US20190358946A1 - Method of Making Core-Stiffened Structure - Google Patents
Method of Making Core-Stiffened Structure Download PDFInfo
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- US20190358946A1 US20190358946A1 US16/533,619 US201916533619A US2019358946A1 US 20190358946 A1 US20190358946 A1 US 20190358946A1 US 201916533619 A US201916533619 A US 201916533619A US 2019358946 A1 US2019358946 A1 US 2019358946A1
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Classifications
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- B32B3/10—Layered products comprising a layer with external or internal discontinuities or unevennesses, or a layer of non-planar shape; Layered products comprising a layer having particular features of form characterised by a discontinuous layer, i.e. formed of separate pieces of material
- B32B3/12—Layered products comprising a layer with external or internal discontinuities or unevennesses, or a layer of non-planar shape; Layered products comprising a layer having particular features of form characterised by a discontinuous layer, i.e. formed of separate pieces of material characterised by a layer of regularly- arranged cells, e.g. a honeycomb structure
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Definitions
- the present application relates in general to the field of core-stiffened structures.
- honeycomb core 101 disposed between and adhesively bonded to an inner skin and an outer skin.
- honeycomb core 101 shown in FIG. 1 .
- honeycomb core 101 includes a plurality of cells 103 (only one labeled for clarity) defined by cell walls 105 (only one labeled for clarity).
- Each of the plurality of cells 103 exhibits a width W.
- the plurality of cells 103 have substantially the same width W but, in some implementations, some cells 103 of the plurality of cells 103 may have different widths W than other cells 103 of the plurality of cells 103 .
- core-stiffened structures have been limited to the use of honeycomb core 101 having cell widths W of less than about 6 mm.
- cell walls 105 fail to provide sufficient support for inner skin 201 and outer skin 203 during “curing” of the core-stiffened part, which entails heating the assembled core-stiffened part under pressure.
- portions of inner skin 201 and portions of outer skin 203 undesirably extend into cells 103 of honeycomb core 101 .
- core-stiffened structures made from larger-celled honeycomb core 101 weigh less than similar structures made from small-celled honeycomb core 101 , the manufacture of large-celled composite structures has been limited.
- core-stiffened composite structure has been sealed from intrusion of moisture.
- Some typical core materials are subject to moisture absorption or corrosion resulting from trapped moisture within the core.
- the sealing of the core edges is done by ramping one skin along a bevel in the core until both skins contact each other and complete a seal around the periphery of the core.
- the pressure on the ramp surface of the core may push the core in a direction lateral to the tool.
- typically material is added to the skin in the proximity of the ramp in order to stabilize the skins from lateral distortion of the core during the cure cycle.
- the skin is thicker than the structural application requires so as to prevent lateral distortion of the core during the cure cycle.
- Such a scenario includes the risk of the core material being pushed laterally along the tool surface.
- additional material is added to the core material and/or to the skins in order to resist the lateral force, and therefore resist core distortion.
- FIG. 1 is a stylized, plan view of a portion of a conventional honeycomb core
- FIG. 2 is a stylized, cross-sectional view of a portion of a conventional, core-stiffened structure utilizing large-celled honeycomb core;
- FIG. 3 is a stylized, side, elevational view of a core-stiffened structure according to the present application
- FIG. 4 is a stylized, cross-sectional view of a portion of honeycomb core used in the core-stiffened structure of FIG. 3 , taken along the line 4 - 4 in FIG. 3 ;
- FIG. 5 is a stylized, exploded, cross-sectional view of a first embodiment of the core-stiffened structure of FIG. 3 ;
- FIG. 6 is a stylized, plan view of a portion of the honeycomb core of FIG. 4 with adhesive applied to a surface thereof;
- FIG. 7 is a stylized, cross-sectional view of the core-stiffened structure of FIG. 5 in a configuration ready for curing or processing;
- FIGS. 8-10 are stylized, cross-sectional views of the core-stiffened structure of FIG. 3 depicting a second illustrative embodiment of a method for making a core-stiffened structure according to the present application;
- FIGS. 11-14 are stylized, cross-sectional views of the core-stiffened structure of FIG. 3 depicting a third illustrative embodiment of a method for making a core-stiffened structure according to the present application;
- FIG. 15 is a stylized, side, elevational view of a core-stiffened structure according to and alternative embodiment of the present application.
- FIGS. 16 and 17 are stylized, cross-sectional views of the core-stiffened structure of FIG. 3 depicting a fourth illustrative embodiment of a method for making a core-stiffened structure according to the present application.
- FIG. 18 is a stylized, cross-sectional view of the core-stiffened structure of FIG. 3 depicting another illustrative embodiment of a method for making a core-stiffened structure according to the present application.
- the method includes the steps of providing a honeycomb core having an adhesive disposed on first and second surfaces thereof, providing a first skin and a second skin, and assembling the first skin, the second skin, and the honeycomb core to form the core-stiffened structure.
- the method further includes the steps of curing the core-stiffened structure and inhibiting at least one of the first skin and the second skin from protruding into at least one cell of the honeycomb core during the step of curing the composite structure.
- the present application provides a core-stiffened structure, including a honeycomb core having first and second surfaces, a first stabilization skin adhesively bonded to the first surface of the core, and in some embodiments, a second stabilization skin adhesively bonded to the second surface of the core.
- the core-stiffened structure further includes a first skin adhesively bonded to the first stabilization skin a second skin adhesively bonded to the first skin and the second stabilization skin, when the second stabilization skin is used.
- a core-stiffened structure assembly in yet another aspect of the present application, includes a honeycomb core having a first surface and a second surface and defining a plurality of cells and passages extending between the plurality of cells and a first skin disposed on the first surface of the honeycomb core.
- the core-stiffened structure assembly further includes a second skin disposed on the second surface of the honeycomb core and a soluble plug disposed in at least one of the plurality of cells .for inhibiting the first skin and the second skin from protruding into the at least one of the plurality of cells during curing of the core-stiffened structure assembly.
- a core-stiffened structure assembly in another aspect of the present application, includes a honeycomb core having a first surface and a second surface and defining a plurality of cells and passages extending between the plurality of cells and a first skin disposed on the first surface of the honeycomb core.
- the core-stiffened structure assembly further includes a second skin disposed on the second surface of the honeycomb core.
- a plug that can be dissolved by chemical reaction is disposed in at least one of the plurality of cells for inhibiting at least one of the first skin and the second skin from protruding into the at least one of the plurality of cells during curing of the core-stiffened structure assembly.
- the present application provides a core-stiffened structure assembly.
- the core-stiffened structure assembly includes a honeycomb core having a first surface and a second surface and defining a plurality of cells and passages extending between the plurality of cells and a first skin disposed on the first surface of the honeycomb core.
- the core-stiffened structure assembly further includes a second skin disposed on the second surface of the honeycomb core and a thermoplastic plug disposed in at least one of the plurality of cells for inhibiting the first skin and the second skin from protruding into the at least one of the plurality of cells during curing of the core-stiffened structure assembly.
- a core-stiffened structure assembly in yet another aspect of the present application, includes a honeycomb core having a first surface and a second surface and defining a plurality of cells and passages extending between the plurality of cells and a first skin disposed on the first surface of the honeycomb core.
- the core-stiffened structure assembly further includes a second skin disposed on the second surface of the honeycomb core and one of a magnetorheological fluid and a ferrofluid, disposed in at least one of the plurality of cells for inhibiting at least one of the first skin and the second skin from protruding into the at least one of the plurality of cells during curing of the composite assembly.
- a core-stiffened structure assembly in another aspect of the present application, includes a core, or optionally an insert having a geometry corresponding to a honeycomb core, a first skin, and a first release film disposed between the first skin and the insert or core.
- the core-stiffened structure assembly further includes a second skin and a second release film disposed between the second skin and the insert or core and between the second skin and the first skin.
- a core-stiffened structure assembly in another aspect of the present application, includes honeycomb core having a first surface and a second surface and defining a plurality of cells and a first skin disposed on the first surface of the honeycomb core and a second skin disposed on the second surface.
- the first and second skin are not sealed together, instead, either the first or second skin terminates at the edge of the honeycomb core. Any moisture can drain or dry out through venting of the edges or through the skin, if the skin is breathable.
- the skin that terminates at the edge of the honeycomb core is tailored to prevent overloading of the core material near the core termination edge by progressively dropping off plies in the skin before reaching the edge.
- the present application provides significant advantages, including: (1) providing a means for utilizing a large-celled honeycomb core in core-stiffened sandwich structures; (2) providing a means for inhibiting face sheets or skins from protruding into cells of a honeycomb core during curing of a core-stiffened sandwich structure; (3) reducing the tendency of lateral movement of honeycomb core during manufacture; and (4) simplifying edge details in some embodiments of the core-stiffened structures.
- honeycomb core means a core material comprising a plurality of interconnected cell walls that define a plurality of cells. While many honeycomb core materials define hexagonal cells, the scope of the present application encompasses core materials that define cells of other shapes, such as square, rectangular, and the like. It should be appreciated that honeycomb can be of a variety of materials, including but not limited to, composite materials and metals. Core can be of any shape and can attach to adjacent skins at angles ranging from perpendicular to parallel. Moreover, the term “large-celled honeycomb core” means, for the purposes of this disclosure, honeycomb core defining cells having a width dimension of more than about 6 mm.
- FIG. 3 depicts an illustrative embodiment of one particular core-stiffened structure 301 according to the present application.
- Core-stiffened structure 301 comprises an inner skin 303 , an outer skin 305 , and a honeycomb core 401 (shown in FIG. 4 ) disposed between and adhesively bonded to inner skin 303 and outer skin 305 .
- inner skin 303 and outer skin 305 preferably comprise a plurality of reinforcing fibers disposed in a polymeric matrix.
- honeycomb core 401 comprises a plurality of cells 403 (only one labeled for clarity) defined by a plurality of interconnected cell walls 405 (only one labeled for clarity).
- the present application is particularly useful when using honeycomb core 401 having cells 403 that exhibit a width W that is greater than about 6 mm.
- FIG. 5 depicts a first illustrative embodiment of a method for making core-stiffened structure 301 according to the present application.
- an inner stabilization skin 501 is placed against an inner side 503 of honeycomb core 401 and a lower stabilization skin 505 is placed against an outer side 507 of honeycomb core 401 .
- only one stabilization skin may be required.
- outer skin 305 is thick enough, then lower stabilization skin 505 is not required to prevent outer skin 305 from deforming into cells 403 of honeycomb core 401 .
- an adhesive (not shown in FIG. 5 ) is applied to inner surface 503 of honeycomb core 401 and to outer surface 507 of honeycomb core 401 .
- the adhesive is applied in a reticulating process, resulting in adhesive 601 substantially covering cell walls 405 at inner surface 503 and outer surface 507 of honeycomb core 401 , as shown in FIG. 6 .
- the adhesive such as adhesive 601 , bonds inner stabilization skin 501 and outer stabilization skin 505 to honeycomb core 401 .
- inner stabilization skin 501 and outer stabilization skin 503 are very thin, such as one or two plies of fiber-reinforced composite material.
- Stabilization skins 501 and 503 may be perforated, porous, or substantially solid without passages extending therethrough.
- inner stabilization skin 501 and outer stabilization skin 505 may be substantially fully “cured,” i.e., the polymeric matrix is substantially fully cross-linked, if the polymeric matrix comprises a thermosetting polymer, or the polymeric matrix is in a hardened state, if the polymeric matrix comprises a thermoplastic polymer.
- inner stabilization skin 501 and outer stabilization skin 505 may be only cured to an extent such that inner stabilization skin 501 and outer stabilization skin 505 do not substantially deform into cells 403 of honeycomb core 401 during processing.
- adhesive may not be required between inner stabilization skin 501 and inner skin 303 , as well as between outer stabilization skin and outer skin 305 .
- outer skin 305 is placed in contact with outer stabilization skin 505 and inner skin 303 is placed in contact with inner stabilization skin 501 .
- inner skin 303 contacts outer skin 305 in areas where inner skin 303 does not contact inner stabilization skin 501 and outer skin 305 does not contact outer stabilization skin 505 .
- Adhesive may be used between inner stabilization skin 501 and inner skin 303 , as well as between outer stabilization skin 505 and outer skin 305 .
- outer skin 305 is first placed onto a mold or tool 701 (shown in FIG. 7 ). It should be noted, however, that one or more other plies or layers, such as a breather ply, may be disposed between outer skin 305 and tool 701 .
- Outer stabilization skin 505 is then located on and placed onto outer skin 305 .
- Honeycomb core 401 with adhesive applied to inner surface 503 and outer surface 507 of honeycomb core 401 , is then placed onto outer stabilization skin 505 , such that outer surface 507 is adjacent outer stabilization skin 505 .
- Inner stabilization skin 501 is then placed onto honeycomb core 401 , such that inner surface 501 of honeycomb core 401 is adjacent inner stabilization skin 501 .
- Inner skin 303 is then placed on inner stabilization skin 501 , extending onto outer skin 305 .
- FIG. 7 depicts assembled core-stiffened structure 301 on tool 701 .
- Bagging material 703 extends over core-stiffened structure 301 and onto tool 701 .
- a vacuum is generated between bagging material 703 and tool 701 during processing or curing to consolidate components of core-stiffened structure 301 and to extract gases from core-stiffened structure 301 during processing.
- Core-stiffened structure 301 is then processed or cured using heat and, preferably, pressure, to form a consolidated core-stiffened structure 301 .
- stabilization skins 501 and 505 are depicted as extending only to the edges of honeycomb core 401 , the scope of the present application is not so limited. Rather, as inner stabilization skin 501 and/or outer stabilization skin 505 may, in certain embodiments, extend beyond the edges of honeycomb core 401 .
- FIGS. 8-10 depict a second illustrative embodiment of a method for making core-stiffened structure 301 according to the present application.
- cell walls 405 of honeycomb core 401 define openings 801 extending between cells 403 .
- a support plug 803 is placed in each of the plurality of cells 403 .
- Adhesive 601 is depicted in reticulated form so as to provide a fillet of adhesive between inner surface 503 and inner skin 303 , and between outer surface 507 and outer skin 305 .
- Plugs 803 extend from inner surface 503 to outer surface 507 of honeycomb core 401 .
- Plugs 803 support inner skin 303 and outer skin 305 in areas between cell walls 405 , thus inhibiting inner skin 303 and outer skin 305 from protruding into cells 403 during processing or curing. It is preferred that plugs 803 are configured so as to be removable after processing or curing; however, plugs 803 may also be permanent and reside within core 401 during the life of core-stiffened structure 301 .
- Openings 801 are to introduce fluid flow within core 401 .
- the fluid flow could be gas or liquid.
- Flow through core 401 can be utilized to introduce heat for manufacturing purposes, to utilize the volume contained in the core to store a liquid such as fuel, or to introduce a washout fluid to dissolve or chemically react to the solid material of plugs 803 .
- flow through core may be used to transfer heat in order to provide ice prevention.
- flow through core may be used to transfer heat in order to change heat signature during service of structure 301 .
- Flow through the core may also be used for pressure relief for a gradient, or to build up pressure in the volume within core 401 .
- openings through at least one of the inner skin 303 or outer skin 305 provide fluid flow, in lieu of or in addition to, openings 801 through core 401 .
- plugs 803 comprise a soluble material.
- a solvent such as water
- plugs 803 may comprise, for example, a eutectic salt, sodium silicate-bonded sand, polyvinyl alcohol-bonded ceramic microspheres, or the like.
- plugs 803 may comprise a thermoplastic material that is melted and evacuated from honeycomb core 401 via openings 801 .
- plugs 803 may comprise a magnetorheological fluid, a ferrofluid, Or the like, which become solid or semi-solid in the presence of a magnetic field and which become liquid when the magnetic field is removed.
- plugs 803 may comprise a clay, such as bentonite, which is removed from honeycomb core 401 via openings 801 by vibrating core-stiffened structure 301 .
- plugs 803 may take on the form of a plurality of beads disposed in each of the plurality of cells 403 , such that the beads are small enough to pass through openings 801 after core-stiffened structure 301 is processed or cured.
- plugs 803 may be configured to be physically compromised through a chemical reaction, and thus evacuated from core 401 in a solid, liquid, or gaseous state. It is preferred that plugs 803 are configured so as to be removable after processing or curing; however, plugs 803 may also be permanent and reside within core 401 during the life of core-stiffened structure 301 .
- plugs 803 are illustrated in FIGS. 8 and 9 as substantially filling cells 403 of honeycomb core 401 , the scope of the present application is not so limited. Rather, plugs 803 may not fully extend between cell walls 405 , as long as sufficient support is provided to inner skin 303 and outer skin 305 to inhibit inner skin 303 and outer skin 305 from protruding into cells 403 of honeycomb core 401 during processing or curing.
- plugs 803 may exhibit a plurality of legs extending from a central focal point or line.
- plugs 803 not only exhibit strength to prevent skins from compressing, but also exhibit strength in the lateral direction to prevent lateral deformation of core 401 during processing.
- Plugs 803 may also exhibit opposing caps supported by an thin axial member such that the caps provide maximum support of inner skin 303 and outer skin 305 while the thin axial member.
- a gap between the caps and the cell walls of core 401 allow space for fillets of adhesive between skins 303 and 305 and core 401 .
- FIGS. 11-14 depict a third illustrative embodiment of a method for making core-stiffened structure 301 .
- processing or curing of core-stiffened structure 301 is accomplished in two steps.
- an insert 1101 corresponding to the geometry of honeycomb core 401 (best shown in FIG. 13 ) is placed between inner skin 303 and outer skin 305 .
- An inner release film 1103 is disposed between insert 1101 and inner skin 303 and an outer release film 1105 is disposed between insert 1101 and outer skin 305 .
- Release film 1103 and 1105 comprise, in one embodiment, “peel-ply” material.
- bagging material 1201 is placed over inner skin 303 , extending onto tool 701 .
- Inner skin 303 and outer skin 305 are then at least partially cured or processed to achieve at least a semi-rigid state.
- FIG. 14 depicts core-stiffened structure 301 assembled and ready for curing or processing, with a bagging material 1401 extending over inner skin 303 and onto tool 701 .
- Core-stiffened structure 301 is then processed, preferably with heat and, in some situations pressure, to adhesively bond inner skin 303 to outer skin 305 and honeycomb core 401 and to adhesively bond outer skin 305 to honeycomb core 401 .
- FIG. 15 depicts another illustrative embodiment of one particular core-stiffened structure 301 according to the present application.
- Core-stiffened structure 301 comprises an inner skin 303 , an outer skin 305 , and a honeycomb core 401 (shown in FIG. 4 ) disposed between and adhesively bonded to inner skin 303 and outer skin 305 .
- inner skin 303 and outer skin 305 preferably comprise a plurality of reinforcing fibers disposed in a polymeric matrix.
- honeycomb core 401 comprises a plurality of cells 403 (only one labeled for clarity) defined by a plurality of interconnected cell walls 405 (only one labeled for clarity).
- Inner skin 303 and outer skin 305 are not sealed together; instead, inner skin 303 terminates at a peripheral edge 1503 of the honeycomb core 401 . Any moisture can drain or dry out through peripheral edge 1503 of the honeycomb core 401 . If either inner skin 303 or outer skin 305 is breathable, then moisture within honeycomb core 401 can also drain or dry out through breathable skin 303 or 305 .
- inner skin 303 does not abruptly terminate at peripheral edge 1503 of the honeycomb core 401 ; instead inner skin 303 steps down via steps 1501 by progressively dropping off at least one ply in inner skin 303 before reaching peripheral edge 1503 .
- the progressive dropping off in plies of inner skin 303 is tailored to prevent overloading of the honeycomb core 401 near the core peripheral edge 1503 . It should be appreciated that the dropping of plies is exemplified in steps 1501 shown in FIG. 15 ; however, steps 1501 may take on a wide variety of configurations depending upon the thickness of inner skin 1501 as well as the predicted loading of core-stiffened structure 301 .
- Core-stiffened structure 301 illustrated in FIG. 15 can be manufactured by the methods of manufacture disclosed herein. However, because core 401 is left exposed about peripheral edge 1503 , the method of manufacture illustrated in FIGS. 8-10 is particularly well suited for manufacturing the embodiment of core-stiffened structure 301 shown in FIG. 15 .
- the embodiment shown in FIG. 15 is configured to survive in high strain environment while being extremely light due to the lack of ramps between inner skin 303 and outer skin 305 .
- FIGS. 16 and 17 depict another illustrative embodiment method for making core-stiffened structure 301 according to the present application.
- processing or curing of core-stiffened structure 301 is preferably accomplished using out-of-autoclave materials that do not require an autoclave to provide high temperature and pressure.
- the illustrated embodiment involves two primary steps. In the first step, inner skin 303 is laid against a caul 1601 and sealed thereto with bagging material 1201 A. Similarly, outer skin 305 is laid against tool 701 and sealed thereto with bagging material 1201 B.
- Honeycomb core 401 which is to be used in core-stiffened structure 301 is sandwiched between bagging materials 1201 A and 1201 B.
- a subsequent bagging material 1201 C is placed in sealing contact with tool 701 so as to enclose caul 1601 , inner skin 303 , core 401 , and outer skin 305 .
- tool 701 is completely enclosed by bagging material 1201 .
- bagging material 1201 C is omitted while pressure from caul 1601 is used to provide pressure between inner skin 303 , core 401 , and outer skin 305 .
- Inner skin 303 and outer skin 305 are allowed to cure while a separate vacuum is pulled on inner skin 303 , outer skin 305 , and on the assembly via bagging materials 1201 A, 1201 B, and 1201 C.
- inner skin 303 and outer skin 305 prevents inner skin 303 and outer skin 305 from sagging and deforming into the cells of core 401 .
- any physical deformations in core 401 are transposed into inner skin 303 and outer skin 305 which provides for improved structural characteristics within core-stiffened structure 301 .
- core is not bonded to inner skin 301 and outer skin 305 due to lack of adhesive and the barrier provided by bagging material 1201 A and 1201 B.
- the second step involves bonding core 401 to inner skin 303 and outer skin 305 .
- Bagging materials 1201 A and 1201 B are removed.
- adhesive 601 is applied to core 401 , preferably through a reticulating process. Adhesive may also be applied directly between inner skin 303 and outer skin 305 .
- bagging material 1201 is preferably used to apply pressure to the final curing step for core-stiffened structure 301 .
- caul 1601 may be used in lieu of, or in addition to, bagging material 1201 .
- the embodiment of core-stiffened structure 301 shown in FIG. 15 may also be manufactured using the method disclosed herein regarding FIGS. 16 and 17 .
- FIG. 18 depicts another illustrative embodiment method for making core-stiffened structure 301 according to the present application.
- processing or curing of core-stiffened structure 301 is preferably accomplished using out-of-autoclave materials that do not require an autoclave to provide high temperature and pressure.
- Outer skin 305 is placed against tool 701 .
- Core 401 is placed against outer skin.
- Adhesive is used to bond inner skin 303 and outer skin 305 to core 401 .
- Cells 403 within core 401 are substantially filled with a plurality of flexible spherical balls, the spherical balls being filled with a gas.
- Inner skin 303 is placed against core 401 .
- Bagging material 1201 is used to create a vacuum seal between the assembly and tool 701 .
- Core 401 , spherical balls, inner skin 303 and outer skin 305 are subjected to vacuum and heat, thereby causing the spherical balls to expand, thereby preventing inner skin 303 and outer skin 305 from sagging into cells 403 of core 401 .
- temperature and pressure are decreased, thereby causing the volume of the spherical balls to decrease. It is then preferred that the spherical balls are shaken out of core 401 through openings in cell walls of core 401 .
- Spherical balls may also be removed by other means, such as being dissolved by water.
- a foam is applied into cells 403 in lieu of the spherical balls.
- the foam expands, similar to the spherical balls, when exposed to at least one of vacuum and heat in order to prevent inner skin 303 and outer skin 305 from sagging or deforming in core 401 during curing.
- honeycomb core materials While the methods disclosed herein are useful in making composite structures comprising conventional honeycomb core materials, they are particularly useful in making composite structures that include honeycomb core comprising reinforcing fibers disposed in a polymeric matrix.
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Abstract
Description
- This application is a divisional of U.S. patent application Ser. No. 15/050,564, filed 23 Feb. 2016, titled “Method of Making Core-Stiffened Structure,” which is a divisional of U.S. patent application Ser. No. 13/521,367, filed 10 Jul. 2012, titled “Method of Making Core-Stiffened Structure,” both of which are incorporated herein for all purposes.
- The present application relates in general to the field of core-stiffened structures.
- Composite structures often comprise honeycomb core disposed between and adhesively bonded to an inner skin and an outer skin. One example of such honeycomb core is a
honeycomb core 101, shown inFIG. 1 . Generally, honeycombcore 101 includes a plurality of cells 103 (only one labeled for clarity) defined by cell walls 105 (only one labeled for clarity). Each of the plurality ofcells 103 exhibits a width W. Typically, the plurality ofcells 103 have substantially the same width W but, in some implementations, somecells 103 of the plurality ofcells 103 may have different widths W thanother cells 103 of the plurality ofcells 103. - Traditionally, core-stiffened structures have been limited to the use of
honeycomb core 101 having cell widths W of less than about 6 mm. At larger widths W, as shown inFIG. 2 ,cell walls 105 fail to provide sufficient support forinner skin 201 andouter skin 203 during “curing” of the core-stiffened part, which entails heating the assembled core-stiffened part under pressure. As a result, portions ofinner skin 201 and portions ofouter skin 203 undesirably extend intocells 103 ofhoneycomb core 101. Thus, while core-stiffened structures made from larger-celled honeycomb core 101 weigh less than similar structures made from small-celled honeycomb core 101, the manufacture of large-celled composite structures has been limited. - Traditionally, core-stiffened composite structure has been sealed from intrusion of moisture. Some typical core materials are subject to moisture absorption or corrosion resulting from trapped moisture within the core. The sealing of the core edges is done by ramping one skin along a bevel in the core until both skins contact each other and complete a seal around the periphery of the core. During the cure cycle, the pressure on the ramp surface of the core may push the core in a direction lateral to the tool. In order to prevent such a distortion of the core, typically material is added to the skin in the proximity of the ramp in order to stabilize the skins from lateral distortion of the core during the cure cycle. As such, the skin is thicker than the structural application requires so as to prevent lateral distortion of the core during the cure cycle.
- A similar situation exists for core stiffened composite structure where one skin is not parallel to the other skin. Such a scenario includes the risk of the core material being pushed laterally along the tool surface. In order to prevent such a distortion of the core material, additional material is added to the core material and/or to the skins in order to resist the lateral force, and therefore resist core distortion.
- There are many methods for processing honeycomb core composite structures well known in the art; however, considerable room for improvement remains.
- The novel features believed characteristic of the application are set forth in the appended claims. However, the application itself, as well as a preferred mode of use, and further objectives and advantages thereof, will best be understood by reference to the following detailed description when read in conjunction with the accompanying drawings, in which the leftmost significant digit(s) in the reference numerals denote(s) the first figure in which the respective reference numerals appear, wherein:
-
FIG. 1 is a stylized, plan view of a portion of a conventional honeycomb core; -
FIG. 2 is a stylized, cross-sectional view of a portion of a conventional, core-stiffened structure utilizing large-celled honeycomb core; -
FIG. 3 is a stylized, side, elevational view of a core-stiffened structure according to the present application; -
FIG. 4 is a stylized, cross-sectional view of a portion of honeycomb core used in the core-stiffened structure ofFIG. 3 , taken along the line 4-4 inFIG. 3 ; -
FIG. 5 , is a stylized, exploded, cross-sectional view of a first embodiment of the core-stiffened structure ofFIG. 3 ; -
FIG. 6 is a stylized, plan view of a portion of the honeycomb core ofFIG. 4 with adhesive applied to a surface thereof; -
FIG. 7 is a stylized, cross-sectional view of the core-stiffened structure ofFIG. 5 in a configuration ready for curing or processing; -
FIGS. 8-10 are stylized, cross-sectional views of the core-stiffened structure ofFIG. 3 depicting a second illustrative embodiment of a method for making a core-stiffened structure according to the present application; -
FIGS. 11-14 are stylized, cross-sectional views of the core-stiffened structure ofFIG. 3 depicting a third illustrative embodiment of a method for making a core-stiffened structure according to the present application; -
FIG. 15 is a stylized, side, elevational view of a core-stiffened structure according to and alternative embodiment of the present application; -
FIGS. 16 and 17 are stylized, cross-sectional views of the core-stiffened structure ofFIG. 3 depicting a fourth illustrative embodiment of a method for making a core-stiffened structure according to the present application; and -
FIG. 18 is a stylized, cross-sectional view of the core-stiffened structure ofFIG. 3 depicting another illustrative embodiment of a method for making a core-stiffened structure according to the present application. - While the application is susceptible to various modifications and alternative forms, specific embodiments thereof have been shown by way of example in the drawings and are herein described in detail. It should be understood, however, that the description herein of specific embodiments is not intended to limit the application to the particular forms disclosed, but on the contrary, the application is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the application as defined by the appended claims.
- Illustrative embodiments of the present application are described below. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation-specific decisions must be made to achieve the developer's specific goals, such as compliance with system-related and business-related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort might be complex and time-consuming but would nevertheless be a routine undertaking for those of ordinary skill in the art having the benefit of this disclosure.
- In the specification, reference may be made to the spatial relationships between various components and to the spatial orientation of various aspects of components as the devices are depicted in the attached drawings. However, as will be recognized by those skilled in the art after a complete reading of the present application, the devices, members, apparatuses, etc. described herein may be positioned in any desired orientation. Thus, the use of terms such as “above,” “below,” “upper,” “lower,” or other like terms to describe a spatial relationship between various components or to describe the spatial orientation of aspects of such components should be understood to describe a relative relationship between the components or a spatial orientation of aspects of such components, respectively, as the device described herein may be oriented in any desired direction.
- There is a need for an improved method for processing a honeycomb core-stiffened structure and the core-stiffened structure thereof. Therefore, it is an object of the present application to provide an improved method for processing a honeycomb core-stiffened structure and a core-stiffened structure thereof.
- This and other objects are achieved by providing a method of making a core-stiffened structure. The method includes the steps of providing a honeycomb core having an adhesive disposed on first and second surfaces thereof, providing a first skin and a second skin, and assembling the first skin, the second skin, and the honeycomb core to form the core-stiffened structure. The method further includes the steps of curing the core-stiffened structure and inhibiting at least one of the first skin and the second skin from protruding into at least one cell of the honeycomb core during the step of curing the composite structure.
- In another aspect, the present application provides a core-stiffened structure, including a honeycomb core having first and second surfaces, a first stabilization skin adhesively bonded to the first surface of the core, and in some embodiments, a second stabilization skin adhesively bonded to the second surface of the core. The core-stiffened structure further includes a first skin adhesively bonded to the first stabilization skin a second skin adhesively bonded to the first skin and the second stabilization skin, when the second stabilization skin is used.
- In yet another aspect of the present application, a core-stiffened structure assembly is provided. The structure assembly includes a honeycomb core having a first surface and a second surface and defining a plurality of cells and passages extending between the plurality of cells and a first skin disposed on the first surface of the honeycomb core. The core-stiffened structure assembly further includes a second skin disposed on the second surface of the honeycomb core and a soluble plug disposed in at least one of the plurality of cells .for inhibiting the first skin and the second skin from protruding into the at least one of the plurality of cells during curing of the core-stiffened structure assembly.
- In another aspect of the present application, a core-stiffened structure assembly is provided. The core-stiffened structure assembly includes a honeycomb core having a first surface and a second surface and defining a plurality of cells and passages extending between the plurality of cells and a first skin disposed on the first surface of the honeycomb core. The core-stiffened structure assembly further includes a second skin disposed on the second surface of the honeycomb core. Further, a plug that can be dissolved by chemical reaction is disposed in at least one of the plurality of cells for inhibiting at least one of the first skin and the second skin from protruding into the at least one of the plurality of cells during curing of the core-stiffened structure assembly.
- In another aspect, the present application provides a core-stiffened structure assembly. The core-stiffened structure assembly includes a honeycomb core having a first surface and a second surface and defining a plurality of cells and passages extending between the plurality of cells and a first skin disposed on the first surface of the honeycomb core. The core-stiffened structure assembly further includes a second skin disposed on the second surface of the honeycomb core and a thermoplastic plug disposed in at least one of the plurality of cells for inhibiting the first skin and the second skin from protruding into the at least one of the plurality of cells during curing of the core-stiffened structure assembly.
- In yet another aspect of the present application, a core-stiffened structure assembly is provided. The core-stiffened structure assembly includes a honeycomb core having a first surface and a second surface and defining a plurality of cells and passages extending between the plurality of cells and a first skin disposed on the first surface of the honeycomb core. The core-stiffened structure assembly further includes a second skin disposed on the second surface of the honeycomb core and one of a magnetorheological fluid and a ferrofluid, disposed in at least one of the plurality of cells for inhibiting at least one of the first skin and the second skin from protruding into the at least one of the plurality of cells during curing of the composite assembly.
- In another aspect of the present application, a core-stiffened structure assembly is provided. The core-stiffened structure assembly includes a core, or optionally an insert having a geometry corresponding to a honeycomb core, a first skin, and a first release film disposed between the first skin and the insert or core. The core-stiffened structure assembly further includes a second skin and a second release film disposed between the second skin and the insert or core and between the second skin and the first skin.
- In another aspect of the present application, a core-stiffened structure assembly is provided. The core-stiffened structure assembly includes honeycomb core having a first surface and a second surface and defining a plurality of cells and a first skin disposed on the first surface of the honeycomb core and a second skin disposed on the second surface. The first and second skin are not sealed together, instead, either the first or second skin terminates at the edge of the honeycomb core. Any moisture can drain or dry out through venting of the edges or through the skin, if the skin is breathable. The skin that terminates at the edge of the honeycomb core is tailored to prevent overloading of the core material near the core termination edge by progressively dropping off plies in the skin before reaching the edge.
- The present application provides significant advantages, including: (1) providing a means for utilizing a large-celled honeycomb core in core-stiffened sandwich structures; (2) providing a means for inhibiting face sheets or skins from protruding into cells of a honeycomb core during curing of a core-stiffened sandwich structure; (3) reducing the tendency of lateral movement of honeycomb core during manufacture; and (4) simplifying edge details in some embodiments of the core-stiffened structures.
- The present application represents a method of making honeycomb core-stiffened composite structures comprising large-celled hoheycomb core. For the purposes of this disclosure, the term “honeycomb core” means a core material comprising a plurality of interconnected cell walls that define a plurality of cells. While many honeycomb core materials define hexagonal cells, the scope of the present application encompasses core materials that define cells of other shapes, such as square, rectangular, and the like. It should be appreciated that honeycomb can be of a variety of materials, including but not limited to, composite materials and metals. Core can be of any shape and can attach to adjacent skins at angles ranging from perpendicular to parallel. Moreover, the term “large-celled honeycomb core” means, for the purposes of this disclosure, honeycomb core defining cells having a width dimension of more than about 6 mm.
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FIG. 3 depicts an illustrative embodiment of one particular core-stiffenedstructure 301 according to the present application. Core-stiffenedstructure 301 comprises aninner skin 303, anouter skin 305, and a honeycomb core 401 (shown inFIG. 4 ) disposed between and adhesively bonded toinner skin 303 andouter skin 305. It should be noted thatinner skin 303 andouter skin 305 preferably comprise a plurality of reinforcing fibers disposed in a polymeric matrix. As shown inFIG. 4 ,honeycomb core 401 comprises a plurality of cells 403 (only one labeled for clarity) defined by a plurality of interconnected cell walls 405 (only one labeled for clarity). The present application is particularly useful when usinghoneycomb core 401 havingcells 403 that exhibit a width W that is greater than about 6 mm. -
FIG. 5 depicts a first illustrative embodiment of a method for making core-stiffenedstructure 301 according to the present application. In the illustrated embodiment, aninner stabilization skin 501 is placed against aninner side 503 ofhoneycomb core 401 and alower stabilization skin 505 is placed against anouter side 507 ofhoneycomb core 401. It should be appreciated that in some embodiments only one stabilization skin may be required. For example, ifouter skin 305 is thick enough, thenlower stabilization skin 505 is not required to preventouter skin 305 from deforming intocells 403 ofhoneycomb core 401. It should be noted that an adhesive (not shown inFIG. 5 ) is applied toinner surface 503 ofhoneycomb core 401 and toouter surface 507 ofhoneycomb core 401. Preferably, the adhesive is applied in a reticulating process, resulting in adhesive 601 substantially coveringcell walls 405 atinner surface 503 andouter surface 507 ofhoneycomb core 401, as shown inFIG. 6 . The adhesive, such asadhesive 601, bondsinner stabilization skin 501 andouter stabilization skin 505 tohoneycomb core 401. - Referring again to
FIG. 5 ,inner stabilization skin 501 andouter stabilization skin 503 are very thin, such as one or two plies of fiber-reinforced composite material. Stabilization skins 501 and 503 may be perforated, porous, or substantially solid without passages extending therethrough. It should be noted thatinner stabilization skin 501 andouter stabilization skin 505 may be substantially fully “cured,” i.e., the polymeric matrix is substantially fully cross-linked, if the polymeric matrix comprises a thermosetting polymer, or the polymeric matrix is in a hardened state, if the polymeric matrix comprises a thermoplastic polymer. Alternatively, if the polymeric matrix ofinner stabilization skin 501 andouter stabilization skin 505 is a thermosetting polymer,inner stabilization skin 501 andouter stabilization skin 505 may be only cured to an extent such thatinner stabilization skin 501 andouter stabilization skin 505 do not substantially deform intocells 403 ofhoneycomb core 401 during processing. In such an embodiment, adhesive may not be required betweeninner stabilization skin 501 andinner skin 303, as well as between outer stabilization skin andouter skin 305. - Still referring to
FIG. 5 ,outer skin 305 is placed in contact withouter stabilization skin 505 andinner skin 303 is placed in contact withinner stabilization skin 501. In the illustrated embodiment,inner skin 303 contactsouter skin 305 in areas whereinner skin 303 does not contactinner stabilization skin 501 andouter skin 305 does not contactouter stabilization skin 505. Adhesive may be used betweeninner stabilization skin 501 andinner skin 303, as well as betweenouter stabilization skin 505 andouter skin 305. - It should be noted that, in a preferred embodiment,
outer skin 305 is first placed onto a mold or tool 701 (shown inFIG. 7 ). It should be noted, however, that one or more other plies or layers, such as a breather ply, may be disposed betweenouter skin 305 andtool 701.Outer stabilization skin 505 is then located on and placed ontoouter skin 305.Honeycomb core 401, with adhesive applied toinner surface 503 andouter surface 507 ofhoneycomb core 401, is then placed ontoouter stabilization skin 505, such thatouter surface 507 is adjacentouter stabilization skin 505.Inner stabilization skin 501 is then placed ontohoneycomb core 401, such thatinner surface 501 ofhoneycomb core 401 is adjacentinner stabilization skin 501.Inner skin 303 is then placed oninner stabilization skin 501, extending ontoouter skin 305. -
FIG. 7 depicts assembled core-stiffenedstructure 301 ontool 701. Baggingmaterial 703 extends over core-stiffenedstructure 301 and ontotool 701. A vacuum is generated between baggingmaterial 703 andtool 701 during processing or curing to consolidate components of core-stiffenedstructure 301 and to extract gases from core-stiffenedstructure 301 during processing. Core-stiffenedstructure 301 is then processed or cured using heat and, preferably, pressure, to form a consolidated core-stiffenedstructure 301. - While stabilization skins 501 and 505 are depicted as extending only to the edges of
honeycomb core 401, the scope of the present application is not so limited. Rather, asinner stabilization skin 501 and/orouter stabilization skin 505 may, in certain embodiments, extend beyond the edges ofhoneycomb core 401. -
FIGS. 8-10 depict a second illustrative embodiment of a method for making core-stiffenedstructure 301 according to the present application. In the illustrated embodiment,cell walls 405 ofhoneycomb core 401 defineopenings 801 extending betweencells 403. Rather than usingstabilization skins support plug 803 is placed in each of the plurality ofcells 403.Adhesive 601 is depicted in reticulated form so as to provide a fillet of adhesive betweeninner surface 503 andinner skin 303, and betweenouter surface 507 andouter skin 305.Plugs 803 extend frominner surface 503 toouter surface 507 ofhoneycomb core 401.Plugs 803 supportinner skin 303 andouter skin 305 in areas betweencell walls 405, thus inhibitinginner skin 303 andouter skin 305 from protruding intocells 403 during processing or curing. It is preferred that plugs 803 are configured so as to be removable after processing or curing; however, plugs 803 may also be permanent and reside withincore 401 during the life of core-stiffenedstructure 301. -
Openings 801 are to introduce fluid flow withincore 401. The fluid flow could be gas or liquid. Flow throughcore 401 can be utilized to introduce heat for manufacturing purposes, to utilize the volume contained in the core to store a liquid such as fuel, or to introduce a washout fluid to dissolve or chemically react to the solid material ofplugs 803. Furthermore, flow through core may be used to transfer heat in order to provide ice prevention. In addition, flow through core may be used to transfer heat in order to change heat signature during service ofstructure 301. Flow through the core may also be used for pressure relief for a gradient, or to build up pressure in the volume withincore 401. In an alternative embodiment, openings through at least one of theinner skin 303 orouter skin 305 provide fluid flow, in lieu of or in addition to,openings 801 throughcore 401. - In one embodiment, plugs 803 comprise a soluble material. In a preferred embodiment, a solvent, such as water, is flushed through
honeycomb core 401, as indicated byarrows 901, viaopenings 801 to erode and removeplugs 803 after core-stiffenedstructure 301 has been processed or cured, as shown inFIGS. 9 and 10 . In such an embodiment, plugs 803 may comprise, for example, a eutectic salt, sodium silicate-bonded sand, polyvinyl alcohol-bonded ceramic microspheres, or the like. Alternatively, plugs 803 may comprise a thermoplastic material that is melted and evacuated fromhoneycomb core 401 viaopenings 801. In other embodiments, plugs 803 may comprise a magnetorheological fluid, a ferrofluid, Or the like, which become solid or semi-solid in the presence of a magnetic field and which become liquid when the magnetic field is removed. Alternatively, plugs 803 may comprise a clay, such as bentonite, which is removed fromhoneycomb core 401 viaopenings 801 by vibrating core-stiffenedstructure 301. Moreover, plugs 803 may take on the form of a plurality of beads disposed in each of the plurality ofcells 403, such that the beads are small enough to pass throughopenings 801 after core-stiffenedstructure 301 is processed or cured. Moreover, plugs 803 may be configured to be physically compromised through a chemical reaction, and thus evacuated fromcore 401 in a solid, liquid, or gaseous state. It is preferred that plugs 803 are configured so as to be removable after processing or curing; however, plugs 803 may also be permanent and reside withincore 401 during the life of core-stiffenedstructure 301. - While
plugs 803 are illustrated inFIGS. 8 and 9 as substantially fillingcells 403 ofhoneycomb core 401, the scope of the present application is not so limited. Rather, plugs 803 may not fully extend betweencell walls 405, as long as sufficient support is provided toinner skin 303 andouter skin 305 to inhibitinner skin 303 andouter skin 305 from protruding intocells 403 ofhoneycomb core 401 during processing or curing. For example, plugs 803 may exhibit a plurality of legs extending from a central focal point or line. Preferably, plugs 803 not only exhibit strength to prevent skins from compressing, but also exhibit strength in the lateral direction to prevent lateral deformation ofcore 401 during processing.Plugs 803 may also exhibit opposing caps supported by an thin axial member such that the caps provide maximum support ofinner skin 303 andouter skin 305 while the thin axial member. Preferably, a gap between the caps and the cell walls ofcore 401 allow space for fillets of adhesive betweenskins core 401. -
FIGS. 11-14 depict a third illustrative embodiment of a method for making core-stiffenedstructure 301. In the illustrated embodiment, processing or curing of core-stiffenedstructure 301 is accomplished in two steps. In the first step, aninsert 1101 corresponding to the geometry of honeycomb core 401 (best shown inFIG. 13 ) is placed betweeninner skin 303 andouter skin 305. Aninner release film 1103 is disposed betweeninsert 1101 andinner skin 303 and anouter release film 1105 is disposed betweeninsert 1101 andouter skin 305.Release film FIG. 12 , baggingmaterial 1201 is placed overinner skin 303, extending ontotool 701.Inner skin 303 andouter skin 305 are then at least partially cured or processed to achieve at least a semi-rigid state. - Referring now to
FIG. 13 ,inner skin 303 is separated fromouter skin 305 andinsert 1101 is replaced withhoneycomb core 401, having adhesive oninner surface 503 andouter surface 505, as discussed herein. Anadhesive layer 1301 is disposed betweeninner skin 303 andouter skin 305 in areas whereinner skin 303 andouter skin 305 abut.FIG. 14 depicts core-stiffenedstructure 301 assembled and ready for curing or processing, with abagging material 1401 extending overinner skin 303 and ontotool 701. Core-stiffenedstructure 301 is then processed, preferably with heat and, in some situations pressure, to adhesively bondinner skin 303 toouter skin 305 andhoneycomb core 401 and to adhesively bondouter skin 305 tohoneycomb core 401. -
FIG. 15 depicts another illustrative embodiment of one particular core-stiffenedstructure 301 according to the present application. Core-stiffenedstructure 301 comprises aninner skin 303, anouter skin 305, and a honeycomb core 401 (shown inFIG. 4 ) disposed between and adhesively bonded toinner skin 303 andouter skin 305. It should be noted thatinner skin 303 andouter skin 305 preferably comprise a plurality of reinforcing fibers disposed in a polymeric matrix. As shown inFIG. 4 ,honeycomb core 401 comprises a plurality of cells 403 (only one labeled for clarity) defined by a plurality of interconnected cell walls 405 (only one labeled for clarity).Inner skin 303 andouter skin 305 are not sealed together; instead,inner skin 303 terminates at aperipheral edge 1503 of thehoneycomb core 401. Any moisture can drain or dry out throughperipheral edge 1503 of thehoneycomb core 401. If eitherinner skin 303 orouter skin 305 is breathable, then moisture withinhoneycomb core 401 can also drain or dry out throughbreathable skin inner skin 303 does not abruptly terminate atperipheral edge 1503 of thehoneycomb core 401; insteadinner skin 303 steps down viasteps 1501 by progressively dropping off at least one ply ininner skin 303 before reachingperipheral edge 1503. The progressive dropping off in plies ofinner skin 303 is tailored to prevent overloading of thehoneycomb core 401 near the coreperipheral edge 1503. It should be appreciated that the dropping of plies is exemplified insteps 1501 shown inFIG. 15 ; however, steps 1501 may take on a wide variety of configurations depending upon the thickness ofinner skin 1501 as well as the predicted loading of core-stiffenedstructure 301. - Core-stiffened
structure 301 illustrated inFIG. 15 can be manufactured by the methods of manufacture disclosed herein. However, becausecore 401 is left exposed aboutperipheral edge 1503, the method of manufacture illustrated inFIGS. 8-10 is particularly well suited for manufacturing the embodiment of core-stiffenedstructure 301 shown inFIG. 15 . The embodiment shown inFIG. 15 is configured to survive in high strain environment while being extremely light due to the lack of ramps betweeninner skin 303 andouter skin 305. -
FIGS. 16 and 17 depict another illustrative embodiment method for making core-stiffenedstructure 301 according to the present application. In the illustrated embodiment, processing or curing of core-stiffenedstructure 301 is preferably accomplished using out-of-autoclave materials that do not require an autoclave to provide high temperature and pressure. The illustrated embodiment involves two primary steps. In the first step,inner skin 303 is laid against acaul 1601 and sealed thereto with baggingmaterial 1201A. Similarly,outer skin 305 is laid againsttool 701 and sealed thereto with baggingmaterial 1201B.Honeycomb core 401 which is to be used in core-stiffenedstructure 301 is sandwiched between baggingmaterials subsequent bagging material 1201C is placed in sealing contact withtool 701 so as to enclosecaul 1601,inner skin 303,core 401, andouter skin 305. In an alternative embodiment,tool 701 is completely enclosed by baggingmaterial 1201. In another alternative embodiment, baggingmaterial 1201C is omitted while pressure fromcaul 1601 is used to provide pressure betweeninner skin 303,core 401, andouter skin 305.Inner skin 303 andouter skin 305 are allowed to cure while a separate vacuum is pulled oninner skin 303,outer skin 305, and on the assembly via baggingmaterials inner skin 303 andouter skin 305 preventsinner skin 303 andouter skin 305 from sagging and deforming into the cells ofcore 401. During the curing process, any physical deformations incore 401 are transposed intoinner skin 303 andouter skin 305 which provides for improved structural characteristics within core-stiffenedstructure 301. At this point in the process, core is not bonded toinner skin 301 andouter skin 305 due to lack of adhesive and the barrier provided by baggingmaterial - The second step involves
bonding core 401 toinner skin 303 andouter skin 305. Baggingmaterials core 401, preferably through a reticulating process. Adhesive may also be applied directly betweeninner skin 303 andouter skin 305. During this second step of the process, baggingmaterial 1201 is preferably used to apply pressure to the final curing step for core-stiffenedstructure 301. However,caul 1601 may be used in lieu of, or in addition to, baggingmaterial 1201. It should be appreciated that the embodiment of core-stiffenedstructure 301 shown inFIG. 15 may also be manufactured using the method disclosed herein regardingFIGS. 16 and 17 . -
FIG. 18 depicts another illustrative embodiment method for making core-stiffenedstructure 301 according to the present application. In the illustrated embodiment, processing or curing of core-stiffenedstructure 301 is preferably accomplished using out-of-autoclave materials that do not require an autoclave to provide high temperature and pressure.Outer skin 305 is placed againsttool 701.Core 401 is placed against outer skin. Adhesive is used to bondinner skin 303 andouter skin 305 tocore 401.Cells 403 withincore 401 are substantially filled with a plurality of flexible spherical balls, the spherical balls being filled with a gas.Inner skin 303 is placed againstcore 401.Bagging material 1201 is used to create a vacuum seal between the assembly andtool 701.Core 401, spherical balls,inner skin 303 andouter skin 305 are subjected to vacuum and heat, thereby causing the spherical balls to expand, thereby preventinginner skin 303 andouter skin 305 from sagging intocells 403 ofcore 401. After curing, temperature and pressure are decreased, thereby causing the volume of the spherical balls to decrease. It is then preferred that the spherical balls are shaken out ofcore 401 through openings in cell walls ofcore 401. Spherical balls may also be removed by other means, such as being dissolved by water. In an alternative embodiment, a foam is applied intocells 403 in lieu of the spherical balls. The foam expands, similar to the spherical balls, when exposed to at least one of vacuum and heat in order to preventinner skin 303 andouter skin 305 from sagging or deforming incore 401 during curing. - While the methods disclosed herein are useful in making composite structures comprising conventional honeycomb core materials, they are particularly useful in making composite structures that include honeycomb core comprising reinforcing fibers disposed in a polymeric matrix.
- The particular embodiments disclosed above are illustrative only, as the application may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular embodiments disclosed above may be altered or modified and all such variations are considered within the scope and spirit of the application. Accordingly, the protection sought herein is as set forth in the claims below. It is apparent that an application with significant advantages has been described and illustrated. Although the present application is shown in a limited number of forms, it is not limited to just these forms, but is amenable to various changes and modifications without departing from the spirit thereof.
Claims (17)
Priority Applications (1)
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US16/533,619 US20190358946A1 (en) | 2010-02-05 | 2019-08-06 | Method of Making Core-Stiffened Structure |
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Application Number | Priority Date | Filing Date | Title |
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PCT/US2010/023357 WO2011096935A1 (en) | 2010-02-05 | 2010-02-05 | Method of making core-stiffened structure |
US201213521367A | 2012-07-10 | 2012-07-10 | |
US15/050,564 US10369772B2 (en) | 2012-07-10 | 2016-02-23 | Method of making core-stiffened structure |
US16/533,619 US20190358946A1 (en) | 2010-02-05 | 2019-08-06 | Method of Making Core-Stiffened Structure |
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DE202015008932U1 (en) * | 2015-05-26 | 2016-03-09 | Carcoustics Techconsult Gmbh | Composite material for producing a stiffening element for lightweight construction and stiffening element for lightweight construction |
US10800129B2 (en) * | 2017-01-24 | 2020-10-13 | Bell Textron Inc. | Honeycomb core sandwich panels |
US11339569B2 (en) * | 2017-04-18 | 2022-05-24 | Nexgen Composites Llc | Unitized construction panel |
FR3074088B1 (en) * | 2017-11-30 | 2021-02-12 | Safran Aircraft Engines | CASING IN REINFORCED COMPOSITE MATERIAL AND ITS MANUFACTURING PROCESS |
US10960637B2 (en) * | 2018-07-02 | 2021-03-30 | The Boeing Company | Core structures for composite panels, aircraft including the same, and related methods |
CN111969315A (en) * | 2020-08-26 | 2020-11-20 | 中国航空工业集团公司济南特种结构研究所 | Layering transition structure of five-layer structure antenna housing |
CN113725623B (en) * | 2021-08-30 | 2024-05-24 | 湖南航天环宇通信科技股份有限公司 | Antenna reflecting surface with back ribs and forming method thereof |
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US10369772B2 (en) | 2019-08-06 |
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