MODULAR TOOLING FOR MULTI-SPAR TORSION BOX

Abstract

Tooling for manufacturing multi-spar torsion boxes with different web heights, the tooling includes a mandrel module having a hollow beam geometry which comprises a first base and a second base opposite to the first base, and two walls extending between said first base and said second base, and at least one spacer module configured for coupling with the mandrel module, wherein the web height of a multi-spar torsion box is defined by the coupling between the mandrel module and at least one spacer module. A method for manufacturing multi-spar torsion boxes with different web heights.

Claims

1. A modular tooling configured to manufacture multi-spar torsion boxes, wherein the boxes have different web heights, the modular tooling comprising: a mandrel module including a hollow beam geometry which comprises a first base, a second base opposite to the first base, and two walls extending between said first base and said second base, and at least one spacer module configured to couple with the mandrel module, wherein the at least one spacer module is selected from a plurality of spacer modules each having a common width and a different height; wherein the web height of a multi-spar torsion box is defined by the coupling between the mandrel module and the at least one spacer module.

2. The modular tooling of claim 1, wherein at least one of the first base, the second base and a wall of the two walls of the mandrel module comprises a first fastener, and wherein the at least one spacer module comprises a second fastener configured to engage the first fastener to fix the mandrel module to the at least one spacer module.

3. The modular tooling of claim 2, wherein one of the first and second fasteners comprises at least one pin complementary to at least one hole arranged on the other of the first and second fasteners, wherein the at least one pin is configured to engage the at least one hole.

4. The modular tooling of claim 1, wherein the at least one spacer module includes a hollow beam geometry comprising a first spacer module base and a second spacer module base opposite to the first spacer module base, and two spacer module walls extending between said first spacer module base and said second spacer module base, and wherein the mandrel module and the at least one spacer module are configured to be stacked such that the first or second base of the mandrel module is abuts the first or second spacer module base.

5. The modular tooling of claim 4, wherein a stack of the mandrel module and the at least one spacer module includes: two opposed bases comprising one of the first and second base of the mandrel module, and one of the first and second spacer module bases; and opposite external walls defined by the two walls of the mandrel module and the two spacer module walls.

6. The modular tooling of claim 1, wherein the at least one spacer module includes a plank spacer module and a hollow beam spacer module, wherein the plank spacer module and the hollow beam spacer module are stacked together.

7. The modular tooling of claim 1, wherein the mandrel module comprises a first mandrel module member and a second mandrel module member configured to couple to the first mandrel module member, wherein the first mandrel module member comprises a first mandrel module base and two first mandrel module walls extending from said first mandrel module base, wherein the second mandrel module member comprises a second mandrel module base and two second mandrel module walls extending from said second mandrel module base, wherein a first of the first mandrel module walls is configured to abut a first of the second mandrel module walls, wherein a second of the first mandrel module walls and a second of the mandrel module walls each comprise a distal end configured to couple with at least one spacer module, and wherein said spacer module is interposed between the distal ends of the first and second mandrel module walls.

8. The modular tooling of claim 7, wherein the distal ends each comprises a projection, and wherein the spacer module has a Z-shaped body configured for engaging with said projections.

9. The modular tooling of claim 8 further comprising a joint sealing located at interfaces between the distal ends of the mandrel module members and the spacer module, wherein the joint seals are configured for provide air tightness to the joint interfaces.

10. The modular tooling of claim 9, wherein the joint sealing comprise a rubber sealant and/or at least one encapsulated anchor nut.

11. The modular tooling of claim 1, wherein at least one spacer module is configured to enclose the mandrel module, such that first and second walls of the mandrel module abut interior walls of the at least one spacer module, and the first and second bases of the mandrel module abut interior bases of the at least one spacer module.

12. The modular tooling of claim 11, wherein the at least one spacer module configured to enclose the mandrel module is a composite laminate spacer module.

13. The modular tooling of claim 1, wherein the mandrel module is an aluminum mandrel module.

14. A method to assemble modular tooling to form a multi-spar torsion box, the method comprising: receiving information defining a selected predefined height for the module tooling, wherein the selected predefined height is selected from a plurality of predefined heights; providing a mandrel module including a hollow beam geometry which comprises a first base, a second base opposite to the first base, and two walls extending between said first base and said second base; selecting at least one spacer module from a plurality of spacer modules, wherein the spacer modules include spacer modules having common widths and different heights, wherein the selection of the at least one spacer module is made to stack one or more of the spacer modules and the mandrel module to the selected predefined height; coupling the mandrel module to the selected at least one spacer module; stacking the selected at least one spacer module and the mandrel module to form a modular tooling assembly stack, wherein the modular tooling assembly stack has a height corresponding to the selected predefined height; and forming multi-spar torsion box using the modular tooling assembly stack.

15. The method of claim 14, wherein the modular tooling stack is a first modular tooling stack and the method further comprises: defining a chord of the multi-spar torsion box to be formed; selecting at least one other spacer module from the plurality of spacer modules; coupling a second mandrel module to the selected at least one other spacer module; stacking the selected at least one other spacer module and the second mandrel module to form a second modular tooling assembly stack, wherein the second modular tooling assembly stack has a height corresponding to the selected predefined height; coupling together along a chordwise direction the first and second multi-spar torsion boxes to form the modular tooling stack which has a dimension in the chordwise direction corresponding to the defined chord of the multi-spar torsion box.

16. A modular tooling kit configured to manufacture multi-spar torsion box, the modular tooling comprising: a hollow beam mandrel module having a first base, a second base opposite to the first base, and side walls extending between the first and second bases; and a plurality of spacer modules each configured to couple with the mandrel module and each of the spacer modules having a width common to a width of the mandrel module and a height differing from at least one of the other spacer modules; wherein the mandrel module is stacked with a selected at least one of the spacer modules to form a modular tool stack having a height corresponding to one of a plurality of predefined web height of the multi-spar torsion box, and wherein the modular tool stack is configured to form a multi-spar torsion boxing having at least one web with a height corresponding to the predefined web height.

17. The modular tooling kit of claim 16, wherein the plurality of spacer modules includes a hollow beam spacer module comprising a first spacer module base and a second spacer module base opposite to the first spacer module base, and two spacer module walls extending between said first spacer module base and said second spacer module base, and wherein the modular tool stack includes the first or second base of the mandrel module abutting the first or second spacer module base.

18. The modular tooling kit of claim 16, wherein the plurality of spacer modules includes a plank spacer module, and the modular tool stack includes the plank spacer module.

Description

SUMMARY OF THE DRAWINGS

[0056] These and other characteristics and advantages of the invention will become clearly understood in view of the detailed description of the invention which becomes apparent from a preferred embodiment of the invention, given just as an example and not being limited thereto, with reference to the drawings.

[0057] FIG. 1 shows tooling for manufacturing a single configuration of a multi-spar torsion box as previously used in the aircraft industry.

[0058] FIG. 2 is a schematic representation of the modularity principle of multi-spar torsion boxes with different web heights produced by the tooling according to the present invention.

[0059] FIG. 3 shows a schematic representation of two different configurations of modular tooling according to an embodiment of the present invention, each configuration defining a different web height for manufacturing a multi-spar torsion box.

[0060] FIG. 4 shows two different configurations of a modular tooling set according to an embodiment of the present invention, each configuration defining a different web height for manufacturing a multi-spar torsion box.

[0061] FIG. 5 shows modular tooling according to an embodiment of the present invention, wherein two mandrel module members and one spacer module are coupled defining a web height for manufacturing a multi-spar torsion box.

[0062] FIG. 6 shows two different configurations of the joint between a z-shaped spacer module and the projections of the distal ends of two mandrel module members according to an embodiment of the present invention.

[0063] FIG. 7 shows a schematic representation of two different configurations of modular tooling according to an embodiment of the present invention, each configuration defining a different web height for manufacturing a multi-spar torsion box.

[0064] FIG. 8 shows a modular tooling comprising several configurations of a coupling between a mandrel module and a spacer module, arranged in combination for manufacturing a multi-spar torsion box.

[0065] FIG. 9 shows an aircraft comprising a multi-spar torsion box manufactured according to an embodiment of the present invention

DETAILED DESCRIPTION

[0066] FIG. 1 schematically illustrates a tooling solution currently used in the aircraft industry, along with a top view of an example of a multi-spar torsion box (100). In particular, the tooling (101) comprises several fixed height mandrels (102) for manufacturing a single configuration of a multi-spar torsion box (100). The tooling (101) shown is used to produce a multi-spar torsion box (100) by a hot forming method.

[0067] The tooling (101) comprises a base plate (103) which performs the functions of sustaining and transporting the rest of the elements which are part of the tooling (101) required for applying a thermodynamic process to the multi-spar torsion box (100) made of composite material, while ensuring fulfilment of the restrictive structural and dimensional tolerances.

[0068] Different layers of composite material are provided along part of the external surface of the mandrels (102), obtaining the desired distribution of composite material which will undergo the curing process. In particular, in FIG. 1 the composite material is distributed following a C-shape pattern, such that the mandrels (102) can be distributed by alternating the orientation of the C-shape pattern for producing the spars (100.1) by bringing together two walls completely covered with composite material; and for producing several stringers or stiffening elements (100.2) by connecting the walls which are only partially covered with composite material.

[0069] In this sense, several mandrels (102) are shown assembled together with fresh composite laminates layered so as to provide the structure with its final shape, prior to said curing process, to build the complete multi-spar torsion box (100). Additionally, external Caul plates (103) are used to secure aerodynamic tolerances.

[0070] Regarding the fixed height mandrels (102) used in the prior art, as shown in FIG. 1, they are built by welding two C-shape aluminum beams and are assembled and coordinated among themselves by means of longitudinal rods (105) with hippodrome shape.

[0071] Using this tooling (101), it is possible to manufacture a multi-spar torsion box (100) combining skins (100.3, 100.4), stringers (100.2) and spars (101.1). As every mandrel (102) has a predefined fixed shape, in case of any multi-spar torsion box (100) height change, new mandrels (102) should be implemented for producing the required structure (100).

[0072] FIG. 2 schematically illustrates the principle of the invention using a set of modular lifting surfaces as an example. In this example, the multi-spar torsion box (100) is modified only by varying the web height of the front and rear spars (101.11, 101.12) while maintaining common upper (100.3) and lower skins (100.4). Then, the addition of different leading edges (LE) (106) and different trailing edges (TE) (107) enables the modification of the lifting surface planform and therefore allows tailoring the size of the lifting surface to the sizing requirements of a particular member of the aircraft family.

[0073] It is to be noted that FIG. 2 is simply a schematic representation of the concept and the implied increase in relative thickness (t/c, thickness-to-chord ratio) has not be taken into account. It is assumed that the different multi-spar torsion boxes (100) with different heights corresponding to each embodiment compensate the increase in loads due to the longer chords for the leading and trailing edges (LE and TE) due to the increased web height.

[0074] Further, for the sake of simplicity, FIG. 2 does not show an increase in trailing edge chord.

[0075] FIG. 3 shows a schematic representation of a front view of two different configurations of modular tooling (10) for manufacturing multi-spar torsion boxes (100) with different web heights (z1, z2) according to an embodiment of the present invention.

[0076] In particular, the Figure to the left shows one mandrel module (11) coupled to a spacer module (12A), and the Figure to the right shows the same mandrel module (11) coupled to a bigger spacer module (12A′), thus allowing to produce a higher multi-spar torsion box (100) for a different structure of an aircraft (1000) of the family.

[0077] Accordingly, the same modular tooling (10) allows providing different web heights to a set of multi-spar torsion boxes (100), thus tailoring the size of said multi-spar torsion boxes (100) to the sizing requirements of a particular member of an aircraft (1000) family.

[0078] The spacer modules (12A, 12A′) shown comprise a hollow beam geometry, with a first flat bottom base (12A.1, 12A.1′), substantially parallel to a second flat top base (12A.2, 12A.2′), which is spaced apart from the first flat bottom base (12A.1, 12A.1′) a distance determined by two parallel walls (12A.3, 12A.4; 12A.3′, 12A.4′) which extend substantially perpendicularly between the first flat bottom base (12A.1, 12A.1′) and the second flat top base (12A.2, 12A.2′).

[0079] Similarly, the mandrel module (11) comprises a hollow beam geometry, with a first flat bottom base (11.1), substantially parallel to a second flat top base (11.2), which is spaced apart from the first flat bottom base (11.1) a distance determined by two parallel walls (11.3, 11.4) which extend substantially perpendicularly between the first flat bottom base (11.1) and the second flat top base (11.2).

[0080] In both left and right stacks of mandrel and spacer modules shown in FIG. 3, the mandrel module (11) and the spacer module (12A, 12A′) are stacked one on the other to form a vertical column. The mandrel module (11) being supported on top of a respective spacer module (12A, 12A′), such that the first flat bottom base (11.1) of the mandrel module (11) is supported on the second flat top base (12A.2, 12A.2′) of the respective spacer module (12A, 12A′).

[0081] The width of the mandrel module (11) is the distance between the walls (11.3, 11.4) and is equal to the width of each spacer modules (12A, 12A′). Thus, the stacking (15) of the mandrel module (11) and each spacer module (12A, 12A′) forms a substantially rectangular geometry comprising two closed cells.

[0082] FIG. 4 shows a front view of two different configurations of modular tooling (10) for manufacturing multi-spar torsion boxes (100) with different web heights (z1, z2) according to an embodiment of the present invention.

[0083] In FIG. 4, the stack on the left shows a mandrel module (11) coupled to a spacer module (12A), and the stack to the right shows the same mandrel module (11) coupled to the same spacer module (12A) and to an additional spacer module (12D) in the form of a plank-shaped structure, for reaching a height (z2) greater than the height (z1) reached without the plank-shaped structure (12D), thus allowing to produce a higher multi-spar torsion box (100) for a different structure of an aircraft (1000) of the family.

[0084] The shared spacer module (12A) shown comprise a hollow beam geometry, with a first flat bottom base (12A.1), parallel to a second flat top base (12A.2), which is spaced apart from the first flat bottom base (12A.1) a distance determined by two parallel walls (12A.3, 12A.4) which extend perpendicularly between the first flat bottom base (12A.1) and the second flat top base (12A.2).

[0085] In the stack to the left in FIG. 4, the mandrel module (11) and the spacer module (12A) are stacked in the same manner than the embodiments shown in FIG. 3. This is, the mandrel module (11) is supported on top of the spacer module (12A), such that the first flat bottom base (11.1) of the mandrel module (11) is supported on the second flat top base (12A.2) of the spacer module (12A). Further, the width of the mandrel module (11), this is, the distance between the walls (11.3, 11.4) is equal to the width of the spacer modules (12A). Thus, the stacking (15) of the mandrel module (11) and the spacer module (12A) has a substantially rectangular geometry, comprising two closed cells.

[0086] However, in the stack to the right in FIG. 4, the plank-shaped structure (12D) is interposed between the mandrel module (11) and the spacer module (12A), such that the first flat bottom base (11.1) of the mandrel module (11) is supported on a top surface of the plank-shaped structure (12D), and the plank-shaped structure (12D) is supported on the second flat top base (12A.2) of the spacer module (12A).

[0087] Additionally, both stacks in FIG. 4 with and without the plank-shaped structure (12D) interposed therebetween comprise complementary fastening means for guiding the coupling process and for fixing said coupling once it has been completed.

[0088] In particular, in the stack to the left in FIG. 4, the mandrel module (11) and the spacer module (12A) comprise a blind hole drilled in the contact surfaces (11.1, 12A.2) of the stacking using a numerical control (NC) machine for achieving tight tolerances and allowing precise coordination between both holes, so that a pin (13) can penetrate both holes, substantially perpendicularly to both contact surfaces (11.1, 12.2), thus securing the coupling. In the same manner, in the figure to the right, the plank shaped structure (12D) stacked between the mandrel module (11) and the spacer module (12A) has been drilled in coordination with the holes of the contact surfaces (11.1, 12A.2) so that a longer pin (13′) can pass through the whole stacking (15), thus fixing the stacking among the mandrel module (11), the plank-shaped structure (12D) and the spacer module (12A).

[0089] FIG. 5 shows a front view of a configuration of a mandrel module (11) coupled to a spacer module (12B) of modular tooling (10) for manufacturing multi-spar torsion boxes (100) according to another embodiment of the invention, wherein the mandrel module (11) is split in a first (16) and second (17) mandrel module members.

[0090] In particular, the first mandrel module member (16) comprises a first base (16.1), a first wall (16.2) and a second wall (16.3) extending from said first base (16.1); and the second mandrel module member (17) comprises a second base (17.1), a first wall (17.2) and a second wall (17.3) extending from said second base (17.1).

[0091] On one side, the first wall (16.2) of the first mandrel module member (16) is shown abutting the first wall (17.2) of the second mandrel module member (17) along a portion of their lengths. Both first walls (16.2, 17.2) are configured for sliding on each other, such that, when the spacer module (12B) is replaced, or is set to couple with the mandrel module members (16, 17) in a different position, the defined web height (z) of the coupling changes thereby, said walls (16.2, 17.2) sliding on each other in order to adapt to the new configuration.

[0092] In this sense, said first walls (16.2, 17.2) are illustrated comprising a thickness reduction along the portion of their lengths configured for mechanically connecting the other respective first wall (16.2, 17.2). This way, the length of the portion in contact is maximized, such that both first walls (16.2, 17.2) can slide on each other along a plurality of configurations for defining different web heights for a multi-spar torsion box (100) to be manufactured. In particular, upon a change in the defined web height of the coupling due to a replacement or a change in the position of the spacer module (12B) interposed between both mandrel module members (16, 17), said first walls (16.2, 17.2) slide on each other in order to adapt to the new configuration, while remaining in mechanical contact, thus preventing the inner hollow volume from any vacuum leakage.

[0093] On the other side, the spacer module (12B) is shown interposed between the distal ends (16.4, 17.4) of the second walls (16.3, 17.3). In this sense, the distal end (16.4, 17.4) portions of both mandrel module members (16, 17) slope obliquely towards the joint interfaces (19.1, 19.2). In a similar manner, the spacer module (12B) shown has a portion substantially shaped as a trapezium, comprising two sloping surfaces configured for abutting the distal ends (16.4, 17.4) along said joint interfaces (19.1, 19.2).

[0094] This particular configuration with oblique surfaces in mechanical contact along the joint interfaces (19.1, 19.2) provides the modular tooling (10) with continuous height adjustment as a result of the potential coupling options for the mandrel module members (16, 17) and the spacer module (12B) along the joint interfaces (19.1, 19.2).

[0095] FIG. 6 shows an alternative embodiment for replacing the oblique surfaces in mechanical contact at the joint interfaces (19.1, 19.2) shown in FIG. 5. In particular, the figure shows a particular embodiment of a coupling between the distal ends (16.4, 17.4) of the mandrel module members (16, 17) and the spacer module (12B) achieved by means of two rectangular projections (16.5, 17.5) which are provided only on a portion of the contact surfaces of distal ends (16.4, 17.4), since the rest of the surface is configured for matching with the spacer module (12B), which, in this particular embodiment, is in the form of a z-shaped body.

[0096] Therefore, said z-shaped body (12B) is configured for matching with the projections (16.5, 17.5) of each respective distal end (16.4, 17.4), thus being interposed between them.

[0097] Further, since securing inner tightness along the composite curing cycle is necessary to ensure that the cycle is performed in proper conditions which prevents defects due to vacuum leakage, such as porosity, the joint interfaces (19.1, 1.2) have been provided with flat rubber sealants (18.1) which are interposed between the contact surfaces of both the rectangular projections (16.5, 17.5) and the z-shaped body (12B).

[0098] Apart from the addition of flat rubber sealants (18.1), in order to improve the sealant effect, as well as the stability of the coupling, an encapsulated anchor nut (18.2) along with a sealant ring has been provided at each joint interface (19.1, 19.2).

[0099] FIG. 7 shows a front view of two different configurations of modular tooling (10) for manufacturing multi-spar torsion boxes (100) with different web heights (z1, z2) according to an embodiment of the present invention.

[0100] The modular tooling to the left in FIG. 7 shows one mandrel module (11) coupled to a spacer module (12C). The modular tooling to the right in FIG. 7 shows the same mandrel module (11) coupled to a bigger spacer module (12C′), thus allowing to produce a higher multi-spar torsion box (100) for a different structure of an aircraft (1000) of the family.

[0101] In particular, the spacer module (12C, 12C′) is provided directly on the mandrel module (11) by an additive layer manufacturing process. More in particular, the modular tooling to the left in FIG. 7 shows a mandrel module (11) made of aluminum, wherein the two opposed bases (11.1, 11.2) and the walls (11.3, 11.4) have been completely surrounded by a composite laminate which has been provided directly on the outer surface of the mandrel module (11), thus wrapping said mandrel module (11), by braiding technology.

[0102] Thus, the length of the walls (11.3, 11.4) of the mandrel module (11), along with the thickness of the spacer module (12C) coupled thereto, resulting from the amount of composite material provided on the mandrel module (11), define a total height (z1) corresponding to the web height of a multi-spar torsion box (100) to be manufactured.

[0103] Regarding the modular tooling shown to the right in FIG. 7, additional composite material has been deposited surrounding the mandrel module (11), thus reaching a greater height (z2) which allows producing a higher multi-spar torsion box (100)

[0104] FIG. 8 shows modular tooling (10) comprising several configurations of a coupling between a mandrel module (11) and a spacer module (12A), arranged in combination for manufacturing a multi-spar torsion box (100), according to the steps of a method for manufacturing multi-spar torsion boxes (100) with different web heights according to the present invention.

[0105] In particular, a distance z1 has been determined as the web height of a multi-spar torsion box (100) to be manufactured. Then, two mandrel modules (11, 11′) have been coupled to respective spacer modules (12A, 12A′) tailored for achieving the web height determined (z1), according to the embodiments shown in FIG. 3. Later on, the mandrel modules (11, 11′) and the spacer modules (12A, 12A′) coupled thereto have been provided with composite material distributed according to a C-shape pattern.

[0106] Then, the two mandrel modules (11, 11′) coupled to respective spacer modules (12A, 12A′) have been arranged and coordinated among themselves by means of a longitudinal rod with hippodrome shape (24), such that two stringers (23) have been defined by bringing together the walls partially covered with composite material. Further, a first spar (20) has been defined by the composite material provided on one of the walls completely covered with composite material.

[0107] In a similar manner, two mandrel modules which are each split in two respective mandrel module members (16, 17; 16′, 17′) coupled with each other have been coupled to respective spacer modules (12B, 12B′) tailored for achieving the web height determined (z1), according to the embodiments shown in FIG. 5. Later on, the mandrel module members (16, 17; 16′, 17′) and the spacer modules (12B, 12B′) coupled thereto have been provided with composite material distributed according to a C-shape pattern.

[0108] Then, the mandrel module members (16, 17; 16′, 17′) coupled to respective spacer modules (12B, 12B′) have been arranged and coordinated among themselves by means of a longitudinal rod with rectangular shape (25), such that two stringers (23) have been defined by bringing together the walls partially covered with composite material. Further, a second spar (22) has been defined by the composite material provided on one of the walls completely covered with composite material.

[0109] Then, the four mandrel modules and respective spacer modules have been further assembled and coordinated among themselves in order to define an intermediate spar (21) by bringing together the other walls completely covered with composite material of each arrangement corresponding to the embodiments of FIGS. 3 and 5.

[0110] Then, composite material has been provided on both the upper and lower base of the assembled modular tooling (10) in order to define the upper skin (26) and lower skin (27) of a multi-spar torsion box (100).

[0111] FIG. 9 shows an aircraft (1000) comprising a multi-spar torsion box (100) manufactured that embodies the invention.

[0112] 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.