DE102016113428A1 - Panel and method of making and using same - Google Patents

Abstract

A number of variations may include a panel comprising a skin and an interior, wherein the interior comprises a micro-grid structure.

Description

TECHNICAL AREA

The field to which the disclosure generally relates relates to components for forming structures, including, but not limited to, vehicle interior and exterior components.

BACKGROUND

At present, interior linings made of injection-molded polymer are used in vehicles.

SUMMARY OF ILLUSTRATIVE VARIATIONS

A number of variations may include a product having a panel comprising a skin and an interior, wherein the interior comprises a micro-grid structure.

A number of variations may include a method, including providing a skin; and forming an interior region comprising a micro-grid structure on the skin to form a panel.

Other illustrative variations within the scope of the invention will be apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while disclosing optional variations within the scope of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

Selected examples of variations within the scope of the invention will become more fully understood from the detailed description and the accompanying drawings, wherein:

1A illustrates a panel according to a number of variations.

1B illustrates a panel according to a number of variations.

1C illustrates a panel according to a number of variations.

2 a panel according to a number of variants illustrated.

3 illustrates a system and method according to a number of variations.

4 illustrates a method according to a number of variations.

5 illustrates a method according to a number of variations.

6 compares a performance attribute for sandwich panels with various core materials according to a number of variations.

7A1 a panel and a number of methods according to a number of variations illustrated.

7A2 a panel and a number of methods according to a number of variations illustrated.

7A3 a panel and a number of methods according to a number of variations illustrated.

7A4 a panel and a number of methods according to a number of variations illustrated.

7A5 a panel and a number of methods according to a number of variations illustrated.

7A6 a panel and a number of methods according to a number of variations illustrated.

7A7 a panel and a number of methods according to a number of variations illustrated.

7A8 a panel and a number of methods according to a number of variations illustrated.

7A9 a panel and a number of methods according to a number of variations illustrated.

7A10 a panel and a number of methods according to a number of variations illustrated.

7B1 a panel and a number of methods according to a number of variations illustrated.

7B2 a panel and a number of methods according to a number of variations illustrated.

7B3 a panel and a number of methods according to a number of variations illustrated.

7B4 a panel and a number of methods according to a number of variations illustrated.

7B5 a panel and a number of methods according to a number of variations illustrated.

7C1 a panel and a number of methods according to a number of variations illustrated.

7C2 a panel and a number of methods according to a number of variations illustrated.

7C3 a panel and a number of methods according to a number of variations illustrated.

DETAILED DESCRIPTION OF THE ILLUSTRATIVE VARIATIONS OF THE INVENTION

The following description of the variations is merely for the purpose of illustration and is in no way intended to limit the invention, its application, or uses.

The 1A - 1C show a product 10 according to a number of variations. In a number of variations, the product can 10 a panel ( 10 ). 1A shows a panel 10 according to a number of variations. 1B shows a cross section along line / section AA of the panel 10 in 1A , 1C shows a detailed view of the in a circle 1C shown cross-section of the panel 10 along line / section AA in 1B , In a number of variations, the panel can 10 forming part of the interior or exterior of a vehicle. In a number of variations, the panel can 10 Cowling, cover, side trim, exterior trim, T-bone top, top interior trim, or any other type. In a number of variations, the vehicle may include a motor vehicle, watercraft, spacecraft, aircraft, or some other type. In a number of variations, the panel can 10 at least one skin 12 and at least one interior area 14 include. In a number of variations can the interior 14 a micro-grid structure 16 include. In a number of variations can the interior 14 a sealant layer 19 between the skin 12 and the micro-grid structure 16 include. In a number of variations, the sealant layer 19 prevent the micro-grid structure 16 during the manufacturing process in the skin 12 entry. In a number of variations, the micro-grid structure 16 a polymeric material 618 include. In a number of variations, the micro-grid structure 16 be consistent throughout. "Uniform" can be defined as consisting of a material composition or consistency. In a number of variations, the micro-grid structure 16 be uneven. In a number of variations, the polymer material may be formed by a plurality of self-propagating polymer optical fibers 26 To be defined ( 2 - 3 ). In a number of variations, the skin can 12 comprise a tissue. In a number of variations, the panel can 10 at least one fastening component 18 include. In a number of variations, the panel can 10 at least one fastening element 20 include. In a number of variations, the panel can 10 at least one bent section 22 and at least one flat section 24 exhibit. In a number of variations can the interior 14 have a thickness (T) of less than 1 millimeter. In a number of variations, the skin can 12 have a thickness of less than 0.5 millimeters. In a number of variations can the interior 14 on the skin 12 be formed. In a number of variations, forming the interior can be 14 , the polymer material 618 or the micro-grid structure 16 include that to the skin 12 be tied or grown up on this. In a number of variations can the interior 14 have a different thickness throughout. In a number of variations, the panel can 10 be multicolored. In a number of variations, the panel can 10 that has a micro-grid structure 16 is made to have a higher stiffness per unit mass than injection molded panels and a higher strength per unit mass than injection molded panels and is lighter (about 10-50%) than injection molded panels and, based on the application of the panels, has an adjustable energy input , 6 shows a bending stiffness metric for sandwich panels 10 minimum mass at which a microstructured core 16 compared with various alternative core materials.

In a number of variations, the skin can 12 a fabric or textile. In a number of variations, the skin can 12 to include a metal. In a number of variations, the skin can 12 include a ceramic. In a number of variations, the skin can 12 comprise a polymer. In a number of variations, the skin can 12 comprise a non-conductive material. In a number of variations, the skin can 12 a material including, but not limited to, plastic steel, stainless steel, copper, nickel, tin, precious metals, zinc, iron, bronze, aluminum, titanium, platinum, shellac, amber, aramid (including Twaron, Kevlar, Technora, Nomex) Silk, leather, rubber, synthetic rubber, phenol-formaldehyde, neoprene, nylon, polyvinyl chloride, polystyrene, polyethylene, polypropylene, polybenzimidazole, polyacrylonitrile, PVB, silicone, bioplastic, teflon, PET, PP, PVDC, PA PTFE, PEO, PPY, PANI, PT, PPS, PPV, PAC, polyester, vinyl polymer, polyolefin, polyacetylene, phenolic resin, polyanhydride, epoxide, phenol, polyimide, PEEK, alumina, beryllia, ceria, zirconia, carbide, boride, nitride, silicide, porcelain, clay, Quartz, alabaster, glass, kaolin, feldspar, steatite, petunia, ferrite, stoneware, PZT, alpaca, angora, byssus, camel hair, cashmere, catgut, dog hair, guanaco, llama, leather, mohair, pashmina, quiviut, hare, silk, Sinew, Spider Silk, Wool, Vikunja, Yak, Abaka, Bagasse, Balsa, Bamboo, Coconut Fiber, Cotton, Flax, Hemp, Jute, Kapok, Kenaf, Pina, Raffia, Ramie, Sisal, Wood, Asbestos, Acetate, Triacetate, Artificial Silk, Lyocell viscose, modal viscose, viscose, glass, silica, carbon, basalt, metallic, acrylic, M icrofiber, modacrylic, nylon, olefin, polyester, polyethylene, spandex, vinylon, vinyon, cylon, saran, carbon fiber reinforced polymer, carbon fiber reinforced plastic, carbon fiber reinforced thermoplastic or carbon nanotube reinforced polymer, fiber reinforced polymer, glass fiber (including E glass, A glass, E-CR glass, C glass, D glass, R glass, F glass, S glass, S-2 glass, hex, or any other type), metallic alloys, combinations thereof, or any other type , In a number of variations, the skin can 12 include a composite laminate comprising multiple layers of the listed materials. In a number of variations, the micro-grid structure 16 in the 2 - 3 shown. In a number of variations, the micro-grid structure 16 comprising a metallic material, at least one of the following: aluminum, titanium, tungsten, nickel, tin, platinum, palladium, copper, steel, molybdenum, gold, or silver. In a number of variations, the micro-grid structure 16 a polymeric material 618 comprising a photopolymer material 130 may include. In a number of variations, the polymer material 618 be coated with a metallic material. In a number of variations, the photopolymer material 130 originally from a monomer 620 be formed or a monomer 620 include. In a number of variations, the micro-grid structure 16 a variety of angled struts or polymer optical fibers 26 (These may also be referred to as angled "lattice structure elements" or "lattice structure members"). In a number of variations, the struts may be made of the polymer optical fibers 26 be formed. In a number of variations, the micro-grid structure 16 using a fixed light or a heat input 600 (It may be collimated UV light) formed around the polymer optical fibers 26 to cure (polymerize), which can propagate itself in a 3D structure. As such, the expanded polymer optical fibers form 26 a micro-grid structure 110 containing the polymer material 618 includes. In a number of variations, a photopolymer material 130 or monomer 620 with a continuous micro-grid structure 16 be formed continuously so that no internal boundaries, z. As boundaries within the interpenetrating portions of the struts of the microstructure, are present. Every node 120 the micro grid structure 110 may be from the photopolymer material 130 or monomer 620 with a continuous micro-grid structure 16 be formed.

In a number of variations, the photopolymer material 130 a plurality of (a) unsaturated molecules, (b) a molecule having a structure RXH (eg X ═ O, S, N) and (c) a photoinitiator greater than 0% and less than 10% of the total weight of the Include polymers. In a number of variations, the unsaturated molecules may contain from 3 to 97% by weight of the monomeric formulation 620 turn off. In a number of variations, the molecule having a structure RXH (eg, X ═ O, S, N) may be about 3-97 wt%

Referring to component (a), in a number of variations, each of the unsaturated molecules may include double bonds C═X2 or triple bonds C═X2, where X2 may be selected from a group comprising C, N, O, and S. In a number of variations, the double bonds C ═ X2 or triple bonds C ≡ X2 may be located at terminal positions of a corresponding unsaturated molecule. In a number of variations, substitution at the multiple bonds may be by any atoms such as H, F, and Cl or groups such as alkyl groups, esters, amine groups, hydroxyl groups, and CN. In a number of variations, one or more of these double bonds or triple bonds may be present in the unsaturated molecules. In a number of variations, these may contain different combinations of these different multiple bonds.

In a number of variations, each of the unsaturated molecules (a) may include one or more different vinyl groups. In a number of variations, these vinyl groups can be at the terminal positions. In a number of variations, the unsaturated molecules may be selected from a group comprising: ethynyl, cyanide, vinyl ethers, vinyl esters, vinyl amides, vinyl triazine, vinyl isocyanurate, acrylate, methacrylate, dienes and trienes. In a number of variations, the unsaturated molecules may be selected from a group comprising: pentaerythritol tetraacrylate; 2, 4, 6-triallyloxy-1,3,5-triazine; Triallyl-1, 3, 5-triazine-2, 4, 6-trione; and tricyclohexane.

Referring to component (b), in a number of variations, the molecule having a structure R-X1-H may contain between about 3 and about 97% by weight of the monomeric formulation 620 turn off. In a number of variations, the molecule having a structure R-X1-H may include part of an organic group. The part of an organic group may include a part of an alkyl group, ester group, amine group and / or hydroxyl group.

Referring to component (c), in a number of variations, the photoinitiator may be greater than 0% and less than about 10% of the total weight of the monomeric formulation 620 turn off. In a number of variations, the photoinitiator can form free radicals upon exposure to intramolecular bond cleavage or intermolecular hydrogen abstraction. In a number of variations, the photoinitiator may be selected from a group comprising: 2, 2-dimethoxy-2-phenylacetophenone; 2-hydroxy-2-methylpropiophenone; camphorquinone; benzophenone; and benzoyl peroxide.

In a number of variations, the monomer formulation 620 further include a radical inhibitor component (d). In a number of variations, component (d) may be a radical inhibitor, that of the monomeric formulation 620 may be added to reduce unwanted polymerization of the regions outside the optical waveguide 26 contribute. A polymerization of the unexposed areas outside the waveguide 26 may be due to residual heat generated by the polymerization reaction or by light emitted from the waveguide during exposure 26 "Escapes". In a number of variations, the radical inhibitor (d) may be selected from a group comprising: hydroquinone, methylhydroquinone, ethylhydroquinone, methoxyhydroquinone, ethoxyhydroquinone, monomethyletherhydroquinone, propylhydroquinone, propoxyhydroquinone, tert-butylhydroquinone and n-butylhydroquinone. In a number of variations, component (d) may comprise between 0-3% by weight of the total composition of the monomer material 620 turn off. In a number of variations, the micro-lattice structure can be 16-component photopolymer material 130 in a monomer formulation 620 which comprises at least some of components (a), (b), (c) and / or (d). In a number of variations, the components may be thoroughly stirred or blended to ensure that they are mixed well and the monomer formulation 620 is uniform.

In a number of variations can be a light entrance 600 (It may be collimated ultraviolet light) used to polymer optical waveguides 26 to cure (polymerize) to the micro-grid structure 110 from the monomer 620 that can self-propagate in a 3D structure. In a number of variations, the size or location of light entry may be determined (or stationary relative to the mask). As such, the expanded polymer optical fibers form 26 the micro grid structure 110 , In a number of variations, the photopolymer material 130 or the monomer 620 undergo a change in refractive index during the polymerization process leading to the formation of polymer optical waveguides 26 can lead. In a number of variations, if a monomer 620 of photopolymer material 130 , which may be photosensitive, exposed under the proper conditions (eg, UV light), the exit area of the polymerization (eg, a small circular area) may "capture" the light and direct it to the tip of the polymerized area Continue to drive this polymerized area. In a number of variations, the source of collimated light 600 have a wavelength of between about 200 nm and about 500 nm. In a number of variations, this process can continue to run and form a structure of light waves 26 with approximately the same cross-sectional dimensions along their entire length. In a number of variations, this process can continue and lead to the formation of a waveguide structure 26 with different cross-sectional dimensions along their overall length.

In a number of variations requires the formation of a polymer optical waveguide 26 a change in the refractive index between the liquid monomer 620 and the solid polymer 110 ( 618 ). In a number of variations, the microstructure polymer structure 110 be as transparent as possible to the wavelength (s) of light that can be used to form free radicals and induce polymerization to self-propagate the polymer optical waveguide 26 to enable. In a number of variations, the self-propagation of the polymer optical waveguide 26 to enable the micro-grid polymer structure 110 and the resulting panel 10 have a variety of colors, including, but not limited to, blue, green, red, yellow, orange, violet, light brown, cyan, black, white, multicolor, nuances thereof, or any other color. In a number of variations, the polymerization of waveguides 26 to form a three-dimensional open-cell micro-lattice polymer structure 110 have such a reactivity that the reaction can come to a standstill when the exposure is turned off to over-cure the monomer 620 to prevent that the polymer optical fiber 26 surrounds.

In a number of variations, the micro-grid structure 16 according to system 550 and or method 500 be formed. As in 4 - 5 can be shown the system or procedure 500 block 510 for providing a light source (eg a source of collimated light) 600 , a reservoir (eg a form) 610 with one volume of a monomer 620 which is capable of polymerizing at a wavelength of the collimated light beam transmitted through the light source 600 is provided, and a structuring device 630 (eg a mask) with a single or multiple openings 640 (eg, open area, hole) of suitable shape and dimension. In a number of variations, the device can be used for structuring 630 be made of a light, flexible and opaque material such as PET film (polyethylene terephthalate). In a number of variations, the opening (s) may 640 have the shape of a triangle, a pentagon, a hexagon, a polygon, an oval, a star or other shape, depending on the corresponding application of the micro-grid structure 16 , In a number of variations, the device can be used for structuring 630 have a 3D shape around a 3D micro grid structure interior 14 to build. In a number of variations, a single collimated beam may block 512 through every single opening 640 in the device for structuring 630 on the monomer 620 be directed. In a number of variations may arise between the structuring device 630 and the monomer 620 a substrate 650 are located. In a number of variations, the substrate can 650 above or below the monomer 620 to be ordered. In a number of variations, the substrate may become 650 composed of a material such as glass, mylar and other suitable materials which convert the incident light beam to the monomer 620 can transfer. In a number of variations, the substrate can 650 the skin 12 be made of other listed materials. In a number of variations, the substrate or the skin 650 respectively. 12 be substantially transparent to the incident light beam. In a number of variations can be in block 514 on the surface of the monomer 620 in the area exposed to a portion of the light beam, at least one optical fiber 26 begin to polymerize to a micro-grid structure 16 to form or "grow up". In a number of variations, the micro-grid structure 16 on the substrate or the skin 650 respectively. 12 Grow, form, bind or attach to a panel 10 to build. Optionally, the substrate or the skin 650 or skin 12 in block 516a in a number of variations around the formed micro-grid structure 16 be wrapped or arranged over to panel 10 to build. Optionally, a second substrate or a second skin 650 ' or a second skin 12 ' in block 516b in a number of variations on the formed micro-grid structure 16 be arranged to panel 10 to build. In a number of variations, the micro-grid structure 16 to the substrate 650 or the skin 12 be bound. In a number of variations can substrate 650 . 650 ' or skin 12 . 12 ' have a 3D shape around a 3D panel 10 to build. In a number of variations, the micro-grid structure 16 within two different skins 12 . 12 ' be arranged adjacent to the micro-grid structure 110 tied or grown on opposite sides. In a number of variations, the skins 12 . 12 ' either before or after the formation of a particular bend or shape of the micro-grid structure 110 be attached or tied. In a number of variations, attaching the skins creates 12 . 12 ' at the micro grid structure 110 a sandwich structure that may have additional strength, stiffness and thermal conductivity properties. In a number of variations, the skin can 12 as a result of curing the micro-grid structure 16 to the micro grid structure 16 be bound. In a number of variations, the skin can 12 using an adhesive (not shown) to the micro-grid structure 16 be bound. In a number of variations, the adhesive may be a UV-curing adhesive. In a number of variations, the sealant layer 19 when tying the micro-grid structure 16 to the skin 12 supportive. In a number of variations, the sealant layer 19 include the adhesive. In a number of variations, the sealant layer 19 prevent the micro-grid structure 16 or the glue in the skin during the formation process 12 entry.

In a number of variations, according to 5 a procedure 900 shown. In a number of variations can through the process 900 from a micro-grid structure 16 and at least one skin 12 a 3-D panel 10 getting produced. In block 1000 can, as in 5 illustrates a photomonomer 130 / 620 to be selected. In a number of variations can be in block 1010 a volume of the selected photomonomer 620 be secured (eg in a reservoir or a mold 610 ). In a number of variations, a geometry can be a mask 630 based on a desired 3D structure in block 1020 be designed. In a number of variations, a structuring device 630 , such as a mask with the designed geometry, in block 1030 securely fastened. In a number of variations, the securely attached mask 630 at least one opening 640 between at least one collimated light source 600 and the volume of the selected photomonomer 620 exhibit. In a number of variations, the mask can 630 with the monomer 620 come into contact or through a substrate 650 or skin 12 be separated. In block 1040 can provide a reasonable exposure time based on the incident energy of a collimated beam of light at least one collimated light source (eg an incident energy of a UV light) 600 and a desired length of one or more waveguides 26 be determined. In a number of variations, the collimated light beam may be from at least one collimated light source 600 for a duration of the exposure time on the mask 630 be directed, so that a part of the collimated beam, the mask 630 happens and through the at least one opening 640 into the photomonomer 620 can be routed to at least one waveguide 26 through a portion of the volume of the photomonomer 650 to build. In a number of variations, the at least one waveguide 26 have a cross-sectional geometry that substantially matches the shaped geometry of the opening on the mask 630 matches. In a number of variations, as in block 1050 shown, several collimated beams in different directions of incidence and / or angles for a certain time through the mask 630 be directed. In a number of variations, as in block 1050a , a single collimated beam at a given direction and given angle through the mask for a certain time 630 be directed. In a number of variations, the collimated light beam may block 1050b , regarding the mask 630 moves and the exposure is repeated. In a number of variations may be out of the micro-grid structure 16 coming from the illuminated waveguides 26 and the skin 12 arises, a panel 10 be formed.

In a number of variations, the change in refractive index between the polymer and the monomer can "capture" and "focus" the light in the polymer and direct the polymerization process. In a number of variations, the polymerized waveguide 26 due to this self-focusing effect with an approximately constant cross-section and a length which is substantially greater than the cross-sectional dimensions. In a number of variations, the direction in which this polymer optical waveguide 26 can grow, depending on the direction of the incident beam 600 , In a number of variations, the cross section of the polymer optical waveguide 26 depending on the shape and dimensions of the incident collimated beam 600 which in turn may be dependent on the shape and dimensions of the opening 640 in the device for structuring 630 , In a number of variations, this may be the micro-grid structure 16 allow to have a curved and a flat part and / or different widths in at least two places. In a number of variations, the length of the polymer optical waveguide 26 "Grow" may depend on a number of parameters, including the size, intensity and exposure time of the incident beam as well as the light absorption / transmission properties of the photopolymer material 130 , In a number of variations, the time it takes to make a polymer optical fiber 26 to be dependent on the kinetics of the polymerization process.

In a number of variations, different thicknesses of the micro-grid structure 16 be achieved by the reservoir 610 to a desired level with monomer 620 filled and, as soon as a light source 600 is used, the growth of the polymer optical fibers 26 is observed towards the light that is on the free surface of the monomer 620 in the shape 610 ends. In a number of variations, the structuring device or the mask 630 be designed so that the reservoir 610 can be moved to the opening 640 , the monomer 620 and the growing waveguides 26 through the range of exposure or exposure to heat 600 to move to a continuous micro-grid structure 16 to build. In a number of variations, the panel can 10 and / or the micro-grid structure 16 in a manufacturing process according to the in US Application No. 11 / 580,335 shown non-limiting methods. In a number of variations, the panel can 10 and / or the micro-grid structure 16 in a continuous or mass production process according to the in US Application No. 12 / 835,276 shown non-limiting methods.

In a number of variations can have multiple openings 640 used to match the distance between the waveguides 26 a variety of waveguides 26 according to the pattern of the plurality of openings 640 to form. In a number of variations, the distance of the opening 640 ie the distance between the openings 640 in the mask 630 , and the series of waveguides 26 passing through each one of the openings 640 the fraction of open volume (ie, open space) of the formed 3D ordered microstructure structure 16 / 110 (or the formed open-cell polymer microfitter structure 16 / 110 ). In a number of variations, a 3D network (or a micro-grid structure 110 ), since the intersecting polymer optical fibers 26 can polymerize together, but not the propagation of the waveguides 26 affect.

In a number of variations, as in 7A1 - 7C3 shown the panel 10 be formed by different methods. In a number of variations, as in 7A1 - 7A10 shown a shape 700 for a desired shape of the panel 10 be used. In a number of variations, in step 7A1, a shape first becomes 700 introduced. In a number of variations, in step 7A2, a skin becomes 12 introduced and can be in the form 700 to be ordered. In a number of variations, the skin can 12 into the mold 700 be vacuum or blow molded, as in 7A3 shown to fit the desired shape, or be formed in any other way. In a number of variations, in step 7A4, a monomer 620 into the mold 700 against the skin 12 in a mass of monomer 620 Material can be initiated. In a number of variations can be a monomer 620 into the mold 700 against the skin 12 along its length over a second shape or conformal mask shape 700 ' which are also against the monomer 620 can be arranged, and the monomer 620 against the skin 12 be applied. In a number of variations, the conformal mask shape 700 ' be translucent to irradiation by the fixed light or the heat input 600 of the monomer 620 to enable. In a number of variations, in steps 7A5-7A6, a conformal mask shape 700 ' against the monomer 620 be arranged to the monomer 620 along the surface of the skin 12 spread. In a number of variations can be a second skin 12 ' against the monomer 620 be incorporated by inclusion in one of the listed methods. In a number of variations, the conformal mask shape 700 ' be translucent to the irradiation of the monomer 600 by the fixed light or the heat input 620 to enable. In a number of variations, in step 7A7, a fixed light or heat input may be used 600 or UV light 660 ' be used to the monomer 620 to irradiate and the micro-grid structure 16 along the length of the mold 700 according to the method described above to form a panel 10 to build. In a number of variations, the monomer 620 be pre-cured. In a number of variations, the monomer 620 in step 7A8 on the formed micro-grid structure 16 from the conformal mask shape 700 ' be removed. In a number of variations, the monomer 620 be re-irradiated in step 7A9. In a number of variations, the monomer 620 be postcured. In a number of variations can be a second skin 12 ' above the microstructure 16 to be ordered. In a number of variations, the panel can 10 in step 7A10 from the mold 700 wherein the panel is at least one skin 12 and an interior area 14 includes a micro-grid structure 16 includes. In a number of variations, as in 7B1 and 7B2 shown the skin 12 in the shape 700 be arranged and the monomer can be on the skin 12 be arranged and by the fixed light or heat input 600 or UV light 660 ' be irradiated to a panel 10 to form as it is in the process of 7A1 - 7A10 will be shown. In a number of variations, however, the monomer 620 partially cured and this partially cured microstructure core 17 Can be used to an intermediate panel 13 to build. In a number of variations, the intervening panel 13 out of form 700 removed and vacuum or blow molded or otherwise in a second form 710 , as in 7B3 and 7B4 Shown to be shaped. In a number of variations, the materials for skin / skins 12 be selected such that they are readily blow / vacuum formable, and the partially cured microstructure core 17 can also be easily deformed because it can have a low modulus and a high elongation at break at the elevated temperature of the blow / vacuum forming operation. In a number of variations, the skin can 12 a lot of holes 25 which assist in the process of blowing / vacuum forming. In a number of variations, after the blow-mold / vacuum-forming process is completed, the microstructure core may be formed 17 by fixed light or heat input 600 or UV light of the appropriate wavelength can be further irradiated or heated to an appropriate temperature around the microstructure core 17 completely harden in its new configuration and so the formation of the panel 10 , as in 7B5 shown to finish. In a number of variations, the fixed light or the heat input can 600 or UV light radiate heat to the formation of the intervening panel 13 in the panel 10 cause. In a number of variations, the panel can 10 are cooled after heat has been added to the micro-grid structure 16 to consolidate. In a number of variations, as in 7C1 - 7C3 shown the shape 700 , as in 7B1 - 7B5 shown the intervening panel 13 form. The microstructure core can be in the intermediate panel 13 but completely harden. In a number of variations, as in 7C2 - 7C3 shown the intervening panel 13 then by the fixed light or heat input 600 or UV light 660 ' to above the glass transition temperature (Tg) of the microstructure structure core 17 be heated or irradiated. Then it will be in the second form 710 arranged to assume a desired shape. In a number of variations, the microstructure core can 17 above its Tg have a much lower modulus and a higher elongation at break. In a number of variations, the skin materials 12 also be chosen such that they are suitable for formation at the temperature to which the core 17 is heated, suitable. In a number of variations is the whole intervening panel 13 then moldable at this temperature. In a number of variations, this panel 13 then blow-molded or vacuum-formed to form it into the second shape 710 bring to. In a number of variations, the intervening panel 13 then be cooled as soon as it is in the shape of the second mold 710 fits the panel 10 to build. The glass transition temperature can vary depending on the used components of the skin 12 and the monomer 620 vary. In a number of variations, using one of these methods can make a second skin 12 ' be placed over the micro grid structure around a panel 10 with two skins and the micro grid structure 12 as an interior area 14 to shape as it is in 1 and 2 will be shown.

In a number of variations can be a sealant layer 19 between the micro-grid structure 16 and the skin 12 , as in 7C1 - 7C3 represented, are arranged. In a number of variations, the sealant layer can prevent the monomer from entering the skin during the manufacturing process 12 it can make a better bond between the skin 12 and the microstructure core 17 promote or the formation of the finished fairing 12 facilitate in another way. In a number of variations, the micro-grid structure 16 on the sealing layer 19 grow, form on, bind to, or attach to. In a number of variations, the sealant layer 19 at least one of an epoxy, a polyurethane, a polyimide, a cyanoacrylate, a urethane, an acrylic, a rubber, a phenol resin, a formaldehyde resin, a phenol-formaldehyde resin, a styrene, a styrene-butadiene, a vinyl resin (such as e.g. including, but not limited to, polyvinyl acetate, polyvinyl butyral, polyvinyl ether, polyvinyl formal, polyvinyl ether or polyvinyl chloride), an acrylic resin, a phenoxy, a polyamide, a polyester, an ethylene-acrylic acid copolymer, ethylene vinyl acetate, a polysulfide, a silicone polymer, a cyanoacrylate, a cement, a glycerol, a nitride, an oxide, a polyolefin polymer, a polyester resin, a polyimide, a polyamide, a polybenzimidazole, a polyquinoxaline, a polyethylenimine, a urea, a melamine, an acrylonitrile-butadiene, a polyisobutylene, a styrene Diene styrene, a polychloroprene, combinations thereof, or otherwise. In a number of variations, the sealing layer can 19 onto the skin 12 applied or developed in situ by suitable surface modifications of the skin. Not all skins require a sealant layer. In a number of variations, the micro-grid structure 16 used to a number of applications of the panels 10 according to numerous parameters, including but not limited to 1) the angle and structure of the polymer optical fibers 26 2) the densification or relative density of the resulting cell structure (or the fraction of the open volume) and 3) the cross-sectional shape and dimensions of the polymer optical fibers 26 , In a number of variations, the thickness of the micro-grid structure 16 depending on the design criteria 10 microns to 5 mm amount. In a number of variations, the length of the waveguide 26 between waveguide nodes 120 the interpenetrating waveguide 26 between 5 and 15 times the thickness. In a number of variations, the micro-grid structure 16 be grown in such a way that the resulting panel 10 depending on its application across its shape or length can have different thicknesses of material. In a number of variations, the micro-grid structure 16 and / or the panel 10 have a continuously varying thickness. In a number of variations, the micro-grid structure 16 and / or the panel 10 have a continuously changing geometry to according to the application of the panel 10 Develop areas of higher or lower stiffness and strength.

In a number of variations, the micro-grid structure 16 with a material enhancer 170 comprising a metallic material selected from the group comprising: nickel (Ni), copper (Cu), gold (Au), silver (Ag), ruthenium (Ru), platinum (Pt), Rhodium (Rh), cobalt (Co), iron (Fe), zinc (Zn), titanium (Ti), aluminum (Al) or combinations thereof. In a number of variations, the coating of a micro-grid structure 110 with a metallic material, the strength, rigidity and thermal conductivity of the micro-grid structure 110 increase. In a number of variations, the micro-grid structure 16 with an enhancer 170 which may comprise a ceramic material and which is selected from the group comprising: silicon carbide, silicon nitride, hafnium carbide, chromium carbide, boron nitride, boron carbide, alumina, titanium diboride, titanium nitride, zirconia, titanium carbide, titanium carbonitride, tantalum carbide, tantalum nitride, or combinations thereof , In a number of variations, the coating of a micro-grid structure 110 with a metallic material, the strength, rigidity and thermal conductivity of the micro-grid structure 110 increase. The enhancer 170 can be applied using a variety of methods, including but not limited to electroplating, metal casting, gel casting, slip casting, sol-gel, chemical vapor deposition, carbide reactions, or otherwise.

In a number of variations, the panel can 10 a fastening component 20 include. In a number of variations, the fastening component 20 a male attachment 18 include, but not limited to, bolt, fastener, buckle, button, cable tie, clamp, clip, coupling, flange, toggle fastener, eyelet, snap, nail, staple, pin, velcro, rivet, screw anchor, push button, staple, needlestick, Belt, threaded fastener, tape fastener, hinged dowel, zipper, wedge anchor, or any other type. In a number of variations can the male attachment 18 after formation according to the known methods on the panel 10 be attached. In a number of variations, the fastening component 20 a female attachment 18 include, but not limited to, a hole, gap, slot, edge, recess, or other type. In a number of variations, the female attachment 18 after formation according to known methods in the panel 10 be formed. In a number of variations, the female attachment 18 the result of the device for structuring 630 be.

The following description of variations merely illustrates components, elements, acts, product, and methods that are considered to fall within the scope of the invention and are not intended to limit such scope to what is concretely disclosed or otherwise expressly stated. The components, elements, acts, products, and methods described herein may be combined and rearranged other than as expressly described herein, and are still considered to be within the scope of the invention.

Variation 1 may include a product comprising a panel comprising a skin and an interior, wherein the interior comprises a micro-grid structure.

Variation 2 may include a product according to Variation 1, wherein the panel comprises an interior trim of a vehicle.

Variation 3 may include a product according to any of Variations 1-2 wherein the skin comprises a tissue, leather or composite laminate.

Variation 4 may include a product according to any of Variations 1-3, wherein the micro-grid structure comprises at least one of a polymeric or metallic material.

Variation 5 may involve a product according to any of Variations 1-4 wherein the micro-grid structure is uniform throughout.

Variation 6 may include a product according to any of variations 1-5, wherein the panel has at least one bent portion and at least one planar portion.

Variation 7 may include a product according to any of variations 1-6, wherein the panel comprises at least one attachment component.

Variation 8 may include a product as set forth in Variations 1-7 wherein the interior is bound or grown on the skin.

Variation 9 may include a product according to any of variations 1-8, wherein the interior region has a different thickness throughout.

Variation 10 may include a product according to any of Variations 1-9, further comprising a sealant layer located between the interior and the skin.

Variation 11 may include a method including providing a skin; and forming an interior region comprising a micro-grid structure on the skin to form a panel.

Variation 12 may include a method of variation 11, further comprising sheathing the skin or placing a second skin over the interior.

Variation 13 may include a method according to any of variations 11-12, wherein the skin comprises a tissue, leather, or composite laminate.

Variation 14 may include a method according to any of variations 11-13, wherein the micro-grid structure comprises at least one of a polymeric material or metallic material.

Variation 15 may include a method according to any of variations 11-14, wherein the panel is formed in a mold.

Variation 16 may include a method according to any of variations 11-15, wherein the panel has at least one bent portion and at least one planar portion.

Variation 17 may include a method of variations 11-16 wherein the interior is attached to or grown on the skin.

Variation 18 may include a method according to any of variations 11-17, wherein the interior region has a continuously different thickness.

Variation 19 may include a method according to any of variations 11-18, further comprising a sealant layer located between the interior region and the skin.

Variation 20 may include a method including providing a mold; placing a skin in the mold; placing a photocuring monomer over the skin; and irradiating the monomer to form a microstructure layer on the skin to form a panel.

Variation 21 may include a method and / or product as set forth in any of Variations 1-20 wherein the panel is one of the options - trim panel, cover, side trim, exterior trim, T-bone top, top interior trim, or another type. is.

Variation 22 may include a method and / or a product according to any of Variations 1-21, wherein the micro-grid structure is consistently uniform.

Variation 23 may include a method and / or product according to any of Variations 1-22 wherein the polymeric material is defined by a plurality of self-propagating polymeric optical fibers.

Variation 24 may include a method and / or product according to any of Variations 1-23, wherein the interior region has a width of less than 1 millimeter.

Variation 25 may include a method and / or a product according to any of Variations 1-24, wherein the skin has a width of less than 0.5 millimeters.

Variation 26 may include a method and / or product according to any of variations 1-25, wherein the skin comprises a material including, but not limited to, plastic steel, stainless steel, copper, nickel, tin, precious metals, zinc, iron , Bronze, aluminum, titanium, platinum, shellac, amber, aramid (including Twaron, Kevlar, Technora, Nomex), silk, rubber, synthetic rubber, phenol-formaldehyde, neoprene, nylon, polyvinyl chloride, polystyrene, polyethylene, polypropylene, polybenzimidazoles, Polyacrylonitrile, PVB, Silicone, Bioplastic, Teflon, PET, PP, PVDC, PA PTFE, PEO, PPY, PANI, PT, PPS, PPV, PAC, Polyester, Vinyl Polymer, Polyolefin, Polyacetylene, Phenolic, Polyanhydride, Epoxy, Phenol, Polyimide , PEEK, alumina, beryllium oxide, ceria, zirconia, carbide, boride, nitride, silicide, porcelain, clay, quartz, alabaster, glass, kaolin, feldspar, steatite, petunia, ferrite, stoneware, PZT, alpaca, angora, byssus, camel hair , Cashmere, catgut, Dog hair, Guanaco, Lama, Leather, Mohair, Pashmina, Quiviut, Rabbit, Silk, Sinew, Spider silk, Wool, Vikunja, Yak, Abaka, Bagasse, Balsa, Bamboo, Coconut fiber, Cotton, Flax, Hemp, Jute, Kapok, Kenaf, Pina, Raffia, Ramie, Sisal, Wood, Asbestos, Acetate, Triacetate, Artificial silk, Lyocell viscose, Modal viscose, Viscose, Glass, Silica, Carbon, Basalt, Metallic, Acrylic, Microfiber, Modacrylic, Nylon, Olefin, Polyester, Polyethylene, spandex, vinylon, vinyon, cylon, saran, carbon fiber reinforced polymer, carbon fiber reinforced plastic, carbon fiber reinforced thermoplastic or carbon nanotube reinforced polymer, fiber reinforced polymer, glass fiber (including E glass, A glass, E CR glass, C glass, D-glass, R-glass, F-glass, S-glass, S-2-glass, hexel or other type), metallic alloys or combinations thereof

Variation 26 may include a method and / or product according to any of variations 1-25 wherein the photopolymer material or monomer comprises a plurality of (a) unsaturated molecules, (b) a molecule having a structure RXH (e.g., X ═ O, S, N) and (c) comprises a photoinitiator.

Variation 27 may include a method and / or a product according to any of variations 1-26 wherein the molecule having a structure RXH (eg, X ═ O, S, N) is between about 3% and about 97% by weight. the monomeric formulation

Variation 28 may include a method and / or product according to any of variations 1-27, wherein the unsaturated molecules comprise C═X2 double bonds or C═X2 triple bonds, wherein X2 may be selected from a group comprising C, N, O, and S includes.

Variation 29 may involve a method and / or a product of variation 28 wherein the substitution on the multiple bonds are any atoms, such as H, F, and Cl, or groups, such as alkyl groups, esters, amine groups, hydroxyl groups, and CN. In a number of variations, one or more of these double bonds or triple bonds may be present in the unsaturated molecules

Variation 30 may include a method and / or product according to any of Variations 1-29, wherein each of the unsaturated molecules comprises (a) one or more different vinyl groups, one of at least comprising: ethynyl, cyanide, vinyl ethers, vinyl esters, vinyl amides, Vinyl triazine, vinyl isocyanurate, acrylate, methacrylate, dienes, trienes, pentaerythritol tetraacrylate; 2, 4, 6-triallyloxy-1,3,5-triazine; Triallyl-1, 3, 5-triazine-2, 4, 6-trione; and tricyclohexane.

Variation 31 may include a method and / or a product according to any of variations 1-30, wherein the molecule having a structure R-X-H comprises an organic group comprising part of an alkyl group, ester group, amine group, and / or hydroxyl group.

Variation 32 may include a method and / or a product according to any of variations 1-31, wherein the photoinitiator is greater than 0% and less than about 10% of the total weight of the monomeric formulation.

Variation 33 may include a method and / or product according to any of variations 1-32, wherein the photoinitiator is selected from a group comprising: 2, 2-dimethoxy-2-phenylacetophenone; 2-hydroxy-2-methylpropiophenone; camphorquinone; benzophenone; and benzoyl peroxide.

Variation 34 may include a method and / or product according to any of Variations 1-33, wherein the monomer further comprises a free radical inhibitor comprising: hydroquinone, methylhydroquinone, ethylhydroquinone, methoxyhydroquinone, ethoxyhydroquinone, monomethyletherhydroquinone, propylhydroquinone, propoxyhydroquinone, tert-butylhydroquinone and n-butylhydroquinone.

Variation 35 may include a method and / or a product according to any of variations 1-34, wherein the radical inhibitor comprises between 0 and 3% by weight of the total composition of the monomeric material.

Variation 36 may include a method and / or product according to any of variations 1-35, wherein the micro-grid structure has no internal boundaries.

Variation 37 may include a method and / or a product according to any of variations 1-36, wherein the polymeric structure and resulting panel may have a variety of colors including, but not limited to, blue, green, red, yellow, orange, violet , Light brown, cyan, black, white, multicolor or nuances thereof.

Variation 38 may include a method and / or product according to any of variations 1-37, wherein the method comprises: providing a light source, a reservoir having a volume of monomer, at a wavelength of a collimated light beam provided by the light source , can polymerize; a structuring device having a single or multiple apertures of a suitable shape and dimension and a skin above or below the monomer; Directing a single collimated beam through each aperture in the structuring device to the monomer; Exposing the monomer to a portion of the light beam through the patterning apparatus to form at least one optical fiber that is capable of beginning to polymerize to form or grow a microstructure on the skin or bonded thereto; and wrapping the skin around the formed micro-grid structure to form a panel or placing or bonding a second skin on the formed micro-grid structure to form a panel.

Variation 40 may include a method and / or a product according to any of Variations 1-39, wherein the structuring device comprises a lightweight, flexible and opaque material, such as PET (polyethylene terephthalate) film.

Variation 41 may include a method and / or product according to any of Variations 1-40, wherein the aperture (s) may be in the shape of a triangle, a pentagon, a hexagon, a polygon, an oval, or a star.

Variation 42 may include a method and / or product according to any of Variations 1-41, wherein the structuring device has a 3D shape to form a 3D micro-grid structured interior region.

Variation 43 may include a method and / or a product according to any of Variations 1-42 wherein the skin binds to the micro-grid structure as a result of curing the method.

Variation 44 may include a method and / or a product according to any of variations 1-43, wherein the skin is bonded to the micro-grid structure using an adhesive comprising a UV adhesive.

Variation 45 may include a method and / or product according to any of Variations 1-44 wherein reservoir, orifice, monomer, waveguide, or structuring apparatus may be moved to form a continuous micro-grid structure.

Variation 46 may include a method and / or a product according to any of variations 1-45, wherein the micro-grid structure has an open cell polymer microfitter structure.

Variation 47 may include a method and / or product according to any of variations 1-46, wherein the thickness of the micro-grid structure may range from 10 microns to 5 mm depending on design criteria.

Variation 48 may include a method and / or product according to any of variations 1-47, wherein the micro-grid structure and / or the panel may have a continuously varying geometry to form regions of higher or lower stiffness and strength in accordance with the panel application.

Variation 49 may include a method and / or a product according to any of Variations 1-48, wherein the micro-grid structure is associated with a material Enhancer comprising a metallic material selected from the group comprising: nickel (Ni), copper (Cu), gold (Au), silver (Ag), ruthenium (Ru), platinum (Pt) , Rhodium (Rh), cobalt (Co), iron (Fe), zinc (Zn), titanium (Ti), aluminum (Al) or combinations thereof.

Variation 50 may include a method and / or product according to any of variations 1-49, wherein the micro-grid structure is coated with a material enhancer comprising a ceramic material selected from the group comprising: silicon carbide, silicon nitride, Hafnium carbide, chromium carbide, boron nitride, boron carbide, alumina, titanium diboride, titanium nitride, zirconia, titanium carbide, titanium carbonitride, tantalum carbide, tantalum nitride, or combinations thereof.

Variation 51 may include a method and / or product according to any of Variations 1-50, wherein the enhancer is applied using a variety of techniques, including electroplating, metal casting, gel casting, slip casting, sol-gel, chemical vapor deposition, or carbide reactions ,

Variation 52 may include a method and / or product according to any of variations 1-51, wherein the fastening component comprises a male fastener, comprising: a bolt, a fastener, a buckle, a button, a cable tie, a clamp, a clip , a coupling, a flange, a toggle fastener, an eyelet, a snap, a nail, a staple, a pin, a hook and loop fastener, a rivet, a screw anchor, a push button, a staple, a needle stitch, a belt, a threaded fastener , a band closure, a hinged dowel, a zipper or a wedge anchor.

Variation 53 may include a method and / or product according to any of variations 1-52, wherein the attachment component includes a female attachment that includes a hole, a gap, a slot, an edge, or a recess.

Variation 54 may include a method and / or a product according to any of variations 1-53, wherein the sealing layer comprises at least one of an epoxy, a polyurethane, a polyimide, a cyanoacrylate, a urethane, an acrylic, a rubber, a phenolic resin, a A formaldehyde resin, a phenol-formaldehyde resin, a styrene, a styrene-butadiene, a vinyl resin (such as, but not limited to, polyvinyl acetate, polyvinyl butyral, polyvinyl ether, polyvinyl formal, polyvinyl ether or polyvinyl chloride), an acrylic resin, a phenoxy, a polyamide, a polyester , an ethylene-acrylic acid copolymer, ethylene-vinyl acetate, a polysulfide, a silicone polymer, a cyanoacrylate, a cement, a glycerol, a nitride, an oxide, a polyolefin polymer, a polyester resin, a polyimide, a polyamide, a polybenzimidazole, a polyquinoxaline, a Polyethyleneimine, a urea, a melamine, an acrylonitrile-butadiene, e inem polyisobutylene, a styrene-diene-styrene, a polychloroprene, combinations thereof, or another type. In a number of variations, the sealant layer 19 before, during or after the formation of the micro-grid structure 16 be applied. In a number of variations, the sealant layer 19 onto the skin 12 or micro-grid structure 16 be applied.

The above description of selected examples of the invention is merely illustrative. Thus, variations or variations thereof are not to be regarded as a departure from the spirit and scope of the invention.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 11/580335 [0047]
• US 12/835276 [0047]

Claims (10)

A product comprising: a panel comprising a skin and an interior, wherein the interior comprises a micro-grid structure. The product of claim 1, wherein the panel comprises an interior trim of a vehicle. The product of claim 1, wherein the skin comprises at least one of fabric, leather or composite laminate. The product of claim 1, wherein the micro-grid structure comprises at least one of a polymeric or a metallic material. A product according to claim 1 wherein the micro-grid structure is uniform throughout. The product of claim 1, wherein the panel has at least one bent portion and at least one planar portion. The product of claim 1, wherein the panel comprises at least one attachment component. A product according to claim 1, wherein the inner region is bonded to or grown on the skin. The product of claim 1, wherein the interior region further comprises a sealant layer located between the micro-grid structure and the skin. Method, comprising: providing a mold; placing a skin in the mold; placing a light-curing monomer over the skin; and irradiating the monomer to form a micro-grid structure layer on the skin to form a panel.

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