In vehicles having an enclosed cabin or cockpit, semi-structural panels composed of sandwich structures may be used to provide interior components such as wall surfaces, floor boards, storage compartments, etc. These panels are formed from paper glued into a honeycomb shape, and then covered with a structural and decorative skin. Additionally, panels may be formed from different materials, such as thermosetting materials and/or thermoplastic materials.
The present inventors have recognized, among other things, that problems to be solved for a process for providing a panel can include paper tearing during an expansion process, or constituent elements of a structure being damaged during a process for obtaining a desired panel shape. As will be apparent from the present disclosure, problems and/or objectives for improvement with respect to structures incorporated in the construction of semi-structural panels, as recognized herein, may include providing a foam structure having sufficient compressive strength for aerospace and automobile applications, that is resistant to moisture absorption, and that can be formed into a desired shape easily without wasting materials.
Accordingly, aspects of the present disclosure provide possible improvements to a foam structure which may address, among others, the issues identified herein. In particular, according to one aspect of the present disclosure, a foam structure formed at least from a thermoplastic material includes a first side, a second side, and a body that extends from the first side to the second side and defines a plurality of apertures. Each aperture of the plurality of apertures is respectively defined by a first wall and a second wall surrounding the first wall. Each first wall includes a reinforcement wall that is formed from the thermoplastic material and has a first compressive strength. At least a portion of each second wall is formed from the thermoplastic material and has a second compressive strength less than the first compressive strength.
Another embodiment is a structure comprising: a foam body comprising a thermoplastic foam, wherein the foam body comprises a first major surface and second major surface opposite the first major surface; wherein the first major surface and the second major surface each independently define a plurality of openings, the foam body defining channels extending partially or fully through the foam body, with each channel extending from an opening in the first major surface, an opening in the second major surface, or a pair of openings, one in the first major surface and the other in the second major surface; wherein the foam body is characterized by a compression strength; and wherein at least a portion of the channels comprise an inward-facing channel surface comprising a channel material having a compression strength greater than the foam body compression strength.
Another embodiment is a method of forming a reinforced foam structure, the method comprising: (a) forming a plurality of channels within a foam body to form a reduced-weight foam body characterized by a compressive strength, the foam body comprising a thermoplastic material and extending from a first major surface to a second major surface opposite the first major surface; wherein each channel extends partially or fully through the foam body; and wherein each channel is defined by a channel surface; and (b) reinforcing at least a portion of the channel surfaces to form a reinforced foam structure, the reinforced foam structure having a compressive strength greater than the compressive strength of the reduced-weight foam body.
Another embodiment is an article comprising the structure in any of its embodiments.
This Summary is intended to provide an overview of subject matter of the present patent application. It is not intended to provide an exclusive or exhaustive explanation of the invention. The detailed description is included to provide further information about the present patent application.
Aspects of the disclosure will now be described in detail with reference to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views, unless specified otherwise.
It is noted that as used in the specification and the appending claims the singular forms “a,” “an.” and “the” can include plural references unless the context clearly dictates otherwise.
Unless specified otherwise, the terms “substantial” or “substantially” as used herein mean “considerable in extent,” or “largely but not necessarily wholly that which is specified.”
Recitation of ranges of values herein are intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can include routines that can be performed in any order with respect to one another to perform the method unless otherwise indicated herein or otherwise clearly contradicted by context.
The pattern of apertures 100a may be arranged or configured to form a honeycomb structure (e.g. a honeycomb core). The honeycomb structure may be formed by adjacent rows and columns of hexagon shaped apertures 102. The apertures 102 can be formed in other shapes, for example circles, pentagons, squares, etc., and arranged in other uniform or non-uniform patterns, as illustrated in
The foam structure 100 can be formed from a thermoplastic material. The following applies to the foam structure 100 production without the apertures 102. A blowing agent may be fed into the primary extruder and mixed into the melt blend under high pressure and temperature. The melt blend may be fed under pressure to a secondary extruder, which can be used to cool a foam material formed therein and transport the foam material through a die to a calibrator to complete a formation of a foam structure. The die may operate at a specific temperature range and pressure range to provide the necessary melt strength and to suppress premature foaming in the die. The calibrator may control the cooling rate of the foam structure and, therefore, enable control over a thickness, width, and density. Alternately the foam structure 100 may be formed in their entirety using a low density foam bead injection process. In this aspect, the apertures 102 may be formed directly in a mold cavity by including aperture cores in a tool. The foam structure 100 may be molded flat with possible forming later or formed into a shape provided that aperture pins are retractable or in a line of draw. The apertures 102 may be formed as described above or alternatively, the mold may serve as a fixture by which the reinforcing process of forming the apertures 102 may be performed.
Formation of the foam structure 100 from the thermoplastic material may enable the foam structure 100 to be thermoformed into different shapes. Specifically, the foam structure 100 may be shaped during a thermoforming process from a flat shape, such as a sheet or board having a predetermined thickness, into an arcuate or a corner shape. In the case of the corner shape, the resulting shape may have two flat sections meeting at an angle of some degree, for example 90°, in a continuous manner to form a corner having a thickness substantially the same as the thickness of the foam structure 100 prior to the thermoforming process. According to an aspect of the present disclosure, the foam material 100, with or without the pattern of apertures 100a formed therein, may be thermoformed into a desired shape.
The thermoplastic material used to form the foam structure 100 may satisfy various Fire, Smoke, and Toxicity (FST) standards established by known authorities for structures utilized in various aerospace applications. For example, the thermoplastic material may meet FST requirements related to cladding and semi-structural components (e.g. panels) provided in an airplane or a helicopter.
The thermoplastic material used to form the foam structure 100 may include polyetherimide (PEI) resin such as ULTEM™ resins, available from SABIC. According to an aspect of the present disclosure, an embodiment of the foam structure 100 formed from polyetherimide foam, which may be created from polyetherimide resin, may be machined and thermoformed and/or used in vacuum bag/autoclave/oven and compression molding processes. Further, polyetherimide foam may have similar properties as other forms of polyetherimide composites, such as polyetherimide fiber based paper. As shown by Table 1, under certain conditions, polyetherimide fiber based paper has lower moisture content than other materials that may be used to form panels.
Thus, incorporation of ULTEM™ foam may cause the foam structure 100 to have low moisture absorption. As a result, a need for edge filling may be reduced for a panel installed in an interior structure of a plane or a helicopter, that is at least in part, constructed with the foam structure 100 formed from ULTEM™ foam. Further, a weight, overall cost, and cost of labor to install the panel in the interior structure, may be reduced. Additional advantages may include favorable dielectric, thermal, and acoustic properties, including a noise-reduction coefficient greater than 0.3.
It will be appreciated that the foam structure 100 may be formed from other types of thermoplastic materials or from combinations other types of thermoplastic materials that may include: acrylics, nylon, fluorocarbons, polyamides, polyethylenes, polyesters, polypropylenes, polycarbonates, polyurethanes, polyetheretherketones, polyphenylene sulfides (PPS), and polyetherketoneketones.
Each aperture 302 defined by a first wall 302a is surrounded by a second wall 304. Unlike the aperture walls 102a of the foam structure 100 illustrated in
The first wall 302a, the reinforcement wall 302b, and the second wall 304 may be formed from the same material, for example the same thermoplastic material. Due to the incorporation of the reinforcement wall 302b, the first wall 302a, although formed from the same thermoplastic material as the second wall 304, has a compressive strength greater than a compressive strength of the second wall 304. As such, for a respective aperture 302, a channel material of the inward-facing channel surface of the channel defined by the respective aperture 302a, has a compressive strength greater than a compressive strength of the body material of the second wall 304 of the respective aperture 302a. A height of each aperture 302 corresponds to a first dimension extending along a second direction T that is orthogonal to a plane of the first side 300b and a plane of the second side 300c. A thickness of each first wall 302a and a thickness of each second wall 304 correspond to a second dimension that extends parallel to the plane of the first side 300b and the plane of the second side 300c according to a respective shape of an aperture 302. A thickness of each first wall 302a/reinforcement wall 302b is less than a thickness of a corresponding portion of the second wall 304 for each aperture 302.
The reinforcement wall 302b may be defined as a portion of the first wall 302a that has been modified by an application of heat, or applications of heat and pressure, and has a physical structure different than the second wall 304. Accordingly, a density of the reinforcement wall 302b may be greater than a density of the second wall 304, and a permeability of the reinforcement wall 302b may be less than a permeability of the second wall 304. Each reinforcement wall 302b may be coated with a material having a permeability that is less than a permeability of a respective reinforcement wall 302b.
According to an aspect of the present disclosure, a first portion of the apertures 302 may be formed in a first a shape and a second portion of the apertures 302 may be formed in a second shape different than the first shape. The arrangement of different types of shapes of the apertures 302 may be selected and implemented in order for the reinforced foam structure 300 to provide a desired level of structural support for a particular application in which the panel 400 including the reinforced foam structure 300 is incorporated. Further, different portions of the reinforced foam structure 300 may have different heights, and the first layer of laminate 402 and the second layer of layer of laminate 402b may be configured to correspond to the different heights of the reinforced foam structure 300.
In step S604, apertures are formed in a body of the uncut and unreinforced foam structure with one or more of a water jet, a laser, a drill, a computer numerical cutting system, a punch system, or similar devices for cutting/modifying foam structures of various materials. The resulting structure is a patterned foam structure such as the foam structure 100 illustrated in
A thickness of the unreinforced version of the foam structure (i.e. a dimension in the second direction T) may optionally be modified at step S606.
In step S608, first walls of the patterned foam structure are modified to include reinforcement walls according to a reinforcing process. Thus, the patterned foam structure is converted into a reinforced foam structure such as the reinforced foam structure 300 illustrated in
In particular, step S608 may include passing a heating element, such as a heat cartridge, through each selected aperture 302. The heating element may include an outer surface that substantially corresponds to a shape defined by a respective first wall 302a (i.e. a shape of a respective aperture 302). Heat may be transmitted from the heating element to the first wall 302a, and a portion of the first wall 302a may soften or liquefy to provide a respective reinforcement wall 302b once cooled. In addition, a pressure may be applied to the first walls 302a during step S608 to modify the structure of the first walls 302a. The physical structure of the first wall 302a of each aperture 302 may be modified along the second direction T in step S608 such that the reinforcement walls 302b extend from the first side 300b to the second side 300c. It will be appreciated that the reinforcement walls 302b may extend over a distance less than a distance from the first side 300b to the second side 300c. An alternative to step S608 or an addition to step S608 may include a process to form the reinforcement walls 302b by melting with a solvent. Another alternative to step S608 or an addition to step S608 may include adding a higher density material to the inner wall with the addition of a prepolymer or tubular structure. In one aspect, heat may be applied to the first major surface and/or a second major surface of the foam structure 100 that may soften or liquefy a portion of the first major surface and/or the second major surface to provide a respective reinforcement of these surfaces once cooled. The process of heating the first major surface and/or a second major surface may increase surface density thereby increasing bonding performance to the laminate layers 402a, 402b described below.
At step S610, first and second laminate layers (402a, 402b) are attached to the reinforced foam structure 300 formed in step S608 to form a panel, such as the panel 400 illustrated in
Next, in step S612, the panel 400 formed in step S610 may be modified such that at least one portion of the panel 400 is orientated at an angle relative to another portion of the panel 400 to form a desired shape. For example, the panel 400 may be heated to a pliable forming temperature and formed into a specific shape in a mold (e.g. the panel may be thermoformed).
Aspects of a panel formed according to the component forming method 600 may overcome several disadvantages of other panels formed according to other methods and used in various applications, such as interior structures of airplanes and helicopters, for which certain FST requirements must to be met. For example, in step S608, an overall structural strength of the unreinforced foam structure is increased through a simple process that does not involve adding new materials which have different material properties. For example, by modifying the first walls 302a through a heating process, or a process that combines an application of heat and pressure to the unreinforced foam structure, the first walls 302a or portions thereof may transition to a softened or liquid state (e.g. melt), and cells forming respective structures of the first walls 302a may fuse together. Increasing a degree that cells are fused together in a portion of a foam structure formed from a thermoplastic material may decrease permeability, increase durability, and increase a stretch resistance of that portion of the foam structure.
Once a cooling process in step S608 is complete, a compressive strength of a first wall 302a of a given aperture 302, now with a reinforcement wall 302b of more densely configured thermoplastic material, will be higher than a compressive strength of a respective second wall 304 surrounding the first wall 302a. A collective increase in compressive strength of the first walls 302a provides the reinforced foam structure 300 with an overall strength that is improved from, for example, the unreinforced foam structure 100. Further, the overall structural strength of the reinforced foam structure 300 may be comparable to those of other structures that include other materials such as papers composed from aramid fibers.
Aramid-based honeycomb structures can be used to produce foam structures for panels used in applications for vehicles having an enclosed cabin or cockpit. However, panels formed predominantly from papers including aramid fibers, or other types of thermosetting materials, may pick up moisture easily, and increase in weight over time. In applications such as airplanes, an increase in weight of interior panels, and therefore an increase in the weight of an airplane, can result in an increase in fuel consumption and a reduction in fuel efficiency. Increased moisture pickup may also increase the risk of mold growing in the interior panels, which can be a health concern for travelers on the airplane.
To explain an advantage of reinforcing a foam structure according to the present disclosure, experimental data from compression testing of foam structures formed from ULTEM™ foam is presented in Table 2. Compression testing is used for screening core materials because sandwich panels may typically fail when bending due to the skin material buckling the core material. Each foam structure tested started from a sample of ULTEM™ foam having a starting density of 80 g/L or 110 g/L. Patterns of apertures that could be formed through a process including step S604, were formed in each foam structure. Once the pattern of apertures were formed in each foam structure, the foam structures having starting densities of 80 g/L and 110 g/L, had final densities of 49.77 g/L and 50.11 g/L, respectively. Some of the foam structures were reinforced, for example through a process including step S608, and thus included reinforcement walls such as the reinforcement walls 302b illustrated in
Table 3 shows the commercially available densities for SABIC ULTEM™ foam products. These foams were used to make the reduced density foam structures according the concepts of the present invention. Density values, expressed in units of kilograms per cubic meter, were determined at 23° C. according to ASTM D1622-14. Compressive strength values, expressed in units of megapascals, were determined at 23° C. according to ASTM D695-15.
Table 4 shows that the commercially available foams can be reduced in density while achieving a higher compressive strength through the reinforcing process. The foam sheets were cut using a Computer Numerical Code (CNC) type machine to ensure the placement of the channels was precisely located according to the desired preprogrammed pattern. The honeycomb pattern allows for the most efficient packing of channels.
The formula for calculating the core density of a sheet after cutting is as follows.
wherein
ρf=core density after cutting, in units of kilograms/meter3.
ρi=initial foam density, in units of kilograms/meter3,
d=cutter diameter, in meters, and
α=center-to-center distance between nearest-neighbor apertures, in meters.
After cutting, thermal energy was applied to each channel resulting in a reinforcing effect that increases the article's compressive strength. Heat was applied to the internal walls of each of the cells by a precisely positioned and timed heating element. The heating element, obtained from McMaster-Carr as item no. 8376T27, was circular in cross-section with a diameter of 3.175 millimeters (0.125 inches) and a length of 50.8 millimeters (2 inches). It had a maximum power of 100 watts, which could be attenuated. It was positioned perpendicular to the plane of the sheet directly above the center of the channel. The heating element was then inserted into the channel at 25.4 centimeters/second (10 inches/second), until the midpoint of the heating element was aligned with the centerline of the sheet. The heating element dwelled motionless in this down position for between 0.5 and 2.0 seconds, depending on the sample identity. The heating element was then retracted and repositioned above the next channel. This ensured that consistently formed reinforcements were obtained.
Table 4 summarizes characterization of reduced density foam structures and their foam precursors. In Table 4, “Initial foam density (kg/m3)” is the initial foam density in units of kilograms per cubic meter, with the initial foam being one of the Table 3 ULTEM™ Foam Grades. “Initial Aperture Diameter (m)” is the aperture (or “opening”) diameter created by the cutting tool), in units of centimeters. “Center-to-center (m)” is the center-to-center distance between an aperture and its nearest neighbors, in units of meters. “Thermal Power (Watts)” is the power of the heating element, in units of watts. “Density reduction (%)” is the difference between the initial foam density and the final bulk density (after cutting and thermal treatment) divided by the initial foam density, the difference being expressed in units of percent. And “Compressive Strength (MPa)” is the compressive strength of the reduced density, reinforced foam structure, in units of megapascals, determined at 23° C. according to ASTM D695-15.
The results in Table 4, in particular the last two rows, show that the Reduced density, reinforced foams exhibit greater compressive strength per unit density than the initial foams from which they are fabricated. That means that the present method can be used to fabric articles of equivalent compressive strength but reduced weight, or equivalent weight but increased compressive strength.
The reduced density, reinforced foam sheets summarized in Table 4 were then fabricated into sandwich structures using a variety of skin materials, but with each sandwich structure using the same skin material on opposite sides. The reduced density, reinforced foam sheets, each having a thickness of 6 millimeters (but alternative 1 to 25.4 millimeters), were laminated on each side to each of the skin materials using a thermoplastic polyester adhesive obtained as Bostik Aerospace Flame Retardant Film Grade SH4275FA-A. The adhesive had a melt temperature below the melt temperature of either the skin or the core. The thermoplastic polyester adhesive was applied at about 40 grams per square meter. Lamination was conducted in a flat plate static press, where the sandwich structure was consolidated at a temperature of 121° C. and a pressure of 69 kilopascals for about 20 minutes.
The skin material was a composite sheet composed of 67 weight percent glass fiber with a polycarbonate matrix polymer obtained as CETEX™ TC925 FST (thickness 0.5 millimeters) from TenCate.
The Long Beam Bending Test is used to quantify the allowable stress in the face skins of a sandwich panel. The following test procedure is based upon ASTM C393/C393M-16. “Standard Test Method for Core Shear Properties of Sandwich Constructions by Beam Flexure.” The specimens tested were uniformly cut to 61 by 7.6 centimeters (24 by 3 inches). The skin applied to both sides of each core was a two-layer TenCate CETEX™ TC1000 polyetherimide/glass fiber laminate.
Approximate stress values in the face skins and core of the sandwich panel are given by:
where
σ=flexural stress in the face skin, in megapascals
τ=shear stress in the core, in megapascals
P=total load, in Newtons
s=support span, in millimeters
l=load span, in millimeters
tf=skin—facing thickness, in millimeters
tc=Honeycomb thickness, in millimeters
b=specimen width, in millimeters
Results are presented in Table 5, where “Core Density (kg/m3)” is the density of the reinforced foam structure. “Flex Stress (MPa)” is the flexural stress in the whole sandwich structure, expressed in units of megapascals. “Core Shear Stress (MPa)” is the core shear stress in the whole sandwich structure, expressed in units of megapascals. “(Flex Stress)/(Core Density) (MPa·m3/kg)” is the density-normalized flexural stress in units of megapascal-meter3/kilogram. “(Core Shear Stress)/(Core Density) (MPa·m3/kg)” is the density-normalized core shear stress in units of megapascal-meter3/kilogram. The results show that the density-normalized flexural stress values and the density-normalized core shear stress values for the reduced density, reinforced foam structures with skins are not decreased compared to values corresponding unmodified foam cores.
At the same time that an overall structural strength may be increased as a result of step S608, the reinforced foam structure 300 as a one-piece structure, or the panel 400 formed at step S610 as a combined structure, may maintain various characteristics of other structures formed from thermoplastic materials. For example, the reinforced foam structure 300 and the panel 400, which each include the reinforcement walls 302b, may still be heated to a pliable forming temperature and formed into a specific shape in a mold. Accordingly, the panel 400 may be modified in step S612 to include transitions that define angles within a wide range, such as angles between 10′ and 170°. In particular, the panel 400 may be shaped to include a transition in the form of a corner that defines an angle of 90° between a first portion and a second portion of the panel 400. Due to the pliability of a thermoplastic material used in step S602, a thickness of the panel 400 for the first portion, the corner, and the second portion may be substantially constant.
From the foregoing discussion it will be appreciated that an advantage of the panel 400, as compared to a panel formed from paper composed of aramid fibers, is the panel 400 may have a comparable overall compressive strength and the apertures can be formed in any shape, while the paper based panel will be constrained to a shape dictated by a pattern of glue lines used to form a honeycomb structure. Further, the panel 400 does not have to be crushed into shape as with many thermoset materials, which involves more steps, labor, and planning than heating the panel 400 to a pliable state and molding the panel 400 to into a desired shape. For example, the panel 400 does not need to be sanded down to the extent a panel formed from thermoset material would need to be sanded. The rough nature of various thermoset materials used to form panels may require a substantial degree of labor intensive sanding, and then the panels must be sealed to prevent moisture. There is also a higher risk that constituent elements may be damaged in methods of forming components that include crushing the elements into desired shapes, than methods in which a component such as the panel 400 is shaped by a thermoforming process. Further still, some panels formed from a thermoset material, and apertures may be formed through an expansion process, not a panel in-plane expansion to create the honeycomb, and if there are any internal weak points within an original block of a honeycomb structure being expanded, tearing may occur that may propagate through the block. As a result, the entire block must be discarded.
The panel 400 may include the reinforced foam structure 300 formed from ULTEM™ foam. As previously discussed, ULTEM™ foam may absorb less moisture than other materials that may be used to form panels. Thus, the panel 400 incorporating ULTEM™ foam may absorb less moisture over time and reduce a corresponding increase in the weight over a lifecycle of the panel, than a panel formed from a different material, such as paper composed of aramid fibers or other thermoset materials. Where a panel is installed in a plane, helicopter, automobile, or other mode of transportation, an increase in weight in the panel will increase an overall weight of a respective mode of transportation in which it is installed. The increase in overall weight will in turn lead to a decrease in fuel efficiency because more power is required to move the mode of transportation. A panel formed with ULTEM™ foam according to the component forming method 600 discussed herein, may absorb less moisture and decrease a fuel efficiency of a given mode of transportation less than a panel that is not formed from an ULTEM™-based material.
In step S704, a process of forming apertures and reinforcing the uncut and unreinforced foam structure are combined. More specifically, a punch system capable of applying heat to individual apertures formed thereby may be utilized to punch through the uncut and unreinforced foam structure, and form apertures. Punching elements of the punch system may remain within respective apertures and apply heat to first walls of the respective apertures. It will be appreciated that the punching elements may also emit heat during the cutting process in which the apertures are formed. Further, a pressure may be applied within the apertures once formed and structurally modify newly formed first walls (e.g. each punching element could expand within a respective aperture). Therefore, the punch system capable of applying heat to individual apertures not only forms the apertures in the uncut and unreinforced foam structure, but additionally heats and modifies (e.g. softens or liquefies) the physical structure of the first walls to form the reinforcement walls. The first walls/reinforcement walls are then permitted to cool and solidify in step S704. Accordingly, in step S704, the uncut and unreinforced foam structure is modified and converted into the reinforced foam structure 300 having a body 300a extending from a first side 300b to a second side 300c as illustrated in
A thickness of the unreinforced version of the foam structure 300 (i.e. a dimension in the second direction T) may optionally be modified at step S706.
At step S708, first and second laminate layers are attached to the reinforced foam structure 300 formed in step S708 to form a panel, such as the panel 400 illustrated in
Next, in step S710, the panel 400 formed in step S708 may be modified such that at least one portion of the panel 400 is orientated at an angle relative to another portion of the panel 400 to form a desired shape. For example, the panel 400 may be heated to a pliable forming temperature and formed into a specific shape in a mold (e.g. the panel may be thermoformed).
The partition 1604 may be formed from a single panel (400, 1300) according to the present disclosure, and includes first partition walls 1604a that face the interior of the aircraft 1600 angled relative to one another and a second partition wall 1604b by respective partition transitions 1604c. An angle defined by the partition transition 1604c between the second partition wall 1604b and each of the first partition walls 1604a may be a right angle. In contrast, angles defined by the partition transitions 1604c between the first partition walls 1604a may range between 120° to 150° (i.e. 60° to 30° from a vertical plane of the aircraft 1600 or a plane prior to a thermoforming process of a single panel used to produce the partition 1604).
The bulkhead 1608 may be formed from a single panel (400, 1300) according to the present disclosure, and includes first, second, and third bulkhead walls (1608a, 1608b, 1608c). The first bulkhead wall 1608a may be angled relative to the second bulkhead wall 1608b by a transition 1608d defining a right angle. The third bulkhead wall 1608c may be angled relative the second bulkhead wall 1608b by another bulkhead transition 1608d defining an angle between 120° to 150° (i.e. 60° to 30° relative to a plane extending through the second bulkhead wall 1608). Any of the first, second, or third bulkhead walls (1608a. 1608b. 1608c) may include cutouts/protruding surface features 1608e that may be formed through any of component forming methods of present disclosure.
The header 16010 may be formed from a single panel (400, 1300) according to the present disclosure, and includes a first header wall 1610a angled relative to a second header wall 1610b through a header transition 1610c which defines a substantially right angle. In addition, the second header wall 1610b may have shaped therein, a curved section 1610d between flat sections of the second header wall 1610b.
The advantage of being able to bend a single panel in multiple directions, and to include sections angled relative to each other by acute, obtuse, or right-angles, is coupled with an increased structural strength provided by the reinforcing processes that form reinforcement walls within foam structures. Accordingly, components formed by the methods described therein may be easier to produce into complex structures as compared to other methods which involve crushing intermediate products formed from thermoset materials. Further, components produced according to the methods of the present disclosure from certain materials, such as PEI, may absorb less moisture over time than the components formed from thermoset materials. In addition, components formed with reinforcement walls according to the component forming methods of the present disclosure, may be stronger structurally that other components formed from thermoplastic materials.
One embodiment is a structure comprising: a foam body comprising a thermoplastic foam, wherein the foam body comprises a first major surface and second major surface opposite the first major surface; wherein the first major surface and the second major surface each independently define a plurality of openings, the foam body defining channels extending partially or fully through the foam body, with each channel extending from an opening in the first major surface, an opening in the second major surface, or a pair of openings, one in the first major surface and the other in the second major surface; wherein the foam body is characterized by a compressive strength; and wherein at least a portion of the channels comprise an inward-facing channel surface comprising a channel material having a compressive strength greater than the foam body compressive strength.
In some embodiments, the portion of the channels comprising an inward-facing channel surface comprising a channel material having a compressive strength greater than the foam body compressive strength is 50 to 100% of the total channels, or 80 to 100% of the total channels, or 90 to 100% of the total channels. In some embodiments, 100% of the total channels have a compressive strength greater than the foam body compressive strength.
In some embodiments the foam body, excepting voids, is chemically homogeneous. In this context, “voids” refers to voids in the foam, and does not include channels through the foam.
In some embodiments, the foam body defines channels extending partially through the foam body. In other embodiments, the foam body defines channels extending fully through the foam body.
In some embodiments, the thermoplastic foam comprises a thermoplastic selected from the group consisting of polyimides (including polyetherimides), acrylics, fluorocarbons, polyamides, poly(phenylene ether)s, poly(phenylene sulfide)s, polyethylenes, polypropylenes, polyesters (including poly(ethylene terephthalate)s), polycarbonates, polyurethanes, polyethersulfones, polyetherketones, polyetheretherketones, polyetherketoneketones, poly(vinyl chloride)s, and combinations thereof. In very specific embodiments, the thermoplastic foam comprises a polyetherimide.
In some embodiments, the foam body is characterized by a void content of 60 to 98.5 volume percent. It will be understood that the void content is defined by voids in the foam and does not include channels through the foam. Within the range of 60 to 98.5 volume percent, the void volume can be 65-95 volume percent, or 70-90 volume percent.
In some embodiments, the structure further comprises an adhesive layer adhered to the first major surface; and a skin layer adhered to a surface of the adhesive layer opposite the first major surface.
In some embodiments, the structure further comprises an adhesive layer adhered to the second major surface, and a skin layer adhered to a surface of the adhesive layer opposite the second major surface. In such embodiments, it is preferred that the structure's two adhesive layers have the same composition, and that the structure's two skin layers have the same composition.
Examples of suitable adhesives include those comprising thermoplastic polyesters, polyurethanes, polyetheretherketones, polyetherketoneketones, polyphenylsulfones, polycarbonates, poly(phenylene sulfide)s, polyamides, and combinations thereof. In some embodiments, the adhesive layer comprises a thermoplastic polyester.
Examples of skin layer materials include aluminum, aluminum alloys, polyetherimides, polycarbonates, polypropylenes, polyetherimide/glass fiber composites, polyetherimide/carbon fiber composites, polycarbonate/glass fiber composites, polycarbonate/carbon fiber composites, and polypropylene/glass fiber composites.
Specific examples of skin layer materials include a composite sheet composed of woven glass fiber with a polyetherimide matrix polymer; a composite sheet composed of nonwoven glass fiber with a polyetherimide matrix polymer; a composite sheet composed of carbon fiber with a polyetherimide matrix polymer. The above composite sheets can have thicknesses of 0.8 to 1.5 millimeters. Other examples of a skin material include a composite sheet composed of glass fiber with a polyetherimide matrix polymer obtained, for example, as CETEX™ TC1000 (thickness 1 or 2 millimeters) from TenCate; a composite sheet composed of glass fiber with a polycarbonate matrix polymer obtained as CETEX™ TC925 FST (thickness 0.5, 1, or 2 millimeters) from TenCate: a composite sheet composed of glass fiber with a polypropylene matrix polymer (thickness 1 or 2 millimeters); a composite sheet composed of carbon fiber with a polyetherimide matrix polymer; a composite sheet composed of carbon fiber with a polycarbmonate matrix polymer; an aluminum sheet (thickness=0.2 to 2 micrometers); polyetherimide sheets available from SABIC as ULTEM™ 1000, ULTEM™ 1010, and ULTEM™ 9011 films, having a thickness from 5 micrometers to 1 millimeter or more; polycarbonate sheets available from SABIC as LEXAN™ EXRL 2252 films having thicknesses from 10 micrometers to 1 millimeter or more; and polypropylene films having thicknesses from 10 micrometers to 1 millimeter or more. In some embodiments, the skin layer comprises a polyetherimide/glass fiber composite.
In a very specific embodiment of the structure, the thermoplastic foam comprises a polyetherimide, the foam body is characterized by a void content of 65 to 95 volume percent, the foam body further comprises an adhesive layer adhered to the first major surface, and a skin layer adhered to a surface of the adhesive layer opposite the first major surface, and the skin layer comprises a composite comprising a polyetherimide and glass fibers.
Another embodiment is a method of forming a reinforced foam structure, the method comprising: (a) forming a plurality of channels within a foam body to form a reduced-weight foam body characterized by a compressive strength, the foam body comprising a thermoplastic material and extending from a first major surface to a second major surface opposite the first major surface; wherein each channel extends partially or fully through the foam body; and wherein each channel is defined by a channel surface; and (b) reinforcing at least a portion of the channel surfaces to form a reinforced foam structure, the reinforced foam structure having a compressive strength greater than the compressive strength of the reduced-weight foam body.
In some embodiments, the portion of channel surfaces reinforced is 50 to 100 (number) percent, or 80 to 100 percent, or 90 to 100 percent. In some embodiments, 100 percent of the channel surfaces are reinforced.
In a very specific embodiment of the method, the foam body comprises a polyetherimide; the foam body is characterized by a void content of 65 to 95 volume percent; the reinforced foam structure further comprises an adhesive layer adhered to the first major surface, and a skin layer adhered to a surface of the adhesive layer opposite the first major surface; the skin layer comprises a composite comprising a polyetherimide and glass fibers; and said reinforcing at least a portion of the channel surfaces comprises passing a heating element through the channels defined by the at least a portion of the channel surfaces.
In some embodiments, the reinforced foam structure further comprises an adhesive layer adhered to the second major surface, and a skin layer adhered to a surface of the adhesive layer opposite the second major surface. In such embodiments, it is preferred that the structure's two adhesive layers have the same composition, and that the structure's two skin layers have the same composition.
Another embodiment is an article comprising the structure of any of the above-described embodiments. Examples of such articles are aviation overhead containers, aviation interior wall panels, and aviation trays.
Another embodiment is a structure comprising: a generally planar body formed at least from a thermoplastic foam, the general planar body comprising a first major surface and second major surface opposite the first major surface, with each major surface defining a plurality of openings, the generally planar body defining channels extending there through, with each channel of at least a portion of the channels extending from an opening in the first major surface to an opening in the second major surface, wherein each channel of the portion of the channels includes an inward-facing channel surface comprising a channel material of a first compressive strength, with the channel material disposed proximal to a body material of a second compressive strength that is lower than the first compressive strength.
In some embodiments of the structure, the thermoplastic foam comprises a thermoplastic selected from the group consisting of polyetherimides, acrylics, fluorocarbons, polyamides, polyethylenes, polyesters, polypropylenes, polycarbonates, polyurethanes, polyetheretherketones, polyphenylene sulfides, and polyetherketoneketones.
In some embodiments of the structure, the thermoplastic foam comprises polyetherimide.
In some embodiments of the structure, at least channels of the portion of the channels are arranged in a pattern defining a honeycomb structure.
In some embodiments of the structure, the generally planar body includes portions without the channels.
In some embodiments of the structure, a first dimension of each channel of the portion of the channels extends along a first axis that is orthogonal to a plane of the first major surface and a plane of the second major surface; a second dimension of each channel of the portion of the channels extends along a second axis that is parallel to the plane of the first major surface and the plane of the second major surface; and a second dimension of an inward-facing channel surface of at least one channel of the portion of the channels is less than a second dimension of a body material the inward-facing channel surface is disposed proximal to.
Another embodiment is a method of forming a panel, the method comprising the processes of: (a) forming a foam structure at least from a thermoplastic material with a body extending from a first side to a second side; (b) forming a plurality of apertures within the body, at least one aperture defined by a first wall surrounded by a second wall; and (c) forming at least one reinforcement wall from at least a portion of the first wall, wherein the reinforcement wall is formed from the thermoplastic material and has a first compressive strength, and wherein at least a portion of the second wall is formed from the thermoplastic material and has a second compressive strength different than the first compressive strength.
In some embodiments of the method, process (b) includes one of cutting the plurality of apertures in the body with one or more of a water jet, a laser, a drill, a computer numerical cutting system, a bead injection process and a punch system.
It will be appreciated that the present disclosure may include any one and up to all of the following examples.
A foam structure formed at least from a thermoplastic material, the foam structure comprising: a first side; a second side; and a body that extends from the first side to the second side and defines a plurality of apertures, wherein each aperture of the plurality of apertures is respectively defined by a first wall and a second wall surrounding the first wall, wherein each first wall includes a reinforcement wall that is formed from the thermoplastic material and has a first compressive strength, and wherein at least a portion of each second wall is formed from the thermoplastic material and has a second compressive strength less than the first compressive strength.
The foam structure as recited in example 1, wherein a respective reinforcement wall of each aperture of at least a portion of the plurality of apertures extends from the first side to the second side.
The foam structure as recited in example 1, wherein a respective reinforcement wall of each aperture of at least a portion of the plurality of apertures extends a distance from the first side that is less than a distance from the first side to the second side.
The foam structure as recited in example 1, wherein a plane extends through the foam structure between and parallel to the first side and the second side, wherein each reinforcement wall extends a respective first distance from the plane towards the first side that is less than a distance from the plane to the first side and extends a respective second distance from the plane towards the second side that is less than a distance from the plane to the second side.
The foam structure as recited in any one of examples 1 to 4, wherein a height of each aperture of the plurality of apertures corresponds to a first dimension extending along a first axis that is orthogonal to a plane of the first side and a plane of the second side, wherein a thickness of each first wall and a thickness of each second wall correspond to a second dimension extending along a second axis that is parallel to the plane of the first side and the plane of the second side, and wherein a thickness of the reinforcement wall is less than a thickness of the portion of the second wall for each aperture of the plurality of apertures.
The foam structure as recited in example 5, wherein each aperture of a first portion of the plurality of apertures has a first height, and wherein each aperture of a second portion of the plurality of apertures has a second height different than the first height.
The foam structure as recited in any one of examples 1 to 6, wherein the thermoplastic material is a thermoplastic foam.
The foam structure as recited in example 7, wherein the thermoplastic foam is formed from polyetherimide.
The foam structure as recited in example 7, wherein a plurality of fibers are dispersed throughout the body.
The foam structure as recited in example 9, wherein the fibers are formed from a material different from the thermoplastic material.
The foam structure as recited in any one of examples 9 and 10, further comprising: a first layer of one of a thermoset material and an adhesive material adhered to the first side of the body, and a second layer of one of the thermoset material and the adhesive material adhered to the second side of the body, wherein the one of the thermoset material and the adhesive material attach the thermoplastic foam to the plurality of fibers.
The foam structure as recited in any one of examples 1 to 11, further comprising a layer of laminate adhered to at least one of the first side and the second side of the body.
The foam structure as recited in any one of examples 1 to 11, further comprising: a first layer of laminate adhered to the first side of the body, and a second layer of laminate adhered to the second side of the body.
The foam structure as recited in any one of examples 1 to 13, wherein a density of the reinforcement wall is greater than a density of the portion of the second wall for each aperture of the plurality of apertures.
The foam structure as recited in any one of examples 1 to 14, wherein a permeability of the reinforcement wall is less than a permeability of the portion of the second wall for each aperture of the plurality of apertures.
The foam structure as recited in example 15, wherein each reinforcement wall is coated with a material having a permeability that is less than a permeability of a respective reinforcement wall.
The foam structure as recited in any one of examples 1 to 16, wherein the plurality of apertures are arranged in a pattern defining a honeycomb structure.
The foam structure as recited in example 17, wherein each aperture of the plurality of apertures is formed in a shape of one of a circle, a square, a pentagon, a hexagon, and an octagon.
The foam structure as recited in example 17, wherein each aperture of a first portion of the plurality of apertures is formed in a first shape of one of a circle, a square, a pentagon, a hexagon, and an octagon, and wherein each aperture of a second portion of the plurality of apertures is formed in a second shape different than the first shape.
A panel arrangement configured to be installed in an aircraft, the panel arrangement comprising: a first external wall; a second external wall; and a first transition structure positioned between the first external wall and the second external such that the second external wall is one of orientated at a first angle relative to the first external wall and has a thickness different from a thickness of the first external wall, wherein the first external wall, the second external wall, and the first transition structure are formed by a one-piece foam structure and at least a first layer of laminate attached to a first side of the one-piece foam structure, wherein the one-piece foam structure includes at a first internal wall and a second internal wall formed from a thermoplastic material, and wherein the first internal wall is positioned adjacent to the second internal wall and has a compressive strength different from a compressive strength of the second internal wall.
The panel arrangement as recited in example 20, wherein the second external wall is orientated by the first transition structure at the first angle relative to the first external wall, and wherein a thickness of the first external wall is equal to a thickness of the second external wall.
The panel arrangement as recited in any one of examples 21, further comprising: a third external wall; and a second transition structure positioned between the first external wall and the third external wall such that the third external wall is orientated at a second angle relative to the first internal wall, wherein the third external wall and the first transition structure are formed by the one-piece foam structure.
The panel arrangement as recited in example 22, wherein the second angle is within a range of 120° to 150°.
The panel arrangement as recited in any one of examples 22 and 23, wherein the third external wall is orientated at the first angle relative to the second internal wall.
The panel arrangement as recited in any one of examples 21 to 24, wherein the first angle is equal to 90°.
The panel arrangement as recited in any one of examples 21 to 24, wherein the first angle is within a range of 120° to 150°.
The panel arrangement as recited in any one of examples 21 to 26, wherein the first external wall includes a curved portion positioned between a first flat portion and a second flat portion, and wherein the first flat portion and the second flat portion are orientated at the first angle relative to the second external wall.
The panel arrangement as recited in any one of examples 20 to 27, wherein the thermoplastic material is a thermoplastic foam.
The panel arrangement as recited in example 28, wherein the thermoplastic foam is formed from polyetherimide.
The panel arrangement as recited in any one of examples 20 to 29, further comprising a second layer of laminate attached to a second side of the one-piece foam structure.
The panel arrangement as recited in example 28, wherein a plurality of fibers are dispersed throughout the one-piece foam structure.
The panel arrangement as recited in example 31, wherein the fibers are formed from a material different from the thermoplastic material.
The panel arrangement as recited in any one of examples 31 and 32, further comprising: a first layer of one of a thermoset material and an adhesive material adhered to the first side of the one-piece foam structure between first side and the first layer of laminate, and a second layer of one of the thermoset material and the adhesive material adhered to the second side of the body, wherein the one of the thermoset material and the adhesive material attach the thermoplastic foam to the plurality of fibers.
The panel arrangement as recited in example 33, further comprising a second layer of laminate attached to the second layer of one of the thermoset material and the adhesive material.
The panel arrangement as recited in any one of examples 20 to 35, wherein the first internal wall defines an aperture within a body of the one-piece foam structure and includes a reinforcement wall that is formed from the thermoplastic material and has a first compressive strength, and wherein the second internal wall surrounds the first internal, is formed from the thermoplastic material, and has a second compressive strength less than the first compressive strength.
The panel arrangement as recited in example 35, wherein a height of the aperture corresponds to a first dimension extending along a first axis that is orthogonal to a plane of the first side of the one-piece foam structure, wherein a thickness of the first internal wall and a thickness of the second internal wall correspond to a second dimension extending along a second axis that is parallel to the plane of the first side, and wherein the thickness of the reinforcement wall is less than the thickness of the second wall.
The panel arrangement as recited in any one of examples 35 to 36, wherein a density of the reinforcement wall is greater than a density of the second wall.
The panel arrangement as recited in any one of examples 35 to 37, wherein a permeability of the reinforcement wall is less than a permeability of the second wall.
The panel arrangement as recited in example 38, wherein the reinforcement wall is coated with a material having a permeability that is less than a permeability of the reinforcement wall.
The panel arrangement as recited in any one of examples 35 to 39, wherein the aperture is one of a plurality of apertures defined by the one-piece foam structure which are arranged in a pattern defining a honeycomb structure.
The foam structure as recited in example 40, wherein each aperture of the plurality of apertures is formed in a shape of one of a circle, a square, a pentagon, a hexagon, and an octagon.
A method of forming a panel, the method comprising processes: (a) forming a foam structure to include a body extending from a first side to a second side and formed at least from a thermoplastic material; (b) forming a plurality of apertures within the body, each aperture defined by a respective first wall surrounded by a respective second wall; and (c) forming reinforcement walls, each reinforcement wall being formed from at least a portion of a respective first wall; wherein each reinforcement wall is formed from the thermoplastic material and has a first compressive strength, and wherein at least a portion of each second wall is formed from the thermoplastic material and has a second compressive strength less than the first compressive strength.
The method of example 42, further comprising adjusting a thickness of a portion of the foam structure after process (a) and before process (c).
The method of any one of examples 42 and 43, wherein process (c) includes permanently modifying a physical structure of a first wall of each aperture of at least a portion of the plurality of apertures.
The method of any one of examples 42 to 44, wherein process (b) includes one of cutting the plurality of apertures in the body with one or more of a water jet, a laser, a drill, a computer numerical cutting system, a bead injection process and a punch system.
The method of example 45, wherein process (c) includes: (c1) passing a heating element through each aperture of the portion of the plurality of apertures such that each heating element includes an outer surface that substantially corresponds to a shape of a first wall of a respective aperture, (c2) applying heat to the first wall of each aperture with a respective heating element such that at least a portion of the first wall melts, (c3) allowing the first wall of each aperture to cool and solidify.
The method of any one of examples 42 to 44, wherein process (c) is combined with process (b) and process (b) includes: (b1) cutting the plurality of apertures in the body with a punch system and applying heat as the plurality of apertures are cut to the first wall of each aperture of the portion of the plurality of apertures such that at least a portion of the first wall melts, and (b2) allowing the first wall of each aperture to cool and solidify.
The method of any one of examples 45 to 47, wherein the physical structure of the first wall of each aperture of the portion of the plurality of apertures is modified from the first side to the second side of the foam structure.
The method of any one of examples 45 to 47, wherein a plane extends through the foam structure between and parallel to the first side and the second side, wherein the physical structure of the first wall of each aperture of the portion of the plurality of apertures is modified over a first distance from the plane towards the first side that is less than a distance from the plane to the first side and over a second distance from the plane towards the second side that is less than a distance from the plane to the second side.
The method of any one of examples 42 to 49, wherein process (b) includes forming the plurality of apertures within the body in an arrangement defining a honeycomb structure.
The method of any one of examples 42 to 50, further comprising a process (d) of attaching a first laminate layer to the first side and attaching a second laminate layer to the second side of the foam structure.
The method of any one of examples 42 to 51, wherein the thermoplastic material is a thermoplastic foam formed from polyetherimide.
The method of example 49, wherein process (a) includes punching fibers through the body of the foam structure.
The method of example 53, wherein the thermoplastic material is a thermoplastic foam formed from polyetherimide and the fibers are formed from a material different that the thermoplastic material.
The method of any one of examples 53 to 54, wherein process (b) includes forming the plurality of apertures within the body in an arrangement defining a honeycomb structure.
The method of any one of examples 53 and 55, further comprising a process (d) of consolidating the foam structure with one of a thermoset material and an adhesive and attaching the fibers to the thermoplastic foam.
The method of example 56, further comprising a process (e) of attaching the first laminate layer and the second laminate layer to the second side of the foam structure.
The method of example 51 or 57, further comprising a process following the attaching of the first laminate layer and the second laminate layer of thermoforming the panel, wherein the panel is thermoformed to include: a first external wall, a second external wall, and a first transition structure positioned between the first external wall and the second external such that the second external wall is orientated at a first angle relative to the first external wall.
The method of example 58, wherein the panel is thermoformed to include: a third external wall, and a second transition structure positioned between the first external wall and the third external wall such that the third external wall is orientated at a second angle relative to the first internal wall.
The method of example 59, wherein the second angle is within a range of 120° to 150°.
The method of any one of examples 59 and 60, wherein the third external wall is orientated at the first angle relative to the second external wall.
The method of any one of examples 59 to 61, wherein the first angle is equal to 90°.
The method of any one of examples 59 to 61, wherein the first angle is within a range of 120° to 150°.
The method of any one of examples 59 to 63, wherein the first external wall includes a curved portion positioned between a first flat portion and a second flat portion, and wherein the first flat portion and the second flat portion are orientated at the first angle relative to the second external wall.
A structure comprising: a generally planar body comprising a first major surface and second major surface opposite the first major surface, with each major surface defining a plurality of openings, the generally planar body defining channels extending there through, with each channel of at least a portion of the channels extending from an opening in the first major surface to an opening in the second major surface, wherein each channel of the portion of the channels includes an inward-facing channel surface comprised of a channel material of a first compressive strength, with the channel material disposed proximal to a body material of a second compressive strength that is lower than the first compressive strength.
The structure as recited in example 65, wherein the generally planar body is formed at least from a thermoplastic material, with the thermoplastic material being a thermoplastic foam.
The foam structure as recited in example 66, wherein a plurality of fibers are dispersed throughout the generally planar body.
The foam structure as recited in example 67, further comprising: a first layer of one of a thermoset material and an adhesive material adhered to the first major surface of the generally planar body, and a second layer of one of the thermoset material and the adhesive material adhered to the second surface of the generally planar body, wherein the one of the thermoset material and the adhesive material attach the thermoplastic foam to the plurality of fibers.
The structure as recited in any one of Examples 65 to 68, wherein a first dimension of each channel of the portion of the channels extends along a first axis that is orthogonal to a plane of the first major surface and a plane of the second major surface, wherein a second dimension of each channel of the portion of the channels extends along a second axis that is parallel to the plane of the first major surface and the plane of the second major surface, and wherein a second dimension of an inward-facing channel surface of at least one channel of the portion of the channels is less than a second dimension of a body material the inward-facing channel surface is disposed proximal to.
A panel comprising: a first external wall; a second external wall; and a first transition structure positioned between the first external wall and the second external, the second external wall extends at a first angle relative to the first external wall or a first dimension of the second external wall along a first direction is different than a first dimension of the first external wall along the first direction, wherein the first external wall, the second external wall, and the first transition structure are formed by a one-piece foam structure and at least a first layer of laminate attached to a first side of the one-piece foam structure, wherein the one-piece foam structure includes at a first internal wall and a second internal wall formed from a thermoplastic material, and wherein the first internal wall is positioned adjacent to the second internal wall and has a first compressive strength different than a second compressive strength of the second internal wall.
The panel as recited in Example 70, wherein the second external wall is orientated by the first transition structure at the first angle relative to the first external wall, and wherein the first dimension of the first external wall is equal to the first dimension of the second external wall.
The panel as recited in Example 71, wherein the first angle is equal to 90°.
A method of forming a panel, the method comprising the processes of: (a) forming a foam structure at least from a thermoplastic material with a body extending from a first side to a second side; (b) forming a plurality of apertures within the body, at least one aperture defined by a first wall surrounded by a second wall; and (c) forming at least one reinforcement wall from at least a portion of the first wall, wherein the reinforcement wall is formed from the thermoplastic material and has a first compressive strength, and wherein at least a portion of the second wall is formed from the thermoplastic material and has a second compressive strength different than the first compressive strength.
A structure comprising: a foam body comprising a thermoplastic foam, wherein the foam body comprises a first major surface and second major surface opposite the first major surface; wherein the first major surface and the second major surface each independently define a plurality of openings, the foam body defining channels extending partially or fully through the foam body, with each channel extending from an opening in the first major surface, an opening in the second major surface, or a pair of openings, one in the first major surface and the other in the second major surface; wherein the foam body is characterized by a compressive strength; and wherein at least a portion of the channels comprise an inward-facing channel surface comprising a channel material having a compressive strength greater than the foam body compressive strength.
The structure of Example 74, wherein the foam body defines channels extending partially through the foam body.
The structure of Example 74, wherein the foam body defines channels extending fully through the foam body.
The structure of any one of Examples 74-76, wherein the thermoplastic foam comprises a thermoplastic selected from the group consisting of polyimides, acrylics, fluorocarbons, polyamides, poly(phenylene ether)s, poly(phenylene sulfide)s, polyethylenes, polypropylenes, polyesters, polycarbonates, polyurethanes, polyethersulfones, polyetherketones, polyetheretherketones, polyetherketoneketones, poly(vinyl chloride)s, and combinations thereof.
The structure of any one of Examples 74-76, wherein the thermoplastic foam comprises a polyetherimide.
The structure of any one of Examples 74-78, wherein the foam body is characterized by a void content of 60 to 98.5 volume percent.
The structure of any one of Examples 74-79, further comprising an adhesive layer adhered to the first major surface; and a skin layer adhered to a surface of the adhesive layer opposite the first major surface.
The structure according to Example 80, wherein the skin layer comprises a material selected from the group consisting of aluminum, aluminum alloys, polyetherimides, polycarbonates, polypropylenes, polyetherimide/glass fiber composites, polyetherimide/carbon fiber composites, polycarbonate/glass fiber composites, polycarbonate/carbon fiber composites, and polypropylene/glass fiber composites.
The structure according to Example 80 or 81, wherein the skin layer comprises a polyetherimide/glass fiber composite.
The structure according to Example 74, wherein the thermoplastic foam comprises a polyetherimide; the foam body is characterized by a void content of 65 to 95 volume percent; the foam body further comprises an adhesive layer adhered to the first major surface, and a skin layer adhered to a surface of the adhesive layer opposite the first major surface; and the skin layer comprises a composite comprising a polyetherimide and glass fibers.
A method of forming a reinforced foam structure, the method comprising: (a) forming a plurality of channels within a foam body to form a reduced-weight foam body characterized by a compressive strength, the foam body comprising a thermoplastic material and extending from a first major surface to a second major surface opposite the first major surface; wherein each channel extends partially or fully through the foam body; and wherein each channel is defined by a channel surface; and (b) reinforcing at least a portion of the channel surfaces to form a reinforced foam structure, the reinforced foam structure having a compressive strength greater than the compressive strength of the reduced-weight foam body.
The method of claim 84, wherein the foam body comprises a polyetherimide; the foam body is characterized by a void content of 65 to 95 volume percent; the reinforced foam structure further comprises an adhesive layer adhered to the first major surface, and a skin layer adhered to a surface of the adhesive layer opposite the first major surface; the skin layer comprises a composite comprising a polyetherimide and glass fibers; and said reinforcing at least a portion of the channel surfaces comprises passing a heating element through the channels defined by the at least a portion of the channel surfaces.
An article comprising the structure of any one of Examples 74-85.
A structure comprising: a generally planar body formed at least from a thermoplastic foam, the general planar body comprising a first major surface and second major surface opposite the first major surface, with each major surface defining a plurality of openings, the generally planar body defining channels extending there through, with each channel of at least a portion of the channels extending from an opening in the first major surface to an opening in the second major surface, wherein each channel of the portion of the channels includes an inward-facing channel surface comprising a channel material of a first compressive strength, with the channel material disposed proximal to a body material of a second compressive strength that is lower than the first compressive strength.
The structure of Example 87, wherein the thermoplastic foam comprises a thermoplastic selected from the group consisting of polyetherimides, acrylics, fluorocarbons, polyamides, polyethylenes, polyesters, polypropylenes, polycarbonates, polyurethanes, polyetheretherketones, polyphenylene sulfides, and polyetherketoneketones.
The structure of Example 87, wherein the thermoplastic foam comprises polyetherimide.
The structure of any one of Examples 87-89, wherein at least channels of the portion of the channels are arranged in a pattern defining a honeycomb structure.
The structure according to any one of Examples 87-90, wherein the generally planar body includes portions without the channels.
A method of forming a panel, the method comprising the processes of: (a) forming a foam structure at least from a thermoplastic material with a body extending from a first side to a second side; (h) forming a plurality of apertures within the body, at least one aperture defined by a first wall surrounded by a second wall; and (c) forming at least one reinforcement wall from at least a portion of the first wall, wherein the reinforcement wall is formed from the thermoplastic material and has a first compressive strength, and wherein at least a portion of the second wall is formed from the thermoplastic material and has a second compressive strength different than the first compressive strength.
The method of Example 92, wherein process (b) includes one of cutting the plurality of apertures in the body with one or more of a water jet, a laser, a drill, a computer numerical cutting system, a bead injection process and a punch system.
Filing Document | Filing Date | Country | Kind |
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PCT/US2016/068225 | 12/22/2016 | WO | 00 |
Number | Date | Country | |
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62387141 | Dec 2015 | US |