of second stiffener portion 106 and transition cross-sectional profiles 112 of transition stiffener portion.
Base 122 of web 120 is stacked on and is cured (e.g., co-cured) or bonded (e.g., co-bonded or secondarily bonded) to charges 160 forming the part of second stiffener portion 106 and to charges 160 forming the part of transition stiffener portion 110.
A portion of base 122 and rib 168 of web 120 forming the part of second stiffener portion 106 may have a constant cross-sectional dimension along second stiffener portion 106. A portion of base 122 and rib 168 forming the part of transition stiffener portion 110 may have a gradually decreasing cross-sectional dimension along transition stiffener portion 110 from second stiffener portion 106 to first stiffener portion 102.
Web 120 may be formed from a composite material. For example, the composite material may include reinforcing fibers and resins. As one example, web 120 (e.g., base 122 and rib 168) may be a carbon fiber composite. Types of carbon fiber composites used to form web 120 include pre-impregnated (“prepreg”) thermoset composite, dry fiber thermoset composite, and thermoplastic composite.
Referring generally to
Web 120 being tapered from second stiffener portion 106 to first stiffener portion 102 gradually reduces the height of transition cross-sectional profiles 112 from second stiffener portion 106 to first stiffener portion 102 and effectively transfers loads between first stiffener portion 102 and second stiffener portion 106 along transition stiffener portion 110.
Referring generally to
Gradually decreasing width W1 of each one of charges 160 and gradually increasing combined height H1 of the stack of charges 160 along transition stiffener portion 110 provides for the smooth transition of transition cross-sectional profiles 112 from second cross-sectional profile 108 to first cross-sectional profile 104 and enables effective load transfer between second stiffener portion 106 and first stiffener portion 102 along transition stiffener portion 110.
Width W1 illustrated in
For example, a width of a portion of each one of charges 160 forming the part of second stiffener portion 106 is greater than a width of a portion of each one of charges 160 forming first stiffener portion 102 and a width of a portion of each one of charges 160 forming the part of transition stiffener portion 110 gradually decreases from the width of the portion of each one of charges 160 forming the part of second stiffener portion 106 to the width of the portion of each one of charges 160 forming first stiffener portion 102. As one example, and as illustrated in
Referring generally to
Progressively (e.g., gradually) decreasing width W2 of base 122 of web 120 and progressively (e.g., gradually) decreasing height H2 of rib 168 of web 120 provides for the smooth transition of transition cross-sectional profiles 112 from second cross-sectional profile 108 to first cross-sectional profile 104 and enables effective load transfer between second stiffener portion 106 and first stiffener portion 102 along transition stiffener portion 110.
Referring generally to
A laminated stack of base charge 124, initial charge 148 and subsequent charge A form an integral, continuous part of stiffener 100 capable of effectively reacting to loads (e.g., different bending loads) and transferring loads between first stiffener portion 102 and second stiffener portion 106 along transition stiffener portion 110.
Base charge 124, initial charge 148 and subsequent charge A being sequentially stacked and laminated define combined height H1 (
In the examples illustrated in
Transition base-charge portion 146 of base charge 124 tapering from second base-charge portion 144 to first base-charge portion 146, transition initial-charge portion 152 of initial charge 148 tapering to first initial-charge portion 150, transition subsequent-charge-A portion of subsequent charge A tapering to first subsequent-charge-A portion gradually reduces the width of the part of stiffener 100 (e.g., the width of the laminated stack of charges 160) from second stiffener portion 106 to first stiffener portion 102 along transition stiffener portion 110 and provides for the smooth transition from second stiffener portion 106 to first stiffener portion 102 along transition stiffener portion 110.
Transition initial-charge portion 152 of initial charge 148 being smaller than transition base-charge portion 146 of base charge 124 and transition subsequent-charge-A portion of subsequent charge A being smaller than transition initial-charge portion 152 of initial charge 148 gradually reduces the width of the part of stiffener 100 (e.g., the width of the laminated stack of charges 160) from base charge 124 to subsequent charge A.
Transition initial-charge portion 152 of initial charge 148 being shaped identically to at least a portion of transition base-charge portion 146 of base charge 124 and first subsequent-charge-A portion of subsequent charge A being shaped identically to first initial-charge portion 150 of initial charge 148 and transition subsequent-charge-A portion of subsequent charge A being smaller than transition initial-charge portion 152 of initial charge 148 and being shaped identically to a portion of transition initial-charge portion 152 gradually increases the combined height of the part of stiffener 100 (e.g., the combined height of the laminated stack of charges 160) from second stiffener portion 106 to first stiffener portion 102 along transition stiffener portion 110.
As one example, and as best illustrated in
As illustrated in
As illustrated in
As described above, base charge 124, initial charge 148, and subsequent charge A each have a trapezoidal cross-sectional shape. The stack of transition base-charge portion 146 of base charge 124, transition initial-charge portion 152 of initial charge 148, and transition subsequent-charge-A portion of subsequent charge A has a trapezoidal cross-sectional shape. The stack of first base-charge portion 142 of base charge 124, first initial-charge portion 150 of initial charge 148, and first subsequent-charge-A portion of subsequent charge A has a trapezoidal cross-sectional shape.
Referring generally to
Web 120 enables second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads primarily due to compression and provides the majority of the height of second cross-sectional profile 108 of second stiffener portion 106 and transition cross-sectional profiles 112 of transition stiffener portion.
As one example, web 120 is stacked on and is cured (e.g., co-cured) or bonded (e.g., co-bonded or secondarily bonded) to second base-charge portion 144 of base charge 124 and, optionally, a portion of transition initial-charge portion 150 of initial charge 148 to form the part of second stiffener portion 106 and to a portion of transition initial-charge portion 150 of initial charge 148 and transition subsequent-charge-A portion of subsequent charge A to form the part of transition stiffener portion 110.
Referring generally to
Covering (e.g., wrapping) base charge 124, initial charge 148 and subsequent charge A with cover layer 176 further integrates base charge 124, initial charge 148 and subsequent charge A (e.g., charges 160) into a continuous part of stiffener 100 capable of reacting to bending loads and transferring loads between first stiffener portion 102 and second stiffener portion 106.
Cover layer 176 may be formed from a composite material. For example, the composite material may include reinforcing fibers and resins. As one example, cover layer 176 may be a carbon fiber composite. Cover layer 176 may be flush against exterior surfaces of base charge 124, initial charge 148 and subsequent charge A. Cover layer 176 may be cured (e.g., co-cured) or bonded (e.g., co-bonded) with base charge 124, initial charge 148, subsequent charge A and web 120.
As one example, cover layer 176 may be one ply of carbon fiber-reinforced polymer fabric mesh with fibers oriented in a zero (0) degree direction and a ninety (90) degree direction and woven together to form a continuous ply.
Referring generally to
Web charge 178 and opposing web charge 184 in combination enable second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads primarily due to compression and provides the majority of the height and a part of the shape of second cross-sectional profile 108 of second stiffener portion 106 and transition cross-sectional profiles 112 of transition stiffener portion.
Second web-charge portion 180 of web charge 178 and second opposing-web-charge portion 186 of opposing web charge 184 may be positioned (e.g., stacked) on second base-charge portion 144 of base charge 124. Cross-sectional dimensions of second web-charge portion 180 of web charge 178 and second opposing-web-charge portion 186 of opposing web charge 184 may be constant along second base-charge portion 144 of base charge 124, for example, to form the part of second stiffener portion 106.
Transition web-charge portion 182 of web charge 178 and transition opposing-web-charge portion 188 of opposing web charge 184 may be positioned (e.g., stacked) on transition initial-charge portion 152 of initial charge 148 and transition subsequent-charge-A portion of subsequent charge A. Cross-section dimensions of transition web-charge portion 182 of web charge 178 and transition opposing-web-charge portion 188 of opposing web charge 184 may gradually decrease along transition initial-charge portion 152 of initial charge 148 and transition subsequent-charge-A portion of subsequent charge A, for example, to form the part of transition stiffener portion 110. The gradual reduction in the cross-sectional dimensions of transition web-charge portion 182 of web charge 178 and transition opposing-web-charge portion 188 of opposing web charge 184 may taper web 120 along transition stiffener portion 110.
Web charge 178 and opposing web charge 184 may be formed from a composite material. For example, the composite material may include reinforcing fibers and resins. As one example, web charge 178 and opposing web charge 184 may be a carbon fiber composite. Web charge 178 and opposing web charge 184 of web 120 may be cured (e.g., co-cured) together. Web charge 178 and opposing web charge 184 of web 120 may be cured (e.g., co-cured) or bonded (e.g., co-bonded or secondarily bonded) to charges 160 (e.g., second base-charge portion 144 of base charge 124) to form the part of second stiffener portion 106 and to charges 160 (e.g., transition initial-charge portion 152 of initial charge 148 and transition subsequent-charge-A portion of subsequent charge A) to form the part of transition stiffener portion 110.
Referring generally to
Thickness T of transition web-charge portion 182 of web charge 178 and of transition opposing-web-charge portion 188 of opposing web charge 184 gradually decreasing from second stiffener portion 106 to first stiffener portion 102 gradually reduces transition cross-sectional profiles 112 from second stiffener portion 106 to first stiffener portion 102.
The gradual reduction in thickness T of transition web-charge portion 182 of web charge 178 and of transition opposing-web-charge portion 188 of opposing web charge 184 may be created during the formation process (e.g., lay-up process) web charge 178 and opposing web charge 184.
Referring generally to
Transition web-charge portion 182 of web charge 178 and transition opposing-web-charge portion 188 of opposing web charge 184 being tapered from second stiffener portion 106 to first stiffener portion 102 smoothly blends transition cross-sectional profiles 112 from second stiffener portion 106 to first stiffener portion 102.
The tapering of transition web-charge portion 182 of web charge 178 and transition opposing-web-charge portion 188 of opposing web charge 184 gradually reduces web 120 along transition stiffener portion 110 to a point where web 120 (e.g., web charge 182 and opposing web charge 184) is effectively eliminated proximate (e.g., at or near) a transition between transition stiffener portion 110 and first stiffener portion 102.
Referring generally to
L-shaped web charge 178 and opposing web charge 184 are used to form a part of T-shaped second cross-sectional profile 108 of second stiffener portion 106.
As used herein, the term “L-shaped” refers to a shaped member having a first (e.g., substantially vertical) portion and a second (e.g., substantially horizontal) portion substantially perpendicularly coupled to a first end of the first portion. The second portion extends laterally outward in one direction from the first end of the first portion.
Referring generally to
A U-shaped web charge 178 and opposing web charge 184 are used to form a part of the I-shaped second cross-sectional profile 108 of second stiffener portion 106.
As used herein, the term “U-shaped” refers to a shaped member having a first (e.g., substantially vertical) portion, a second (e.g., substantially horizontal) portion perpendicularly coupled to a first end of the first portion, and a third (e.g., substantially horizontal) portion substantially perpendicularly coupled to a second end (opposite the first end) of the first portion. The second portion extends laterally outward in one direction from the first end of the first portion. The third portion extends laterally outward in the same one direction from the second end of the first portion.
Referring generally to
Cap charge 190 intercouples web charge 178 and opposing web charge 184 and forms a part of the I-shaped second cross-sectional profile 108 of second stiffener portion 106. Cap charge 190 further enables second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads primarily due to compression loading.
As one example, cap charge 190 is stacked on and laminated to the third portions of the U-shaped web charge 178 and opposing web charge 184.
Cap charge 190 may be formed from a composite material. For example, the composite material may include reinforcing fibers and resins. As one example, cap charge 190 may be a carbon fiber composite. Cap charge 190 may be cured (e.g., co-cured) or bonded (e.g., co-bonded or secondarily bonded) to web 120 (e.g., web charge 178 and opposing web charge 184) to form the part of second stiffener portion 106 and the part of transition stiffener portion 110.
Referring generally to
Filler charge 192 enhances the load-carrying capabilities of stiffener 100.
Filler charge 192 fills an open space between web charge 178 and opposing web charge 184. As one example, the open space between web charge 178 and opposing web charge 184 is formed by the radius or angular transition between the first portions and the second portions of the L-shaped or U-shaped web charge 178 and opposing web charge 184. Filler charge 192 may be formed or cut as required to fill the open space (e.g., the radius) between web charge 178 and opposing web charge 184.
A cross-sectional dimension of second filler-charge portion 194 of filler charge 192 may be along second base-charge portion 144 of base charge 124, for example, to form the part of second stiffener portion 106. A cross-sectional dimension of transition filler-charge portion 196 of filler charge 194 may gradually decrease along transition initial-charge portion 152 of initial charge 148 and transition subsequent-charge-A portion of subsequent charge A, for example, to form the part of transition stiffener portion 110.
Filler charge 192 may be formed from a composite material. For example, the composite material may include reinforcing fibers or a woven fabric and resins. As one example, filler charge 192 may be a carbon fiber composite. Filler charge 192 may be cured (e.g., co-cured) or bonded (e.g., co-bonded or secondarily bonded) to web 120 (e.g., web charge 178 and opposing web charge 184), second base-charge portion 144 of base charge 124, and transition initial-charge portion 152 of initial charge 148 and transition subsequent-charge-A portion of subsequent charge A.
Referring to
When used in the construction of wing 206 of aircraft 208 (e.g.,
Referring generally to
Subsequent charge B being stacked and laminated onto subsequent charge A further increases combined height H1 (
As illustrated in
As illustrated in
As described above, transition subsequent-charge-B has a trapezoidal cross-sectional shape. The stack of transition base-charge portion 146 of base charge 124, transition initial-charge portion 152 of initial charge 148, transition subsequent-charge-A portion of subsequent charge A, and transition subsequent-charge-B portion of subsequent charge B has a trapezoidal cross-sectional shape. The stack of first base-charge portion 142 of base charge 124, first initial-charge portion 150 of initial charge 148, first subsequent-charge-A portion of subsequent charge A, and first subsequent-charge-B portion of subsequent charge B has a trapezoidal cross-sectional shape.
Referring generally to
Subsequent charges B through N being sequentially stacked and laminated onto subsequent charge A further increases combined height H1 (
As illustrated in
As illustrated in
As described above, each one of transition subsequent-charge-B-through-N portions of subsequent charges B through N has a trapezoidal cross-sectional shape. The stack of transition base-charge portion 146 of base charge 124, transition initial-charge portion 152 of initial charge 148, transition subsequent-charge-A portion of subsequent charge A, and transition subsequent-charge-B-through-N portions of subsequent charges B through N has a trapezoidal cross-sectional shape. The stack of first base-charge portion 142 of base charge 124, first initial-charge portion 150 of initial charge 148, first subsequent-charge-A portion of subsequent charge A, and first subsequent-charge-B-through-N portions of subsequent charges B through N has a trapezoidal cross-sectional shape.
Referring generally to
Structure 200 having skin 202 stiffened by stiffener 100 provides different structural characteristics, for example, size, shape and/or load bearing characteristics along a length of stiffener 100.
First stiffener portion 102 and second stiffener portion 106 enable a single continuous stiffener 100 having different cross-sectional profiles and/or dimensions to stiffen structure 200, which provide different structural characteristics, for example, size, shape and/or load bearing characteristics.
Transition stiffener portion 110 effectively transfers a load between first stiffer portion 102 and second stiffener portion 106. Gradually shifting (e.g., tapering) from first cross-sectional profile 104 of first stiffener portion 102 to second cross-sectional profile 108 of second stiffener portion 106 along transition stiffener portion 110 provides a more effective load transfer as compared to abutting, splicing or otherwise coupling two different stiffeners each having a different cross-sectional profile.
Referring generally to
A trapezoidally shaped first cross-sectional profile 104 of first stiffener portion 102 of stiffener 100 enables first stiffener portion 102 and, thus, structure 200 to suitably react to bending loads primarily due to tension loading, while also providing a relatively short profile height.
Referring generally to
A T-shaped second-cross sectional profile 108 of second stiffener portion 106 of stiffener 100 enables second stiffener portion 106, and, thus, structure 200 to suitably react to bending loads primarily due to compression loading, while also providing a relatively tall profile height.
Referring generally to
I-shaped second cross-sectional profile 108 of second stiffener portion 106 of stiffener 100 enables second stiffener portion 106 and, thus, structure 200 to suitably react to bending loads primarily due to compression loading, while also providing a relatively tall profile height.
Referring generally to
Transition cross-sectional profiles 112 of transition stiffener portion 110 gradually shifting (e.g., transitioning) from first cross-sectional profile 104 of first stiffener portion 102 to second cross-sectional profile 108 of second stiffener portion 106 to provides effective load transfer between first stiffener portion 102 and second stiffener portion 106 through transition stiffener portion 110 and along skin 202 of structure 200.
Referring generally to
All of transition cross-sectional profiles 112 of transition stiffener portion 110 being different provide a consistent and continual transition (e.g., ramp rate) between first cross-sectional profile 104 of first stiffener portion 102 and second cross-sectional profile 108 of second stiffener portion 106 (e.g., from second cross-sectional profile 108 of second stiffener portion 106 to first cross-sectional profile 104 of first stiffener portion 102 or from first cross-sectional profile 104 of first stiffener portion 102 to second cross-sectional profile 108 of second stiffener portion 106).
Referring generally to
A smooth transition between first cross-sectional profile 104 and second cross-sectional profile 108 along transition cross-sectional profiles 112 gradually changes the centroid of stiffener 100 and reduces the potential of stiffener 100 pulling off of surface 204 of skin 202.
Abrupt changes to the centroid of stiffener 100 may increase the potential of stiffener 100 pulling away from surface 204 of skin 202.
Referring generally to
Charges 160 that are stacked and laminated together form an integral, continuous part of stiffener 100 capable of effectively transferring loads between first stiffener portion 102 and second stiffener portion 106 along transition stiffener portion 110.
Referring, e.g., to
Varying and/or alternating the orientation of reinforcing fibers 240 among prepreg composite plies 126, with respect to a longitudinal axis of each one of charges 160, at a plurality of different angles, such as approximate angles of 0-degrees, −45-degrees, 90-degrees, and 45-degrees, produces optimum mechanical properties (e.g., strength and/or stiffness) in charges 160 and stiffener 100 formed from charges 160.
Referring generally to
Base 122 and rib 168 of web 120 enables second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads due to compression and provides the majority of the height and a part of the shape of second cross-sectional profile 108 of second stiffener portion 106 and transition cross-sectional profiles 112 of transition stiffener portion.
Referring generally to
Web 120 being tapered from second stiffener portion 106 to first stiffener portion 102 gradually reduces the height of transition cross-sectional profiles 112 from second stiffener portion 106 to first stiffener portion 102 and effectively transfers loads between first stiffener portion 102 and second stiffener portion 106 along transition stiffener portion 110.
Referring generally to
Gradually decreasing width W1 of each one of charges 160 and gradually increasing combined height H1 of the stack of charges 160 along transition stiffener portion 110 provides for the smooth transition of transition cross-sectional profiles 112 from second cross-sectional profile 108 to first cross-sectional profile 104 and enables effective load transfer between second stiffener portion 106 and first stiffener portion 102 along transition stiffener portion 110.
Referring generally to
Progressively (e.g., gradually) decreasing width W2 of base 122 of web 120 and progressively (e.g., gradually) decreasing height H2 of rib 168 of web 120 provides for the smooth transition of transition cross-sectional profiles 112 from second cross-sectional profile 108 to first cross-sectional profile 104 and enables effective load transfer between second stiffener portion 106 and first stiffener portion 102 along transition stiffener portion 110.
Referring generally to
A laminated stack of base charge 124, initial charge 148, and subsequent charge A form an integral, continuous part of stiffener 100 capable of effectively reacting to loads (e.g., different bending loads) and transferring loads between first stiffener portion 102 and second stiffener portion 106 along transition stiffener portion 110 and along skin 202.
Referring generally to
Web 120 enables second stiffener portion 106 and transition stiffener portion 110 and, thus, skin 202 to suitably react to bending loads primarily due to compression and provides the majority of the height of second cross-sectional profile 108 of second stiffener portion 106 and transition cross-sectional profiles 112 of transition stiffener portion.
Referring generally to
Covering (e.g., wrapping) base charge 124, initial charge 148 and subsequent charge A with cover layer 176 further integrates base charge 124, initial charge 148 and subsequent charge A (e.g., charges 160) into a continuous part of stiffener 100 capable of reacting to bending loads and transferring loads between first stiffener portion 102 and second stiffener portion 106.
Referring generally to
Covering (e.g., wrapping) base charge 124, initial charge 148 and subsequent charge A (e.g., charges 160) and at least a portion of surface 204 of skin 202 with cover layer 176 further integrates base charge 124, initial charge 148, subsequent charge A and skin 202 into integral structure 200 capable of reacting to bending loads and transferring loads between first stiffener portion 102 and second stiffener portion 106 and along skin 202.
Referring generally to
Web charge 178 and opposing web charge 184 in combination enable second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads primarily due to compression and provides the majority of the height and a part of the shape of second cross-sectional profile 108 of second stiffener portion 106 and transition cross-sectional profiles 112 of transition stiffener portion.
Referring generally to
Thickness T of transition web-charge portion 182 of web charge 178 and of transition opposing-web-charge portion 188 of opposing web charge 184 gradually decreasing from second stiffener portion 106 to first stiffener portion 102 gradually reduces the transition cross-sectional profiles 112 from second stiffener portion 106 to first stiffener portion 102.
Referring generally to
Transition web-charge portion 182 of web charge 178 and transition opposing-web-charge portion 188 of opposing web charge 184 being tapered from second stiffener portion 106 to first stiffener portion 102 smoothly transitions the transition cross-sectional profiles 112 from second stiffener portion 106 to first stiffener portion 102.
Referring generally to
L-shaped web charge 178 and opposing web charge 184 are used to form a part of T-shaped second cross-sectional profile 108 of second stiffener portion 106.
Referring generally to
U-shaped web charge 178 and opposing web charge 184 are used to form a part of I-shaped second cross-sectional profile 108 of second stiffener portion 106.
Referring generally to
Cap charge 190 intercouples web charge 178 and opposing web charge 184 and forms a part of the I-shaped second cross-sectional profile 108 of second stiffener portion 106. Cap charge 190 further enables second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads primarily due to compression loading.
Referring generally to
Filler charge 192 enhances the load-carrying capabilities of stiffener 100 and structure 200.
Referring generally to
Subsequent charge B being stacked and laminated onto subsequent charge A further increases combined height H1 (
Referring generally to
Subsequent charges B through N being sequentially stacked and laminated onto subsequent charge A further increases combined height H1 (
Referring generally to
First brace 210 and second brace 212 couples stiffener 100 and, thus, skin 202 to another component, for example, another component of structure 200 positioned opposite skin 202 and distribute loads.
First brace 210 is configured (e.g., suitably shaped) to be coupled to first cross-sectional profile 104 of first stiffener portion 102. Second brace 212 is configured (e.g., suitably shaped) to be coupled to second cross-sectional profile 108 of second stiffener portion 106.
Referring generally to
Positioning transition stiffener portion 110 between first brace 210 and second brace 212 enables effective load transfer between first stiffener portion 102 and second stiffener portion 106 (e.g., from second stiffener portion 106 to first stiffener portion 102) and distribution of the load to first brace 210 and second brace 212.
Referring generally to
Upper skin 216 stiffened by upper stiffener 220 and lower skin 218 stiffened by lower stiffener 222 form structure 200, such as a box structure, with upper skin 216 and lower skin 222 being spaced apart and intercoupled by first brace 210 and second brace 212.
Upper stiffener 220 including second stiffener portion 106 having a high profile (e.g., a tall second cross-sectional profile 108) and first stiffener portion 102 having a low profile (e.g., a short first cross-sectional profile 104) enables a distance between upper skin 216 and lower skin 218 to be reduced, at least along first stiffener portion 102 of upper stiffener 220, resulting in structure 200 having a reduced thickness and/or an increase in the available clearance between upper skin 216 (and upper stiffener 220) and lower skin 218 (and lower stiffener 222).
Referring generally to
Upper stringer 224 having a low profile portion (e.g., first stiffener portion 102 having first cross-sectional profile 104) enables a decrease in the thickness of wing 206, at least along a portion of wing 206 stiffened by first stiffener portion 102 of upper stringer 224 (e.g., outboard portion 242 of wing 206).
As one example, distance D (
Ribs 214 provide shape and support to wing 206 (e.g., the wingbox structure). Ribs 214 distribute loads from and between upper stringer 224 and lower stringer 226. A distance between ribs 214 may define a rib bay (not explicitly illustrated). Transition stiffener portion 110 of upper stiffener 224 may be positioned within the rib bay (e.g., may extend between adjacent ribs 214).
Referring generally to
A constant cross-sectional profile of lower stiffener 222 enables lower stiffener 222 to suitably react to certain types of loads (e.g., bending loads primarily due to tension loading).
The cross-sectional profile of lower stiffener 222 may have any suitable shape depending upon the particular structural application of lower stiffener 222, for example, when used to construct structure 200. As one example, the cross-sectional profile of lower stiffener 222 may be designed to react to bending loads primarily due to tension.
Lower stiffener 222 may have a different cross-sectional profile than a cross-sectional profile of at least part of upper stiffener 220. As one example, the cross-sectional profile of lower stiffener 222 may be the same as first cross-sectional profile 104 of first stiffener portion 102 of upper stiffener 220 and different than second cross-sectional profile 108 of second stiffener portion 106 of upper stiffener 220.
Referring generally to
A trapezoidally shaped cross-sectional profile of lower stiffener 222 enables lower stiffener 222 to suitably react to bending loads primarily due to tension loading, while also providing a relatively short profile height.
Referring generally to
Second stiffener portion 106 having second cross-sectional profile 108 of upper stiffener 220 (e.g., upper stringer 224) extending continuously from first end 228 to second end 230 of wing 206 enables wing 206 to react to bending loads primarily due to compression.
As one example, at least a portion of the length of wing 206 that experiences bending loads primary from compression is stiffened by second stiffener portion 106 of upper stiffener 220. A remaining portion of the length of wing 206 (e.g., outboard portion 242) is stiffened by first stiffener portion 102 of upper stiffener 220 since bending loads primarily from compression imposed on wing 206 are less farther from fuselage 232.
Referring generally to
Transition portion 110 of upper stiffener 220 being located at least twenty-five percent of length of wing 206 away from second end 230 of wing 206 defines the length of first stiffener portion 102 of upper stiffener 220 relative to second stiffener portion 106 of upper stiffener 220 and enables a reduction in thickness of an outermost twenty-five percent of wing 206.
Referring generally to
Transition portion 110 of upper stiffener 220 being located at least fifty percent of length of wing 206 away from second end 230 of wing 206 defines the length of first stiffener portion 102 of upper stiffener 220 relative to second stiffener portion 106 of upper stiffener 220 and enables a reduction in thickness of an outermost fifty percent of wing 206.
Referring generally to
Co-curing stiffener 100 and skin 202 bonds stiffener 100 and skin 202 at least partially defines the load bearing and load transferring characteristics of structure 200. In the co-curing process, both stiffener 100 and skin 202 are formed from an uncured composite material. All resins of the uncured composite materials of both stiffener 100 and skin 202 are simultaneously cured during the same process to bond stiffener 100 to skin 202.
Referring generally to
Co-bonding stiffener 100 and skin 202 bonds stiffener 100 and skin 202 at least partially defines the load bearing and load transferring characteristics of structure 200. In the co-bonding process, one of stiffener 100 and skin 202 is formed from an uncured composite material and one of stiffener 100 and skin 202 is formed from a cured composite material. Resins of the uncured composite material are cured during the process to bond stiffener 100 to skin 202.
Referring generally to
Secondarily bonding stiffener 100 and skin 202 bonds stiffener 100 and skin 202 at least partially defines the load bearing and load transferring characteristics of structure 200. In the secondary bonding process, both stiffener 100 and skin 202 are formed from a cured (e.g., pre-cured) composite material. An adhesive is applied between stiffener 100 and skin 202 and is cured during the same process to bond stiffener 100 to skin 202.
Referring generally to
Laminating a successive stack of base charge 124, initial charge 148 and subsequent charge A thereby forms integral and continuous portions of part of stiffener 100 (e.g., first stiffener portion 102, part of transition stiffener portion 110, and part of second stiffener portion 106) capable of effectively reacting to loads (e.g., different bending loads) and transferring loads between first stiffener portion 102 and the part of second stiffener portion 106 along the part of transition stiffener portion 110.
Referring generally to
Laminating subsequent charge B stacked onto subsequent charge A further increases combined height H1 (
Referring generally to
Providing a smooth transition among transition initial-charge portion 152 of initial charge 148, transition subsequent-charge-A portion of subsequent charge A, and transition subsequent-charge-B portion of subsequent charge B gradually changes the centroid of the part of stiffener 100 and reduces the potential of transition initial-charge portion 152 of initial charge 148, transition subsequent-charge-A portion of subsequent charge A, and transition subsequent-charge-B portion of subsequent charge B pulling away from each other, for example, under a bending load.
Referring generally to
Removing end portions of transition initial-charge portion 152, transition subsequent-charge-A portion, and transition subsequent-charge-B portion, for example, at a predetermined cutting angle (e.g., similar to the ramp rate of the increase in combined height H1 of charges 160), provides a smooth surface along the part of transition stiffener portion 110.
As one example, cover layer 176, filler charge 192, and/or web 120 may be stacked on and laminated to the smooth surface of transition stiffener portion 110.
As one example, ends portions (illustrated but not explicitly identified) of transition initial-charge portion 152, transition subsequent-charge-A portion, and transition subsequent-charge-B portion may be removed (e.g., cut off) by using an ultrasonic knife (not explicitly illustrated), for example, under computer control. As one example, ends portions of transition initial-charge portion 152, transition subsequent-charge-A portion, and transition subsequent-charge-B portion may be cut away at an angle.
Referring generally to
Covering (e.g., wrapping) first stiffener portion 102, the part of transition stiffener portion 110, and the part of second stiffener portion 106 with cover layer 176 further integrates first base-charge portion 142 of base charge 124, first initial-charge portion 150 of initial charge 148, first subsequent-charge-A portion of subsequent charge A, transition base-charge portion 146 of base charge 124, transition initial-charge portion 152 of initial charge 148, transition subsequent-charge-A portion of subsequent charge A, and second base-charge portion 144 of base charge 124 into a continuous part of stiffener 100 capable of reacting to bending loads and transferring loads between first stiffener portion 102 and second stiffener portion 106 along transition stiffener portion 110.
Referring generally to
Providing web 120 enables second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads primarily due to compression.
Referring generally to
In combination, providing web charge 178 and opposing web charge 184 enable second stiffener portion 106 and transition stiffener portion 110 to suitably react to bending loads primarily due to compression and provides the majority of the height and a part of the shape of second cross-sectional profile 108 of second stiffener portion 106 and transition cross-sectional profiles 112 of transition stiffener portion.
Referring generally to
Providing filler charge 192 between web charge 178 and opposing web charge 184 fills an open space between web charge 178 and opposing web charge 184 enhances the load-carrying capabilities of stiffener 100.
Referring generally to
Trimming transition web-charge portion 182 of web charge 178 and transition opposing-web-charge portion 188 of opposing web charge 184 to taper transition web-charge portion 182 and transition opposing-web-charge portion 188 from second stiffener portion 106 to first stiffener portion 102 provides smooth transition between second stiffener portion 106 to first stiffener portion 102 along transition stiffener portion 110 and gradually changes the centroid of stiffener 100.
As one example, transition web-charge portion 182 of web charge 178 and transition opposing-web-charge portion 188 of opposing web charge 184 may be performed (e.g., cut off) by using an ultrasonic knife (not explicitly illustrated), for example, under computer control. As one example, ends portions of transition initial-charge portion 152, transition subsequent-charge-A portion, and transition subsequent-charge-B portion may be cut away at an angle.
Examples of the present disclosure may be described in the context of aircraft manufacturing and service method 1100 as shown in
Each of the processes of illustrative method 1100 may be performed or carried out by a system integrator, a third party, and/or an operator (e.g., a customer). For the purposes of this description, a system integrator may include, without limitation, any number of aircraft manufacturers and major-system subcontractors; a third party may include, without limitation, any number of vendors, subcontractors, and suppliers; and an operator may be an airline, leasing company, military entity, service organization, and so on.
As shown in
Apparatus(es) and method(s) shown or described herein may be employed during any one or more of the stages of the manufacturing and service method 1100. For example, components or subassemblies corresponding to component and subassembly manufacturing (block 1108) may be fabricated or manufactured in a manner similar to components or subassemblies produced while aircraft 1102 is in service (block 1114). Also, one or more examples of the apparatus(es), method(s), or combination thereof may be utilized during production stages 1108 and 1110, for example, by substantially expediting assembly of or reducing the cost of aircraft 1102. Similarly, one or more examples of the apparatus or method realizations, or a combination thereof, may be utilized, for example and without limitation, while aircraft 1102 is in service (block 1114) and/or during maintenance and service (block 1116).
Different examples of the apparatus(es) and method(s) disclosed herein include a variety of components, features, and functionalities. It should be understood that the various examples of the apparatus(es) and method(s) disclosed herein may include any of the components, features, and functionalities of any of the other examples of the apparatus(es) and method(s) disclosed herein in any combination, and all of such possibilities are intended to be within the scope of the present disclosure.
Many modifications of examples set forth herein will come to mind to one skilled in the art to which the present disclosure pertains having the benefit of the teachings presented in the foregoing descriptions and the associated drawings.
Therefore, it is to be understood that the present disclosure is not to be limited to the specific examples illustrated and that modifications and other examples are intended to be included within the scope of the appended claims. Moreover, although the foregoing description and the associated drawings describe examples of the present disclosure in the context of certain illustrative combinations of elements and/or functions, it should be appreciated that different combinations of elements and/or functions may be provided by alternative implementations without departing from the scope of the appended claims. Accordingly, parenthetical reference numerals in the appended claims are presented for illustrative purposes only and are not intended to limit the scope of the claimed subject matter to the specific examples provided in the present disclosure.
Claims
1. A method (300) of making a stiffener (100), the method (300) comprising:
- laying up a base charge (124) to form a part of a first stiffener portion (102) of the stiffener (100) from a first base-charge portion (142) of the base charge (124), to form a part of a second stiffener portion (106) of the stiffener (100) from a second base-charge portion (144) of the base charge (124), and to form a part of a transition stiffener portion (110) of the stiffener (100) from a transition base-charge portion (146) of the base charge (124), wherein the transition base-charge portion (146) tapers from the second base-charge portion (144) to the first base-charge portion (142);
- laminating an initial charge (148) onto the base charge (124) to form a part of the first stiffener portion (102) of the stiffener (100) from a first initial-charge portion (150) of the initial charge (148) and to form a part of the transition stiffener portion (110) of the stiffener (100) from a transition initial-charge portion (152) of the initial charge (148), wherein the first initial-charge portion (150) of the initial charge (148) is shaped identically to the first base-charge portion (142) of the base charge (124) and the transition initial-charge portion (152) of the initial charge (148) is shaped identically to at least a portion of the transition base-charge portion (146) of the base charge (124); and
- laminating a subsequent charge A onto the initial charge (148) to form a part of the first stiffener portion (102) of the stiffener (100) from a first subsequent-charge-A portion of the subsequent charge A and to form a part of the transition stiffener portion (110) of the stiffener (100) from a transition subsequent-charge-A portion of the subsequent charge A, wherein the first subsequent-charge-A portion of the subsequent charge A is shaped identically to the first initial-charge portion (150) of the initial charge (148) and the transition subsequent-charge-A portion of the subsequent charge A is smaller than the transition initial-charge portion (152) of the initial charge (148) and is shaped identically to a portion of the transition initial-charge portion (152).
2. The method (300) according to claim 1, further comprising adding a web (120) that forms a part of the second stiffener portion (106) and a part of the transition stiffener portion (110).
3. The method (300) according to claim 1, further comprising:
- laminating a subsequent charge B onto the subsequent charge A to form a part of the first stiffener portion (102) of the stiffener (100) from a first subsequent-charge-B portion of the subsequent charge B and to form a part of the transition stiffener portion (110) of the stiffener (100) from a transition subsequent-charge-B portion of the subsequent charge B.
4. The method (300) according to claim 3, wherein the first subsequent-charge-B portion of the subsequent charge B is shaped identically to the first subsequent-charge-A portion of the subsequent charge A and the transition subsequent-charge-B portion of the subsequent charge B is smaller than the transition subsequent-charge-A portion of the subsequent charge A and is shaped identically to a portion of the transition subsequent-charge-A portion.
5. The method (300) according to claim 4, further comprising adding a web (120) that forms a part of the second stiffener portion (106) and a part of the transition stiffener portion (110).
6. The method (300) according to claim 4, further comprising covering with a cover layer (176) the first stiffener portion (102), formed, at least partially, by the first base-charge portion (142) of the base charge (124), the first initial-charge portion (150) of the initial charge (148), and the first subsequent-charge-A portion of the subsequent charge A.
7. The method (300) according to claim 4, further comprising covering with a cover layer (176) a part of the transition stiffener portion (110) formed, at least partially, by the transition base-charge portion (146) of the base charge (124), the transition initial-charge portion (152) of the initial charge (148) and the transition subsequent-charge-A portion of the subsequent charge A.
8. The method (300) according to claim 4, further comprising covering with a cover layer (176) a part of the second stiffener portion (106), formed, at least partially, by the second base-charge portion (144) of the base charge (124).
9. The method (300) according to claim 4, further comprising covering with a cover layer (176):
- the first stiffener portion (102), formed, at least partially, by the first base-charge portion (142) of the base charge (124), the first initial-charge portion (150) of the initial charge (148), and the first subsequent-charge-A portion of the subsequent charge A;
- a part of the transition stiffener portion (110) formed, at least partially, by the transition base-charge portion (146) of the base charge (124), the transition initial-charge portion (152) of the initial charge (148) and the transition subsequent-charge-A portion of the subsequent charge A; and
- a part of the second stiffener portion (106), formed, at least partially, by the second base-charge portion (144) of the base charge (124).
10. The method (300) according to claim 4, further comprising a step of providing a smooth transition among the transition initial-charge portion (152) of the initial charge (148), the transition subsequent-charge-A portion of the subsequent charge A, and the transition subsequent-charge-B portion of the subsequent charge B.
11. The method (300) according to claim 10, further comprising adding a web (120) that forms a part of the second stiffener portion (106) and a part of the transition stiffener portion (110).
12. The method (300) according to claim 10, further comprising covering with a cover layer (176):
- the first stiffener portion (102), formed, at least partially, by the first base-charge portion (142) of the base charge (124), the first initial-charge portion (150) of the initial charge (148), and the first subsequent-charge-A portion of the subsequent charge A;
- a part of the transition stiffener portion (110) formed, at least partially, by the transition base-charge portion (146) of the base charge (124), the transition initial-charge portion (152) of the initial charge (148) and the transition subsequent-charge-A portion of the subsequent charge A; and
- a part of the second stiffener portion (106), formed, at least partially, by the second base-charge portion (144) of the base charge (124).
13. The method (300) according to claim 10, wherein the step of providing the smooth transition among the transition initial-charge portion (152) of the initial charge (148), the transition subsequent-charge-A portion of the subsequent charge A, and the transition subsequent-charge-B portion of the subsequent charge B comprises removing end portions of the transition initial-charge portion (152), the transition subsequent-charge-A portion, and the transition subsequent-charge-B portion.
14. The method (300) according to claim 13, further comprising adding a web (120) that forms a part of the second stiffener portion (106) and a part of the transition stiffener portion (110).
15. The method (300) according to claim 13, further comprising covering with a cover layer (176):
- the first stiffener portion (102), formed, at least partially, by the first base-charge portion (142) of the base charge (124), the first initial-charge portion (150) of the initial charge (148), and the first subsequent-charge-A portion of the subsequent charge A;
- a part of the transition stiffener portion (110) formed, at least partially, by the transition base-charge portion (146) of the base charge (124), the transition initial-charge portion (152) of the initial charge (148) and the transition subsequent-charge-A portion of the subsequent charge A; and
- a part of the second stiffener portion (106), formed, at least partially, by the second base-charge portion (144) of the base charge (124).
16. The method (300) according to claim 15, further comprising a step of adding a web (120) that forms a part of the second stiffener portion (106) and a part of the transition stiffener portion (110).
17. The method (300) according to claim 16, wherein the step of adding the web (120) that forms a part of the second stiffener portion (106) and a part of the transition stiffener portion (110) comprises:
- forming a part of the second stiffener portion (106) from a second web-charge portion (180) of a web charge (178);
- forming a part of the transition stiffener portion (110) from a transition web-charge portion (182) of the web charge (178);
- abutting an opposing web charge (184) with the web charge (178);
- forming a part of the second stiffener portion (106) from a second opposing-web-charge portion (186) of the opposing web charge (184); and
- forming a part of the transition stiffener portion (110) from a transition opposing-web-charge portion (188) of the opposing web charge (184).
18. The method (300) according to claim 17, further comprising trimming the transition web-charge portion (182) of the web charge (178) and the transition opposing-web-charge portion (188) of the opposing web charge (184) such that the transition web-charge portion (182) of the web charge (178) and the transition opposing-web-charge portion (188) of the opposing web charge (184) taper from the second stiffener portion (106) to the first stiffener portion (102).
19. The method (300) according to claim 17, further comprising placing a filler charge (192) between the web charge (178) and the opposing web charge (184) to form a part of the second stiffener portion (106) from a second filler-charge portion (194) of the filler charge (192) and to form a part of the transition stiffener portion (110) from a transition filler-charge portion (196) of the filler charge (192).
20. The method (300) according to claim 19, further comprising trimming the transition web-charge portion (182) of the web charge (178) and the transition opposing-web-charge portion (188) of the opposing web charge (184) such that the transition web-charge portion (182) of the web charge (178) and the transition opposing-web-charge portion (188) of the opposing web charge (184) taper from the second stiffener portion (106) to the first stiffener portion (102).
Type: Application
Filed: Aug 30, 2017
Publication Date: Jan 4, 2018
Applicant: The Boeing Company (Chicago, IL)
Inventor: Jordan D. Charles (Seattle, WA)
Application Number: 15/690,521