Abstract: A film using fullerene derivatives, a method for producing such films, and use of same are provided. In the film formed of hemispherical particles according to the present invention, the hemispherical particles are organized like a hexagonal close-packed structure, and are formed by specific fullerene derivatives. The hemispherical particles preferably have a bilayer membrane structure assembled to provide a flake-like surface for the hemispherical particles.

Abstract: Novel methods for extending electrostatic chuck lifetimes are provided. The methods involve providing a chuck having a metal cooling plate attached to a ceramic top plate via indium bonding, and after a period of use, disassembling the chuck, and providing a new chuck including the used metal cooling plate. In certain embodiments, the use of indium as a bond material uniquely allows the described disassembly and reassembly without damage to other parts of the chuck.

Abstract: A manufacturing method of functional film comprising the steps of: a first step of feeding a lengthy substrate with self-support including a first laminate film on a back side, forming an organic film on a front side of the substrate while transferring the substrate, providing a second laminate film on a surface of the organic film, and taking up the substrate into a film roll; and a second step of loading the film roll on a vacuum deposition apparatus, continuously feeding the substrate including the first laminate film and the second laminate film from the film roll, removing the second laminate film while transferring the substrate, forming an inorganic film over the organic film of the substrate, and taking up the substrate into a film roll.

Abstract: An embodiment of the invention provides a method for forming an antenna which includes: providing a workpiece having a surface; providing a compression head including a main body, a soft rubber head disposed on the main body, and at least a through-hole, wherein the through-hole penetrates through the main body and the soft rubber head; adsorbing and fixing a conducting film on the soft rubber head through the through-hole; moving the compression head against the surface of the workpiece to press the conducting film onto the surface of the workpiece; removing the compression head; and patterning the conducting film.

Abstract: A method for manufacturing graphene using light capable of transferring and patterning graphene, and graphene manufactured using the method are disclosed. The method includes forming a graphene layer on a catalyst metal layer, attaching a support layer losing adhesion by light on the graphene layer, removing the catalyst metal layer, disposing a substrate on the graphene layer, and separating the support layer from the graphene layer by irradiating light to the support layer.

Abstract: There is provided a nail enamel strip having a substrate layer and a nail enamel film with one or more nail enamel layers, at least one of the nail enamel layers having a cross-linked polymer. The nail enamel film is detachably adhered to the substrate layer. Further, there is provided a method for making the nail enamel strips, and a method of applying the nail enamel strip on a nail.

Abstract: A system and method for labeling containers requiring large amounts of information to be printed thereon using an improved nested label that is reduced in length. The nested label has a first edge, a base layer extending from the first edge, and a top layer positioned above the base layer and extending from the first edge. The base layer includes a rear surface having a substantially permanent pressure sensitive adhesive coating for adhering to the outside surface of the container and a front surface having a release coating. The top layer has a rear surface having a substantially permanent pressure sensitive adhesive coating and a front surface. The top layer is wrapped on top of the base layer from the first edge to a first position covering the base layer.

Abstract: The method relates to application of a transparent film (3) to a window (2) realized in a portion of paper (1), the portion of paper (1) being defined in a continuous strip (10) destined to be wound in a reel. The film (3) exhibits larger dimensions than the window (2), such that a frame (30) is defined about the window (2), a total thickness of which is given by the portion of paper (1) plus the film (3). The method includes a stage of pressing with which at least a part of the frame (30) is brought to a total thickness which is not greater than an original thickness of the portion of paper (1). This enables the strip (10) to be wound strictly adheringly in the various spires thereof.

Abstract: A method and product for distributing promotional materials while reducing reflected light glare into a human's eyes is provided. A non-toxic, non-reflective colored and finished material may be applied on a human's cheek where incident direct or indirect light is likely to be reflected into a human's eyes. The non-reflective material may comprise a decal, a shape, and a promotional item. The decal may comprise a non-reflective and non-toxic material of a dull or matte color having a wavelength falling outside of the range of wavelengths between 430 nm and 690 nm. The shape may be formed within the non-reflective material, comprising a color contrasting with the dull or matte color, wherein the shape is configured to provide communication. The promotional item may be for promoting a product or service affixed to the decal, wherein the shape formed within the non-reflective material is associated with the promotional item.

Abstract: A method of applying graphics to a set of articles with a graphic transfer assembly is disclosed. The method includes a step of selecting an article from a set of articles comprising different types of articles. After selecting a last that may be associated with the article, the last may be attached to a last assembly of the graphic transfer assembly. With the article attached to the graphic transfer assembly, a deformable membrane may apply graphics to curved portions of the article. A protective member can be used to protect a portion of the article during the graphic transfer process.

Abstract: A method of manufacturing a thin film device according to an aspect of the invention may include: preparing a substrate on which a sacrificial layer and a thin film to be transferred are sequentially formed; temporarily bonding the thin film to a circumferential surface of the transfer roll, and simultaneously removing the sacrificial layer to separate the thin film from the substrate at a first position of a transfer roll that is rolling; and transferring the thin film onto a sheet by running the sheet so that a surface of the sheet is bonded to the thin film temporarily bonded to the circumferential surface of the transfer roll. The substrate may be a transparent substrate.

Abstract: A composite porous membrane used as a separator for a battery includes a porous membrane A made of a polyolefin resin and a porous membrane B containing a heat-resistant resin laminated thereto, wherein the surface of the porous membrane B on the side that does not face the porous A has a three-dimensional network structure having nodes, and the peeling interface on the side of the porous membrane B formed when the porous membrane A and the porous membrane B are peeled off has a membrane morphology having pores with a pore size of 50 to 500 nm in an amount of at least 100 pores/10 ?m2.

Abstract: A kit holding a film sheet and a miniature squeegee may also include a bottle of an activation solution for an adhesive on the film sheet. The film sheet corresponds in size and shape to a display of an electronic device. Excess solution is removed from the display while evenly distributing the adhesive using wiping motions with the squeegee. In a dry adhesive application, a cover sheet over the adhesive is perforated so that one portion of the cover sheet may be removed for adhering one part of the film sheet to the display, and after securing the one part, the remainder of the cover sheet is removed to adhere the remainder of the film sheet to the display.

Abstract: A single cell-culture chamber is provided that includes a dried vitrigel membrane covering and secured to one open end surface of a tubular frame. Also provided is a double cell-culture chamber that includes two tubular frames of substantially the same planar cross-sectional shape adhesively secured to each other with a dried vitrigel membrane interposed between the opposing open end surfaces of the tubular frames so as to form a first chamber and a second chamber via the dried vitrigel membrane.

Abstract: A tape adhering apparatus and a tape adhering method for adhering an ACF tape formed from an anisotropic conductive film to a target adhering area on a substrate are disclosed. It is an objective of the invention to provide a tape adhering apparatus and a tape adhering method that enable shortening of a time consumed by operation for adhering one cut piece of an ACF tape. According to the present invention, the separator is peeled from the cut piece of the ACF tape by letting the tape conveyor means convey the tape member in synchronism with the transfer action of the transfer base and thereafter a cut portion of the ACF tape to be next adhered is placed at the cutting position of the tape cutting means by letting the tape conveyor means continually convey the tape member in the forward conveyance direction.

Abstract: A method for forming a dye sublimation image in a substrate with a dye carrier having an image formed thereon of a sublimatic dyestuff is provided. The image of the dye carrier is placed against a first surface of the substrate. The substrate and dye carrier are conveyed along a path with a first part and a second part. A continuous pressure is provided against the first surface of the substrate in the first part and second part of the path and therebetween. The dye carrier is heated to a sublimation temperature in the first part of the path. The dye carrier is then cooled to a depressure temperature in the second part of the path.

Abstract: The present disclosure relates to a transfer film for attaching protection film to flat panel display and method for manufacturing the flat panel display using the same. The present disclosure suggests a transfer film comprising: a lower film; and a protection film temporarily attached on the lower film and including a base film and an adhesion layer disposed on an upper surface of the base film. In the present disclosure, the flat panel display can be encapsulated using a transfer film having a protection film temporarily attached on a flexible lower film, so that it is possible to perfectly encapsulate the flat panel display with the protection film without any foreign material such as air bubble.

Abstract: A retransfer intermediate sheet for receiving an image to be printed onto an article by thermal retrasfer comprises a substrate which is preferably heat-deformable; and an image-receiving coating on one side of the substrate, comprising an image-receiving layer for receiving an image by printing, preferably inkjet printing, of dye-containing ink, the image-receiving layer comprising amorphous porous silica, a first, non-dye absorbing polymeric binder and a second, flexible polymeric binder. The sheet is particularly useful for printing on three dimensional articles, e.g. being heated and vacuum formed to conform to an article. The invention also coven a method of printing and an article bearing a printed image.

Abstract: According to various aspects, exemplary embodiments are provided of thermal interface material assemblies. In one exemplary embodiment, a thermal interface material assembly generally includes a thermal interface material having a first side and a second side and a dry material having a thickness of about 0.0005 inches or less. The dry material is disposed along at least a portion of the first side of the thermal interface material.

Abstract: [Object] To provide a method for transferring a graphene film, which can transfer a graphene film on a desired substrate with excellent adhesiveness, can effectively prevent defects from being generated in a graphene film and is excellent also in mass productivity, and a method for manufacturing a transparent conductive film. [Solving Means] One layer or a plurality of layers of graphene films 12 formed on a first substrate 11 and a second substrate 14 are stuck with a resin layer 13 that contains less than 1% by weight of a volatile component and has adhesiveness, the first substrate 11 and the second substrate 14 are pressurized to reduce a thickness of the resin layer 13, the resin layer 13 is cured, after that the first substrate 11 is removed.

Abstract: Disclosed herein is an adhesive application method of applying adhesive to a protruding part formed on a substrate. The adhesive application method includes an adhesive preparing step of forming an adhesive layer on the surface of a plate member, an adhesive applying step of allowing the protruding part and the adhesive layer to be brought into contact with each other such that the surface of the substrate around the protruding part does not contact the adhesive layer, and a moving step of moving the substrate and the plate member relative to each other in the plane parallel with the surface of the plate member while the surface of the substrate around the protruding part is not in contact with the adhesive layer and the protruding part and the adhesive layer are in contact with each other.

Abstract: A method for manufacturing an electronic ink display device is provided, which includes the steps of: forming an electronic ink layer on an driving substrate; forming a front protective layer and a back protective layer covering outside of the electronic ink layer and outside of the driving substrate separately, in which a dimension of the front protective layer is greater than that of the back protective layer; and filling an sealant covering and surrounding sidewall of the electronic ink layer and sidewall of the driving substrate. An electronic ink display device is also provided.

Abstract: The present invention includes an article and method for transferring an image from one substrate to another. The method includes providing or obtaining an image transfer sheet that is comprised of a substrate layer, a release layer and an image-imparting layer that may comprise a low density polyethylene or other polymeric component having a melting temperature within a range of about 90 degrees C. to about 700 degrees C. An image is imparted to the low density polyethylene area with an image-imparting medium. A second image-receiving substrate can be provided. The second image-receiving substrate is contacted to the first image transfer sheet at the polymer, image-imparting layer. Heat is applied to the image transfer sheet so that the low density polyethylene encapsulates the image-imparting medium and transfers the encapsulates to the image-receiving substrate, thereby forming a mirror image on the image-receiving substrate.

Abstract: In one embodiment, a method of applying an image to a substrate includes the steps of: imaging a printable surface with an image to form an imaged surface having a printed area and a non-printed area; positioning a masking sheet comprising an outer masking layer adjacent the imaged surface such that the outer masking layer is in contact with the imaged surface; transferring a corresponding portion of the outer masking layer to the printed area of the imaged surface, leaving a negative image mask on the masking sheet; transferring the negative image mask to a transfer layer of a heat transfer paper to form a heat transfer paper having a masked portion corresponding to the negative image mask and an unmasked portion; and transferring the unmasked portion corresponding to the printed area to a substrate. Other methods of making and using negative image masks are also disclosed.

Abstract: A formation method of an organic layer (13) includes a transfer process of forming the organic layer (13) by superposing a donor substrate (30) having a light heat converting layer (32) and a transfer layer (34) formed sequentially to cover at least regions corresponding to organic layer formation regions on a support plate (31) and a transfer mask (40) having openings corresponding to the organic layer formation regions, on each other so that the transfer layer-side surface of the donor substrate (30) comes into contact with the transfer mask (40), and, with the resultant structure placed above a transfer target substrate (20) so that the transfer mask (40) is on the lower side, transferring the transfer layer (34) onto the transfer target substrate (20) via the openings of the transfer mask (40).

Abstract: A stamping device for stamping a nanotube network onto a target substrate is disclosed. The device comprises a template structure having a support structure formed on or attached to a substrate, and a plurality of nanotubes being supported by the support structure and engaging a plane which is spatially separated from the substrate.

Abstract: A process for printing an image on a surface of a resin member includes providing a transfer medium with an image on one side of the transfer medium, providing a liquid resin, placing the one side of the transfer medium with the image and the liquid resin in contact with each other, and partially curing the liquid resin to form the resin member while maintaining the image of the transfer medium in contact with an image side of the resin member. The process may include placing the liquid resin and/or the transfer medium in a mold for shaping the resin member during curing.

Abstract: There are provided a carbon wire using CNT or a similar carbon filament having a sufficiently low electrical resistance value, and a wire assembly employing that carbon wire. A carbon wire (1) includes an assembly portion (3) and a graphite layer (4). The assembly portion (3) is configured of a plurality of carbon filaments implemented as carbon nanotubes (2) in contact with one another. The graphite layer (4) is provided at an outer circumference of the assembly portion (3).

Abstract: A method for applying a multicolored paint system to a substrate includes (1) applying a first pigmented coating material to the substrate, (2) drying and/or curing the first pigmented coating material at a selected drying and/or curing temperature, and (3) applying a second pigmented coating material to the substrate, with partial recoating of the first pigmented coating material, wherein the second pigmented coating material is applied using a laminate including a carrier on which there is a layer of the second pigmented coating material, the layer being already cured.

Abstract: A method of transferring nanostructured thin catalytic layers to a gas diffusion layer and thus making a catalyst coated diffusion media is described. The method includes treating the gas diffusion layer with a temporary adhesive to temporarily increase the adhesion strength within the microporous layer and to carbon fiber paper substrate, transferring the nanostructured thin catalytic layer to the microporous side of a gas diffusion media layer. The nanostructured thin catalytic layer can then be further processed, including adding additional components or layers to the nanostructured thin catalytic layer on the gas diffusion media layer. Preparation of catalyst coated diffusion media and a catalyst coated diffusion media based membrane electrode assembly (MEA) are also described.

Abstract: [Object] To provide a transparent conductive film that has sufficiently low sheet resistance and a sufficiently high visible light transmittance, is capable of securing high conductivity on an entire surface thereof, and has excellent corrosion resistance to an electrolyte solution, a method of producing the transparent conductive film, and a photoelectric conversion apparatus and an electronic apparatus using the transparent conductive film. [Solving Means] A transparent conductive film includes a metal fine line network layer 12 and one or more layers of graphene layers 13 provided on at least one surface of the metal fine line network layer 12. The metal fine line network layer 12 includes at least one metal selected from a group consisting of copper, silver, aluminum, gold, iron, nickel, titanium, and platinum. The metal fine line network layer 12 is provided on a transparent substrate 11.

Abstract: A multilayer image transfer sheet for non-thermally transferring an image to a receiving object includes, in the following order with respect to each other, a backing sheet; a water-releasable sacrificial layer disposed on the backing sheet; an ink-absorbing layer disposed over the water-releasable sacrificial layer; a printed image layer formed on the ink-absorbing layer; and an adhesive layer disposed over the printed image layer and configured and arranged for permanent attachment of the printed image layer to a receiving object. The printed image layer includes ink printed to form at least one image.

Abstract: A method of making a reconstructed electrode having a plurality of nanostructured thin catalytic layers is provided. The method includes combining a donor decal comprising at least one nanostructured thin catalytic layer on a substrate with an acceptor decal comprising a porous substrate and at least one nanostructured thin catalytic layer. The donor decal and acceptor decal are bonded together using a temporary adhesive, and the donor substrate is removed. The temporary adhesive is then removed with appropriate solvents. Catalyst coated proton exchange membranes and catalyst coated diffusion media made from the reconstructed electrode decals having a plurality of nanostructured thin catalytic layers are also described.

Abstract: The invention provides a process to deliver an elastomeric composition to a substrate. The elastomeric composition is cooled. The cooling also results in substantially complete transfer of the elastomeric composition from the pattern roll to the substrate with a resulting reduction in elastomer degradation.

Abstract: Articles created using particulate from recycled souvenirs and a method of decorating articles such as garments with patterns made from ground particulate obtained from noteworthy spectator sport objects such as race car tires, for example, wherein the pattern resembles the nature or characteristic of the recycled item.

Abstract: A method for sealing a vent includes coupling a film including an adhesive surface to an applicator, applying the film onto the vent using the applicator adhering the adhesive surface to at least one of the vent and a portion of a structure surrounding the vent, and decoupling the film from the applicator during or after the applying the film. An applicator for applying a sealing film to a vent for sealing the vent includes a first elongate member, a second elongate member having a bore extending along its length and receiving the first member within the bore, where the first elongate member is longer than the second elongate member and where a first end portion of the first elongate member extends beyond a first end of the second elongate member and a second end portion of the first elongate member extends beyond a second end of the first elongate member, and where the second elongate member is rotatable to various orientations relative to the first elongate member about a longitudinal axis.

Abstract: Some embodiments teach a method of preparing a flexible substrate assembly. The method can include: (a) providing a carrier substrate; (b) providing a cross-linking adhesive; (c) providing a plastic substrate; and (d) coupling the carrier substrate to the plastic substrate using the cross-linking adhesive. Other embodiments are disclosed in this application.

Abstract: A film laminating apparatus and method for a plate member having a flat or curved surface includes a first holder, a pressing roll, a film holder, support means, position confirmation means and alignment means. The first holder has absorption means that allows a plate member to be absorbed to a surface thereof by deforming the plate member. The pressing roll presses a film on a surface of the plate member absorbed to the first holder. The film holder is provided to the pressing roll, and fixes the film to be laminated to a surface of the pressing roll. The support means supports the pressing roll to be movable. The position confirmation means confirms the position of the plate member and the position of the film fixed to the pressing roll. The alignment means aligns the film and the plate member, based on the positions confirmed by the position confirmation means.

Abstract: A method and apparatus of fabrication of a multilayer flexible metamaterial can be fabricated using flip chip transfer (FCT) technique. This technique is different from other similar techniques such as metal lift off process, which fabricates the nanostructures directly onto the flexible substrate or nanometer printing technique. It is a solution-free FCT technique using double-side optical adhesive as the intermediate transfer layer and a tri-layer metamaterial nanostructures on a rigid substrate can be transferred onto adhesive first. Another embodiment of the present invention is the fabrication method and apparatus that allows the transfer of the metamaterial from a rigid substrate such as glass, quartz and metals onto a flexible substrate such as plastic or polymer film. Thus, a flexible metamaterial can be fabricated independent of the original substrate used.

Abstract: A convenient and simple method to apply permanent designs, artwork, messages, etc. . . . to shoes by manually by applying a tattoo having a base layer, a top layer, and an intermediate ink layer containing the design, artwork, or message to applied. The ink layer is permanently transferred to the shoe by manually applying pressure or water.

Abstract: A method for manufacturing a flexible structure including implanting ionic species in first and second source substrates so as to form first and second embrittlement regions respectively, delimiting first and second thin films, providing a flexible substrate, the stiffness R of which is less than or equal to 107 GPa·?m3, securing the first and second thin films to the first and second faces of the flexible substrate respectively so as to form a stack including the flexible structure delimited by the first and second embrittlement regions, the flexible structure having a stiffening effect suitable for allowing transfers of the first and second thin films, and applying a thermal budget so as to transfer the first and second thin films onto the flexible substrate.

Abstract: A method of applying a surface-coating material to a substrate includes providing a flexible laminate with a carrier and at least one layer of surface-coating material applied to the carrier and comprising a surface-coating material containing a double-bond-containing, OH-functional component A, a double-bond-containing, NCO-functional component B, and, optionally, a double-bond-containing component C which is different from A and B; applying a layer of adhesive to the substrate, contacting the carrier side of the laminate with a surface of the substrate such that the layer of surface-coating material is at least partially cured before or when it contacts the surface of the substrate, and removing the carrier from the layer of surface-coating material.

Abstract: A method of applying a graphic to an article is disclosed. The method includes applying a graphic to a backer material and covering the backer material with a clear protective layer, which may be silicone, to help prevent degradation of the graphic with time and use.

Abstract: A method and apparatus are provided for of applying a sublimation transfer to a coffee cup having a handle connected at two locations to the cup. A sublimation transfer is placed around the container with a dye image an outer surface of the cup and extending beneath the handle. An elastic clamp wraps around the cup and sublimation transfer and extends beneath the handle to press the dye layer against the cup beneath the handle. The clamp has an elongated opening near one end of the clamp and the opening is placed over the handle to fasten the clamp to the cup. The wrapped cup and sublimation transfer is placed on a conveyor oven for sublimation heating, with the clamp being removed for reuse after the sublimation transfer of the dye layer onto the cup is completed.

Abstract: The present invention provides die bonder and bonding method by which a bonding load from a high load to a low load is obtained or high-speed mounting is attained. In a die bonder or a bonding method in which a bonding head is ascended/descended by a first ascending/descending drive shaft unit, a die is picked up, the picked-up die is installed onto a workpiece, and after installed, a load is exerted on the die by the bonding head to bond the die to the workpiece, whether the load is higher/lower than a predetermined load is determined, and in bonding, when the load is higher than the predetermined load, the high load is exerted by the first ascending/descending drive shaft unit, and when the load is lower than the predetermined load, the low load is exerted by a second ascending/descending drive shaft unit.

Abstract: A film application system having multiple foil application stations. Each foil application station has a support for an elongated plastic component (typically vinyl) having an input and an output side. A drive moves successive elongated components along a path through the application station from the input side to the output side as decorative foil is applied to a surface of the component. A properly positioned and oriented transfer head applies heat and pressure to the elongated film as the component moves through the application station. The disclosed system must accommodate different style and shape components corresponding to different style windows, doors, or sashes. A backing fixture that is configured to support a given configuration component is positioned to support the component as the component moves through the application station in a region of the transfer head.

Abstract: A device for analyzing a fluid, including a layer including a plurality of sensors of MEMS and/or NEMS type, a layer including a mechanism controlling the sensor and for processing information transmitted by the sensors, the control and processing mechanism being electrically connected to the detectors, and a layer positioned on the layer including the sensors on a side of a face including the sensors including a mechanism spatially and temporally distributing the fluid on the sensors.

Abstract: An air-permeable composite fabric is provided. The composite fabric has an inner fabric layer, an outer fabric layer, and an intermediate vapor barrier. The vapor barrier is selected from adhesive material and an adhesive/membrane combination designed so the composite fabric has a level of air permeability to allow air flow between the first fabric layer and the second fabric layer and a variable level of water vapor diffusion resistance that decreases as air speed impinging on the composite fabric increases.

Abstract: A method for applying labels comprising providing a system for applying the labels, supplying at least one label, guiding a cable or conduit to the labeling system with at least one guide roller, providing a label applicator for applying the label to the cable or conduit, guiding a moving cable or conduit using the at least one guide roller, providing at least one tamping device, providing a tamping pad with the at least one tamping device, applying at least one label to at least one portion of the cable or conduit with the at least one tamping device, providing at least one guide shoe assembly; and pressing the at least one label against the at least one portion of the cable or conduit using the at least one guide shoe assembly.

Abstract: A heat transferable material includes a heat transferable polymeric binder and a light stabilizer that is an N-oxyl radical derived from a hindered amine. The N-oxyl radical has the following formula (A) or formula (B): wherein R1, R2, R5, and R6 are each a straight or branched C1-C6 alkyl or alkene, and R3 and R4 are each independently H, CH2CH3, CH3, OH, OR, COOH, COOR, or NH—C(=O)R, wherein R is a straight or branched C1-C6 alkyl or alkene, and having a molecular weight of 600 or less. At least one of R3 and R4 is not hydrogen. The heat transferable material can be in a section or patch on a thermal donor element to provide a protective overcoat material. A patch in the donor element can include a dye. The heat transferable material provides better image stability and improved iridescence when transferred to a receiver of some type.