Abstract: The present application relates to a method of preparing a metal pattern having a 3D structure, a metal pattern laminate, and use of the metal pattern laminate. According to the method of preparing a metal pattern, the metal pattern having a 3D structure can be effectively formed on a receptor. Especially, the metal pattern having a 3D structure can also be effectively and rapidly transferred to a surface of the receptor, such as, a flexible substrate, to which the metal pattern is not easily transferred. The metal pattern laminate prepared using the method can, for example, be usefully used for metal layers of flexible electronic devices or metal interconnection lines.

Abstract: There is provided a transfer sheet with improvement in smudges and blurs of a transfer sheet when printed matters are produced. A transfer sheet according to the present invention comprises a substrate, and in the order a peel layer and a transfer layer on the substrate, wherein the peel layer contains a binder resin containing an acrylic-based resin of more than 0 mass % and 49 mass % or less and a vinyl chloride-vinyl acetate resin of 51 mass % or more and less than 100 mass %.

Abstract: Conveyance means for conveying an IC tag continuous body includes a tractor feeder unit for conveying the IC tag continuous body by engaging and disengaging feed pins with sprocket holes formed in the IC tag continuous body and a negative pressure conveyance unit for conveying the IC tag continuous body while suctioning it to a conveyance belt, and printing on the IC tags in the printing device is configured such that a toner image transferred to the IC tags by a print unit is optically fixed by an optical fixation unit in a non-contact manner.

Abstract: A last assembly includes a plurality of retractable pins and a plurality of vacuum holes, both acting to hold footwear segments to the last assembly to facilitate manufacturing of, or modification to, an article of footwear. A method of making or modifying an article of footwear includes placing footwear segments on the last assembly by associating an extension portion of at least one footwear segment with the retractable pins, modifying the footwear segments and then removing the extension portion.

Abstract: A method of bonding two components includes plating a first of the components with a first silver layer, a tin layer, and a second silver layer, plating a second of the components with silver, inserting the first and second components into a pre-heated press, and applying pressure to the components causing the components to bond. A stack of layers has a first component layer, a first silver layer, a tin layer, a second silver layer, a second component silver layer, and a second component layer.

Abstract: A method of manufacturing a frangible laminate is provided. The method comprises constructing a reinforced polymer matrix, cutting the reinforced polymer matrix into a plurality of laminae, forming a laminate via stacking the plurality of laminae and at least one energy dissipating member, and consolidating the laminate.

Abstract: Apparatus and methods for fulfillment of patient prescription orders by adapting a standard or stock container pre-filled with medication or the like for use as a patient-specific container through precise application of patient-specific information to the pre-filled container. Precise placement of the patient-specific information to the pre-filled container enables pharmacy management to fully utilize valuable information provided with the pre-filled container, thereby improving the quality of service to the patient while making the process of prescription order fulfillment more efficient. In general, preferred embodiments comprise control apparatus and information-application apparatus. In embodiments, the information-application apparatus is adapted to place a patient-specific label on the container. Preferred forms of the information-application apparatus include a label printer and a positioner. The preferred printer applies patient-specific information on a label.

Abstract: A method for producing a soft magnetic film laminate circuit board having a soft magnetic film laminated on at least one side of a circuit board includes the steps of bringing a soft magnetic thermosetting film containing soft magnetic particles, having a porosity of 15% or more and 60% or less, and in a semi-cured state into contact with the one side of the circuit board and bringing the soft magnetic thermosetting film into a cured state by vacuum hot pressing.

Abstract: A method of manufacturing a device with a planar electrode structure, the method comprising: (a) forming a microfluidic channel on a substrate; (b) applying a primer layer to at least part of the microfluidic channel, (c) applying a conductive liquid to the microfluidic channel, the conductive liquid comprising electrically conductive particles dispersed in a carrier medium, the carrier medium including a solvent; (d) allowing the conductive liquid to flow throughout the microfluidic channel by capillary action to form the planar electrode structure; and (e) evaporating the solvent from the carrier medium, is described. Devices obtainable using the method and their applications are also described.

Abstract: An optical member includes a base having a surface, and a plurality of protrusions formed on the surface of the base. The plurality of protrusions is arranged in a form to cause a space between the protrusions to be filled up with adhesive to adhere an adhesion target component above the base by a capillary phenomenon.

Abstract: A semiconductor device of an embodiment includes a layered substance formed by laminating two-dimensional substances in two or more layers. The layered substance includes at least either one of a p-type region having a first intercalation substance between layers of the layered substance and an n-type region having a second intercalation substance between layers of the layered substance. The layered substance includes a conductive region that is adjacent to at least either one of the p-type region and the n-type region. The conductive region includes neither the first intercalation substance nor the second intercalation substance. A sealing member is formed on the conductive region, or on the conductive region and an end of the layered substance.

Abstract: Transfer films, articles made therewith, and methods of making and using transfer films to form bridged nanostructures are disclosed.

Abstract: A system for laminating an optical film according to an exemplary embodiment of the present disclosure includes a panel transfer unit to transfer a panel, a first laminating unit installed on a transfer line of the panel to laminate an optical film on a first surface of the panel along a first direction parallel to a transfer direction of the panel, and a second laminating unit installed on the transfer line of the panel to laminate an optical film full-cut into a predetermined length on a second surface of the panel along a direction perpendicular to the first direction.

Abstract: A method of forming a circuit board includes forming a conductive pattern on a substrate; forming a first negative resist on the substrate after formation of the conductive pattern; partially exposing the first negative resist on the surface of the conductive pattern to form a first via exposure portion; forming a second negative resist on the substrate after formation of the first via exposure portion; partially exposing the second negative resist on the first via exposure portion to form a second via exposure portion larger than the first via exposure portion; developing the first negative resist and the second negative resist after formation of the second via exposure portion to form a via opening reaching the conductive pattern; and filling the via opening with a conductive material.

Abstract: An element manufacturing method and apparatus for efficiently manufacturing an element such as an organic semiconductor element. First, an intermediate product that includes a substrate and a protrusion extending in a normal direction of the substrate is provided. Next, in a stacking chamber conditioned to a vacuum environment, a stacked structure is formed by continuously stacking a lid member on the intermediate product at a side where the protrusion is provided. After this operation, the stacked structure is transported from the stacking chamber to a first pressure chamber coupled to the stacking chamber and conditioned to a first pressure higher than the pressure in the vacuum environment. Next, the stacked structure is further transported from the first pressure chamber to a separation chamber coupled to the first pressure chamber and conditioned to a vacuum environment, and then the stacked structure is separated into the intermediate product and the lid member.

Abstract: In accordance with an alternative embodiment of the present invention, a method for forming a semiconductor device includes applying a paste over a semiconductor substrate, and forming a ceramic carrier by solidifying the paste. The semiconductor substrate is thinned using the ceramic carrier as a carrier.

Abstract: A method of manufacturing a glass component includes preparing a glass substrate having a thickness greater than or equal to 300 ?m, forming first electric wires on a first surface of the glass substrate, forming a structure by joining the glass substrate via a resin layer to a support substrate such that the first surface of the glass substrate faces the resin layer, thinning the glass substrate from a second surface of the glass substrate to a thickness between 10 ?m and 80 ?m, forming through holes in the glass substrate by irradiating the glass substrate from the second surface with a laser beam, forming second electric wires on the second surface of the glass substrate such that the second electric wires are electrically connected to the corresponding first electric wires via conductors filling the through holes, and separating the glass substrate from the support substrate.

Abstract: Aspects of the invention are directed towards an integrated circuit package and method of forming the same, and more particularly to a redistributed chip packaging for an integrated circuit. The integrated circuit package includes an integrated circuit having a protective material on at least a portion of the integrated circuit. A lead frame is coupled to the integrated circuit and a conductive layer is also coupled to the interconnect. A solder ball is coupled to the conductive layer and a passivation layer is on the conductive layer. Active and passive components are electrically coupled to the integrated circuit.

Abstract: The present invention provides kits and methods for selectively transferring a portion of an image from a substrate (e.g., paper) to a dough (e.g., Silly Putty®) comprising pressing the dough onto an image printed on the substrate. The image comprises transferable ink and non-transferable ink. At least a portion of the image comprising transferable ink transfers from the substrate to the dough and the non-transferable ink does not transfer from the substrate to the dough. The dough can be used to reveal an image that was “hidden” within the visible image printed on the substrate. The present invention also provides methods for making a substrate with an image comprising transferable ink (e.g., cold-set web ink) and non-transferable ink (e.g., sheet-fed offset ink) printed thereon, comprising using a sheet-fed offset press to print the image onto the substrate.

Abstract: This invention provides a composition for thermal insulation, comprising magnesium oxychloride cement (MOC) and air-filled glass or ceramic beads, and a method of preparing said composition. The composition may further comprise one or more additives selected from the group consisting of titanium dioxide, fly ash, pigment, potassium dihydrogen phosphate (KH2PO4) and sodium dihydrogen phosphate (NaH2PO4).

Abstract: A method of manufacturing an organic light emitting display apparatus using a donor mask. The donor mask includes a base substrate, a light to heat conversion layer provided on the base substrate, and a reflection layer disposed between the base substrate and the light to heat conversion layer and comprising a through hole corresponding to a first transfer region, a non-transfer region having a first thickness and a second transfer region having a second thickness smaller than the first thickness, and the organic light emitting display apparatus using the same.

Abstract: The object of the invention is to be able to adjust gloss or impart gloss variation not only for a decoration layer of dark color such as black ink, but also for a decoration layer of light color other than black and the gloss of the ink printed portion is adjusted or the gloss variation where a high gloss pattern part and a low gloss pattern part are adjacent to each other is imparted according to the ratio of blend of ultraviolet ray absorbent and/or ultraviolet ray shielding agent contained in an ink of a print pattern of a transfer film.

Abstract: A display device includes a flexible display panel including a recognition pattern, the recognition pattern having a plurality of sub-patterns with different color concentrations and disposed in a first direction, a housing accommodating the flexible display panel, the flexible display panel being configured to extend out of the housing in the first direction to vary a display area, and a photosensor in the housing, the photosensor corresponding to the recognition pattern and being configured to recognize the recognition pattern and to sense the display area of the flexible display panel.

Abstract: The present invention relates to an apparatus for massive manufacturing a hierarchical structure that can hierarchically form high performance micro units one a flexible substrate. For this purpose, an apparatus for manufacturing a hierarchical structure according to the present invention is provided to layer micro units provided on a dummy substrate that is made of a hard material on a target substrate that is made of a flexible material by releasing the micro units from the dummy substrate. The apparatus includes: a transfer stage flat-transferring the dummy substrate by supporting the same and a main roller rolling the target substrate by winding the same as the transfer stage proceeds and layering the micro unit of the dummy substrate on the target substrate.

Abstract: The present invention relates to a laminate panel (40; 40?; 40?; 40??) with a carrier layer (41; 41?; 41?; 41??) of wood or wood-based material, in which at least the upper side has a decoration and a layer of a cured resin (46; 46?; 46?; 46??). The rear side of the laminate panel (40; 40?; 40?; 40??) is provided with a paperless counteracting layer of a cured counteracting material (45; 45?; 45?; 45??).

Abstract: Transfer films, articles made therewith, and methods of making and using transfer films to form bridged nanostructures are disclosed.

Abstract: Methods and apparatuses for resonance tuning of microcavities are provided. An apparatus comprises a whispering gallery mode optical microcavity characterized by at least one resonance frequency; optical components configured to evanescently couple a probe laser beam into the microcavity; an absorber element in thermal contact with the microcavity; and optical components configured to illuminate the absorber element with a free space pump light beam, wherein the absorber element is configured to absorb energy from the free space pump light beam, thereby generating heat, and to transfer the heat to the microcavity, thereby inducing a shift in the at least one resonance frequency. The absorber element may be configured as a pillar forming an interfacial region with the microcavity at one of the ends of the pillar. The surface of the microcavity may be substantially free of a coating material.

Abstract: An integrated circuit includes a substrate and an interconnect part above the substrate, and further includes a photosensitive region in the substrate. A filter is provided aligned with the photosensitive region. The filter is formed by at least one layer of filter material. In one implementation for front side illumination, the layer of filter material is positioned above the photosensitive region between the interconnect part and the substrate. In another implementation for back side illumination, the layer of filter material is positioned below the photosensitive region opposite the interconnect part. The layer of filter material is configured such that a product of the thickness of the layer of filter material and the imaginary part of the refractive index of the layer of filter material is above 1 nm.

Abstract: A method for making a touch panel is provided. A number of first transparent conductive layers are formed on an insulative substrate. Each of the first transparent conductive layers is resistance anisotropy. An adhesive layer is formed on the insulative substrate to cover only part of the first transparent conductive layers. A carbon nanotube layer is formed on the adhesive layer. The carbon nanotube layer is patterned to obtain a number of second transparent conductive layers spaced from each other and with each corresponding to one first transparent conductive layer. A number of first electrodes, a first conductive trace, a number of second electrodes, and a second conductive trace are formed contemporaneously.

Abstract: A decorating method includes the steps of coating a base material with a coating composition comprising 45-95 parts of urethane methacrylate, 1-50 parts of a compound having at least an intra-molecular radical polymeric double bond, and 0.1-15 parts of photopolymerization initiator. The coating is hardened to form an under coat. Vacuum deposition of indium and/or tin in a crystalline structure-independent way is performed to form a non-conductive thin film. Then, a UV-hardening resin, poly acrylic-urethane resin, or acrylate-silica resin is applied, which is hardened to form a hard coat layer.

Abstract: A method and structure for forming an ink jet printhead can include the use of a transfer pad to transfer an adhesive solution to an ink jet printhead substrate. The adhesive solution can be placed within a patterned recess of a cliché and then an upper surface of the adhesive solution can be gelled. A surface of the transfer pad contacts the gelled upper surface and transfers the adhesive solution to the ink jet printhead substrate. During the transfer, a lower surface of the adhesive solution gels. During contact with the ink jet printhead substrate, the gelled lower surface adheres to the ink jet printhead substrate while the gelled upper surface releases from the transfer pad.

Abstract: An optical device includes: a light transmissive first substrate; a light transmissive second substrate; a polarizing layer disposed between the first substrate and the second substrate; a first bonding layer which bonds the first substrate to the polarizing layer; and a second bonding layer which bonds the second substrate to the polarizing layer, wherein the first bonding layer is an adhesive layer, and the second bonding layer contains a structure of siloxane (Si—O) and a leaving group. By forming the first bonding layer of an adhesive layer, a necessary strength can be ensured, and also the optical properties can be enhanced by absorbing the irregularities of the polarizing layer formed of a synthetic resin so as to prevent the contamination with air bubbles. Since the time of exposure of the polarizing layer to heat generated by a plasma can be decreased, the polarizing layer is not deteriorated.

Abstract: A process for coating a substrate comprising the sequential steps of (a) providing a transfer sheet provided with a printed powder coating, (b) applying the transfer sheet onto the substrate with the powder coating in contact with the substrate, (c) removing the transfer sheet from the powder coating and (d) curing the powder coating on the substrate.

Abstract: Apparatus and methods for fulfillment of patient prescription orders by adapting a standard or stock container pre-filled with medication or the like for use as a patient-specific container through precise application of patient-specific information to the pre-filled container. Precise placement of the patient-specific information to the pre-filled container enables pharmacy management to fully utilize valuable information provided with the pre-filled container, thereby improving the quality of service to the patient while making the process of prescription order fulfillment more efficient. In general, preferred embodiments comprise control apparatus and information-application apparatus. In embodiments, the information-application apparatus is adapted to place a patient-specific label on the container. Preferred forms of the information-application apparatus include a label printer and a positioner. The preferred printer applies patient-specific information on a label.

Abstract: There is provided an image transfer sheet, including: an image receiving layer; a bonding layer; a transparent support; and a substrate, in this order, wherein a peeling strength between the transparent support and the substrate is lower than a peeling strength between the image receiving layer and the bonding layer, and between the bonding layer and the transparent support.

Abstract: Methods for fastening nanoscale structures within an anchoring structure to form a nanostructure composite and nanostructure composites formed therefrom. A primary fluid layer is formed on an anchoring substrate. Nanostructures are provided on an initial substrate, the nanostructures having a defined height and orientation with respect to the initial substrate. The nanostructures are introduced to a desired depth in the primary fluid layer, such that the orientation of the nanostructures relative to the growth substrate is substantially maintained. The primary fluid layer comprises one or more fluid layers. Ones of multiple fluid layers are selected such that when altered to form an anchoring structure, a portion of the anchoring structure can be removed, permitting exposure of at least a portion of the nanostructures from the anchoring structure in which they are affixed. The growth substrate is removed. Ends or other parts of nanostructures may be exposed from the anchoring structure.

Abstract: A graphic transfer assembly is disclosed. The graphic transfer assembly includes an inflatable member that is capable of expanding to fill the interior of an article of footwear. The graphic transfer assembly can include a fluid pump for filling the inflatable member.

Abstract: A wrappable protective sleeve for providing protection to at least one elongate member contained therein and methods of construction and use thereof are provided. The sleeve includes a flexible textile wall having opposite inner and outer faces bounded by opposite edges and opposite ends. The opposite edges extend generally parallel to one another between the opposite ends. A pair of adhesive layers is bonded to the inner face, with each of the adhesive layers being spaced from one another. The adhesive layers extend between the opposite ends adjacent the opposite edges. Further, a release paper is releasably adhered to the pair of adhesive layers for subsequent removal and use of the sleeve.

Abstract: The invention relates to a method and a transfer strip for decorating surfaces, in particular for decorating outer packagings. A transfer strip comprising a strip-like backing film (11), a decorative layer (13) and a release layer (12) arranged between the decorative layer (13) and the backing film is provided. The decorative layer (13) has a multiplicity of identical optically variable decorative elements, which are arranged in first area regions, which are separate from one another and spaced apart from one another in the longitudinal direction of the transfer strip. The decorative layer (13) has second area regions, which are separate from one another and spaced apart from one another in the longitudinal direction of the transfer strip and in which the decorative layer (13) has one or more individualizable layers for providing respectively different machine-readable optical markings.

Abstract: A method for preparing a composite fabric includes: casting a foamed liquid adhesive onto a smooth release-coated web; applying a fabric to the wet adhesive; fixing the adhesive to the fabric by drying; removing the release-coated web from the adhesive coated intermediate; depositing onto an embossed casting substrate a layer of liquid skin coat composition; applying the porous adhesive layer of the adhesive-coated intermediate to the wet skin layer; drying to fix the skin layer to the adhesive-coated intermediate; and separating the embossed casting substrate from the dried composite to provide the composite fabric. The resulting composite fabrics look and feel like soft shell composite fabrics.

Abstract: A method for transfer of a two-dimensional material includes forming a spreading layer of a two-dimensional material on a first substrate. The spreading layer has at least one monolayer. A stressor layer is formed on the spreading layer. The stressor layer is configured to apply stress to a closest monolayer of the spreading layer. The closest monolayer is exfoliated by mechanically splitting the spreading layer wherein at least the closest monolayer remains on the stressor layer. The at least one monolayer is stamped against a second substrate to adhere remnants of the two-dimensional material on the at least one monolayer to the second substrate to provide a single monolayer on the stressor layer. The single monolayer is transferred to a third substrate.

Abstract: The use of a heat idler moveable along a path provides speed and flexibility in the heat labeling of containers.

Abstract: A method for producing an analysis tape for fluid samples, in particular body fluids, is proposed. In the method, diagnostic auxiliary labels are transferred to a carrier tape, wherein at least one vacuum roller is used for the transfer of the diagnostic auxiliary labels. The diagnostic auxiliary labels are detected on the vacuum roller. At least one tape position of the carrier tape is furthermore detected. The transfer of the auxiliary labels to the carrier tape is effected in accordance with the detected auxiliary labels and the tape position.

Abstract: A method for making a carbon nanotube film is provided. First, a carbon nanotube array is formed on a grown substrate. The carbon nanotube array is pressed with a first substrate using a first pressing force to form a carbon nanotube film precursor. Then the first substrate and the grown substrate are separated, and the carbon nanotube film precursor is transferred onto the first substrate. After that, the carbon nanotube film precursor is pressed using a second substrate with a second pressing force. Lastly, the first substrate and the second substrate is separated, with part of the carbon nanotube precursor transferred to the second substrate to form the carbon nanotube film.

Abstract: A composite fabric includes: a fabric backing; an adhesive layer; a midlayer barrier bonded to the fabric backing by the adhesive layer; and an external barrier bonded to the midlayer barrier, wherein the composite fabric has a hydrostatic pressure resistance of at least 100 psi and is sufficiently flexible such that it can be formed into a tube and everted. A process and an apparatus for producing the composite fabric are also disclosed. The composite fabric is particularly suitable for use as a liner in a cured-in-place pipe repair method.

Abstract: Row bars are attached to a lapping ring by a first single-sided adhesive film that adheres to the row bars and are secured to a first lapping ring by a vacuum. After backside lapping is performed on the row bars, the row bars are transferred to a second lapping ring with second single-sided adhesive film by compressing the row bars between the adhesive films and deactivating the vacuum, thereby releasing the row bars from the first lapping ring and providing ring-to-ring transfer without peeling the row bars off the first single-sided adhesive film. Lapping rings used for this process include vacuum channels and slots for holding the row bars so that the top surfaces of the row bars and lapping ring are substantially flat. Ring-to-ring transfer tools are used to transfer row bars between the backside lapping ring and the frontside lapping ring with minimal handling of the row bars.

Abstract: An ink-jettable adhesive composition comprising a polyurethane dispersion and a stabilizer is produced that can be used to form an image transfer system. The image transfer system generally comprises an adhesive layer formed from the adhesive composition, an ink image, and a removable transfer substrate. The image transfer system is capable of depositing the ink image and adhesive layer onto the surface of a textile. The resulting adhered ink image and adhesive layer can produce a durable and vivid image on a large variety of textiles.

Abstract: A pressure-sensitive adhesive label comprising: recording paper including a recording surface; a pressure-sensitive adhesive layer placed on a rear surface of the recording paper on an opposite side of the recording surface; and a function layer placed on the pressure-sensitive adhesive layer, wherein a surface of the pressure-sensitive adhesive layer on the function layer side has a smoother surface than the rear surface of the recording paper, and the function layer is configured to be opened by heating to expose the pressure-sensitive adhesive layer.

Abstract: A method for manufacturing a color electrophoretic display device includes the following steps. First, a substrate having a displaying region and a circuit region around the displaying region is provided. Next, a driving array is formed in the displaying region. Subsequently, an electrophoretic display layer is formed on the driving array. Afterwards, a thermal transfer process is performed so that a color filter layer is formed on the electrophoretic display layer. The method can increase the production eligibility rate of the color electrophoretic display device, thereby improving the display quality of the color electrophoretic display device.

Abstract: A method of creating a substrate containing multiple holographic images. The method includes dividing the substrate into a plurality of equally sized print surfaces and placing a holographic image on each of the print surfaces. Wherein the holographic image is placed at substantially the same location on each of the print surfaces.