Abstract: A method and apparatus for transferring formed adhesive elements from a reservoir (30) containing plural formed adhesive elements (12) to a bonding part attachable to a glass surface or other substrate through the use of adhesives. Transfer of the formed adhesive element to the bonding part (14) is accomplished by use of a vacuum tool (10) having a vacuum outlet, an internal plenum, and a series of vacuum lines formed in an adhesive element holding face. The vacuum tool is positioned over a reservoir of formed adhesive elements. Once the formed adhesive elements have been captured by the vacuum tool (10) the tool is used to place them into contact with the heated bonding part (14) directly or indirectly by intermediate placement onto a matrix (60) having a plurality of ejector pins (72) movably fitted therein. The ejector pins move the formed adhesive elements into position against the bonding part.

Abstract: Disclosed is a transparent conductive film including a substrate, and a conductive composite on the substrate, wherein the conductive composite includes conductive carbon material and a non-carbon inorganic material having a surface modified by an electron-withdrawing group, and the non-carbon inorganic material contacts the conductive carbon material. Furthermore, the disclosed provides a method of manufacturing the transparent conductive film.

Abstract: A resin-rich peel ply that does not leave behind residual fibers after peeling and can work well with different resin-based composite substrates. The resin-rich peel ply is composed of a woven fabric impregnated with a resin matrix different from the resin matrix of the composite substrate. The peel ply is designed such that, upon manual removal of the peel ply from the composite substrate's surface, a thin film of the peel ply resin remains on the composite substrate's surface to create a bondable surface capable of bonding with another composite substrate, but no fibrous material from the woven fabric remains on the same surface.

Abstract: The present invention provides a semiconductor device and a fabricating method thereof. The fabricating method comprises: providing a first substrate; forming a soft dry film having an adhesive film and a release film; sticking the soft dry film on the first substrate with the adhesive film; removing the release film; sticking a second substrate on the adhesive film; and heating the adhesive film to solidify the adhesive film to form a solid adhesive film. The semiconductor device comprises: a first substrate, a solid adhesive film, and a second substrate. The solid adhesive film is formed on the first substrate, and the second substrate is formed on the solid adhesive film.

Abstract: A template material for use in attaching items, such as rhinestones and the like, to a base material, including the material of an article of clothing or an accessory item such as a hat, belt or purse. The template material comprises a flock material and a backing material, such as vinyl. A back surface of the flock is joined to the front surface of the vinyl to define a flock top surface and sticky bottom surface of the template material. A method of manufacturing the template material uses heat to join the flock to the vinyl. A method of utilizing the template material comprises cutting holes in the template material in a pattern, filling each hole with an item, removing the items from the template with a plastic sheet, placing the plastic sheet on a base material and applying heat to the items to attach them to the base material.

Abstract: A tape adhering device including: a drawing roller for drawing out a tape; a tape fixing means for fixing one portion of the tape drawn out from the drawing roller; a tape drawing means for drawing out a predetermined amount of tape, which is fixed by the tape fixing means, from the drawing roller between the tape fixing means and the drawing roller; and a tape adhering means for adhering the tape, which is located in the downstream of the tape fixing means, onto an object to be adhered under the condition that fixing operation of the tape by the tape fixing means is released.

Abstract: The present invention relates to a process for transferring at least one coating onto at least one geometrically defined surface of a lens substrate to produced a lens substrate coated with at least one functional coating adhering to at least one geometrically defined surface through a layer of transparent adhesive composition.

Abstract: Graphene transferring members, graphene transferrer, methods of transferring graphene, and methods of fabricating a graphene device, may include a metal thin-film layer pattern and a graphene layer sequentially stacked on an adhesive member. The metal thin-film layer and the graphene layer may have the same shape. After transferring the graphene layer onto a transfer-target substrate during the fabrication of a graphene device, the metal thin-film layer is patterned to form electrodes on respective ends of the graphene layer by removing a portion of the metal thin-film layer.

Abstract: The present invention relates to a production process for a decorative sheet comprising a step in which a primer layer is formed on a releasing film having a smooth surface, a step in which a design layer is formed on the above primer layer, a step in which the primer layer and the design layer are transferred on a base material, a step in which the releasing film on the base material is peeled off, a step in which an ionizing radiation curable resin composition is laminated on the primer layer formed on the base material and a step in which the above ionizing radiation curable resin composition is cross-linked and cured to form a surface protective layer.

Abstract: A method of transferring graphene, the method including: preparing a graphene forming structure including a base member, an oxide layer that is hydrophilic and is formed on the base member, a metal catalyst layer that is hydrophobic and is formed on the oxide layer, and graphene that is formed on the metal catalyst layer; attaching the graphene forming structure on a surface of a first carrier; separating the oxide layer from the metal catalyst layer by applying steam to the graphene forming structure; and removing the metal catalyst layer.

Abstract: A method for combining with adhesive at least two flat products positioned at least partially one above the other is provided. The method includes moving first flat products in an overlapping flow along a guiding line in a conveying direction and separating the first flat products into a non-overlapping flow after leaving the guiding line and while being conveyed through an underneath-arranged conveying region. The method also includes supplying second flat products from underneath the first flat products with a synchronous time relative to the first flat products. The second flat products each have an adhesive surface. The method further includes combining a respective one of the first flat products along the adhesive covered surface of an underneath supplied respective one of the second flat products.

Abstract: An additive manufacturing system comprising a transfer medium configured to receive the layers from a imaging engine, a heater configured to heat the layers on the transfer medium, and a layer transfusion assembly that includes a build platform, and is configured to transfuse the heated layers onto the build platform in a layer-by-layer manner to print a three-dimensional part.

Abstract: A method for bonding a thin film piece includes: forming a support layer on each upper face of a plurality of thin film pieces; fixing the plurality of thin film pieces to a first substrate through a temporary fixing layer provided on a lower face of the first substrate so that the temporary fixing layer contacts with the upper face and at least a part of a side face of each support layer; bonding a lower face of the plurality of thin film pieces to a second substrate; and removing the first substrate from the plurality of thin film pieces by removing at least one of the support layer and the temporary fixing layer.

Abstract: An improved process for manufacture of polymer coated composite substrates is described. a coated composite substrate is prepared in the press by applying a layer of a primer coating composition to the surface of a compressible mat comprising fibers and/or particles and a resin binder. The primer coating composition is formulated preferably as a fast setting polymer latex capable of forming a chemically crosslinked polymer matrix when applied to the surface of a compressible mat. a thermosetting top coat composition can be applied directly over the wet primer coating composition before heat-processing the mat to improve surface quality and release characteristics. Compressing and heating the coated mat produces a primed composite substrate directly out of the press.

Abstract: A method for making a plurality of electromechanical transducers includes, depositing a layer of conductive material attached to a first side of a piezoelectric layer to form a laminar structure, attaching the laminar structure to a rigid carrier substrate using a removable double-sided tape, forming piezoelectric transducers, attaching the electromechanical transducer to a fluid channel substructure, and removing the rigid carrier substrate and the double-sided tape.

Abstract: Provided is an image transfer material, comprising a support, optionally at least one barrier layer, a melt transfer layer, and an image receiving layer. Also provided is a process for preparing the image transfer material. Further provided is a heat transfer process using the disclosed material. In the heat transfer process, after imaging, the image receiving layer and melt transfer layer are peeled away from the optionally barrier-coated support material and placed, preferably image side up, on top of a receptor element. A non-stick sheet is then optionally placed over the imaged peeled material and heat is applied to the top of the optional non stick sheet. The melt transfer layer then melts and adheres the image to the receptor element. A composition comprising: at least one self-crosslinking polymer, and at least one dye retention aid.

Abstract: There is described a process for the production of a multilayer body (4) having an electrically conductive layer (421) arranged on a carrier layer (41), in which there is provided a transfer film (5) having a transfer layer (52) of an electrically conductive polymer. The electrically conductive layer is transferred from the transfer film (5) on to the multilayer body (4). There are also provided a transfer film and a multilayer body produced in accordance with the process.

Abstract: According to various embodiments, a film assembly may include a protective film, first and second removable opposing tabs, an adhesive, and a split release liner. The first and second opposing tabs may be configured to facilitate the alignment of the protective film with respect to a surface of a portable electronic device. Once aligned, a minority portion of the split release liner may be removed exposing a minority portion of the protective film coated with the adhesive. The minority portion of the protective film may then be adhered to the surface of the portable electronic device. Subsequently, the remaining sections of the split release liner may be removed and the protective film may be fully adhered to the surface of the portable electronic device. Once fully adhered, the first and second opposing tabs may be removed.

Abstract: A heat transferable material includes a light stabilizer that is an N-oxyl radical derived from a hindered amine and having the formula, wherein R1, R2, R5, and R6 are each independently selected from a straight or branched C1-C6 alkyl or alkene, and R3 and R4 are each independently selected from H, CH2CH3, CH3, OH, OR, COOH, or COOR, wherein R is a straight or branched C1-C6 alkyl or alkene, and having a molecular weight of 600 or less, except that all of R1, R2, R5, and R6 are not methyl when both R3 and R4 are hydrogen. The heat transferable material can be in one or more sections or patches on a thermal donor element to provide a protective overcoat material. The heat transferable material provides better image stability and improved iridescence when applied to a receiver.

Abstract: A method for auxiliary assembling micro-components though liquid medium. This method includes following steps: providing a substrate, an adhesive layer, at least one micro-component and a liquid medium, wherein the adhesive layer is on the substrate and the micro-component and the liquid medium are on the adhesive layer. The adhesive is used for adhering one side of the micro-component and another side of the micro-components is disposed with is disposed with the liquid medium. Then, the another side of the micro-component which is disposed with the liquid medium touches a target area, and the substrate moves toward the target zone at a speed that is smaller than 90 ?m/s for placing the micro-component on the target zone or moves away from the target zone at a speed greater than 4370 ?m/s for picking up the micro-component from the target zone.

Abstract: The invention relates to a method for transferring a nano-layer (1) from a first substrate (5, 105) to a second substrate (30, 130), wherein the nano-layer (1) comprises a self-aggregating monolayer with cross-linked phenyl units and/or a mono-atomic graphite layer (graphene), wherein the method comprises the following steps: a. applying a transfer medium (20, 120) onto nano-layer (1), wherein in this step or afterwards the transfer medium (20, 120) is transformed from a liquid or gaseous phase in a solid phase; b. separating the transfer medium (20, 120) and the nano-layer (1) from the first substrate (5, 105); and c. applying the transfer medium (20, 120) and the nano-layer (1) onto the second substrate (30, 130); and d. removing the transfer medium (20, 120).

Abstract: A heat transfer material kit is disclosed that includes a first image transfer material that includes a printable non-porous surface, and a second image transfer material that includes an outer layer having a film forming binder and thermoplastic particles. A method of using the kit is disclosed that includes the steps of a) imaging the substantially non-porous printable surface to form an imaged surface having printed and un-printed areas; b) positioning the outer layer adjacent the imaged surface; c) transferring a portion of the outer layer to the printed area while transferring a lesser portion of the outer layer to the non-printed area to form a coated imaged surface having a non-printed area with less coating than the printed area; and d) thereafter transferring the coated image to a substrate. Alternate methods of using the kit and applying images to substrates that provide good image appearance and durability are also disclosed.

Abstract: A heat transfer material kit is disclosed that includes a first image transfer material that includes a printable non-porous surface, and a second image transfer material that includes an outer layer having a film forming binder and thermoplastic particles. The film forming binder is polar. A method of using the kit is disclosed that includes the steps of a) imaging the substantially non-porous printable surface to form an imaged surface having printed and un-printed areas; b) positioning the outer layer adjacent the imaged surface; c) transferring a portion of the outer layer to the printed area while transferring a lesser portion of the outer layer to the non-printed area to form a coated imaged surface having a non-printed area with less coating than the printed area; and d) thereafter transferring the coated image to a substrate. Alternate methods of using the kit and applying images to substrates that provide good image appearance and durability are also disclosed.

Abstract: A device for manufacturing an organic light-emitting display panel and a method of manufacturing an organic light-emitting display panel by using the same. A device for manufacturing an organic light-emitting display panel includes a plurality of chambers; a deposition unit configured to form a transfer layer on a film supplied into the plurality of chambers in a roll-to-roll process; and a laser thermal transfer device configured to transfer a pattern of the transfer layer formed on the film onto a substrate that is supplied into a chamber of the plurality of chambers.

Abstract: A strelchable wrap for holding a sheet with sublimable ink against an object, such as a mug, for transferring an image from the sheet to the mug. The wrap has two layers of elastomeric, rubber material glued together. The inner layer has a greater sponginess to conform the sheet to the mug, while the outer layer has greater strength to stretch and hold the web over the sheet. Flexible rods, held at the ends of the rubber sheet by the outer layer glued to itself, attach the web with the sheet to the mug. The rods connect together above and below the mug and hold the rubber web in a stretched condition with the inked sheet in contact with the mug. The rods also extend above and below the rubber web which, in turn, is wider than the mug. Connecting together the ends of the connector rods permits their joinder.

Abstract: A method for removing a carbonization catalyst from a graphene sheet, the method includes contacting the carbonization catalyst with a salt solution, which is capable of oxidizing the carbonization catalyst.

Abstract: A method sticks onto a curved surface of a substrate a functional film (4) that has a substantially planar initial shape. To this end, the film (4) is retained on a deformable membrane (1) by connecting means (2) that allow portions of said film to slip relative to the membrane when said membrane is deformed. This reduces stresses that are created in the film by the deformation. The method is adapted for applying a functional film to an ophthalmic lens.

Abstract: A method for producing glass-polymer laminates is provided. The method includes applying a glass fit material onto a transfer substrate to form a coated substrate, exposing the coated substrate to a temperature above the melting temperature of the glass frit material to form a glass layer on the transfer substrate, laminating the glass layer film and a polymer substrate and removing the transfer substrate from the glass layer to form a glass-polymer laminate.

Abstract: A laminate donor element can be used to transfer a composite of a metal grid and an electronically conductive polymer to a receiver sheet for use in various devices. The laminate donor element has a donor substrate, a metal grid that is disposed over only portions of the donor substrate, leaving portions of the substrate uncovered by the metal grid, and an electronically conductive polymer that covers the portions of the donor substrate that are uncovered by the metal grid. The composite of metal grid and electronically conductive polymer exhibits a peel force of less than or equal to 40 g/cm for separation from the donor substrate at room temperature. The resulting article has a substrate on which a reverse composite of the metal grid and electronically conductive polymer is disposed, which article can be incorporated into various devices.

Abstract: There is disclosed a glass treatment for treating exterior glass to prevent bird collisions with the glass. The treatment consists of a plurality of visible markings applied to an exterior surface of the glass, the plurality of markings extending substantially across the entire exterior surface. The markings are separated from each other by a vertical distance not exceeding 2.5 inches and by a horizontal distance not exceeding 4.5 inches. The markings occupy no more than 15% of the exterior surface of the glass.

Abstract: Surface-modified adhesives may be prepared by contacting an adhesive layer to an at least partially discontinuous layer on a releasing substrate and removing the adhesive layer such that at least a portion of the at least partially discontinuous layer adheres to the adhesive surface. The modified adhesive surface remains an adhesive surface. The modified adhesive layer can be used to prepare adhesive articles, including articles containing multiple surface-modified adhesive layers.

Abstract: An air conveyor is positioned on a tabbing machine and includes a housing having an air chamber and a web entry and web exit and air port communicating with the air chamber. An air nozzle assembly is positioned within the air chamber and includes upper and lower nozzle plates that extend across the air chamber and spaced from each other to form a web delivery channel that is aligned with the web entry and web exit. Each of the nozzle plates includes a plurality of air nozzles extending through the nozzle plate and configured to pass pressurized air from the air chamber into the web delivery channel such that a web of material entering the web entry is drawn, for example, by venturi pressure, from the web entry through the web delivery channel and out the web exit.

Abstract: A production method of a multi-layer printed wiring board containing the following steps (1)-(5): (1) a temporary fitting preparatory step including conveying an adhesive sheet from an adhesive sheet roll wherein an adhesive sheet having a prepreg formed on a support film is wound in a roll and placing the adhesive sheet such that a prepreg surface contacts one or both of the surfaces of a circuit board, (2) a temporary fitting step for temporarily fitting the adhesive sheet to the circuit board, including partially adhering the adhesive sheet to the circuit board by heating and pressing a part of the adhesive sheet from the support film side, and cutting the adhesive sheet according to the size of the circuit board with a cutter, (3) a laminating step including heating and pressing the temporarily fitted adhesive sheet under reduced pressure to laminate the adhesive sheet on the circuit board, (4) a thermal curing step including forming an insulating layer by thermally curing the prepreg, and (5) a detachin

Abstract: A flexible piezoelectric structure and a method of making the structure are disclosed. A piezoelectric film having a relatively high piezoelectric coefficient is attached to a flexible substrate. The piezoelectric film is fabricated on a different substrate and transferred to the flexible substrate by contact.

Abstract: 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. After a cut piece 4S of an ACF tape 4 is pressed against and adhered to a target adhering area Sa on a substrate 2 by a press tool 22, a transfer base 14 is transferred, and a tape member Tp is then forwardly conveyed in synchronism with transfer of the transfer base 14 in such a way that the press tool 22 comes to an elevated position above the target adhering area Sa on the substrate 2 where the cut piece 4S of the ACF tape 4 is to be adhered, thereby peeling a separator Sp off from the cut piece 4S of the ACF tape 4. A tape cutting unit 24 is disposed downstream of a region Rg of, immediately below the press tool 22, of the tape member Tp conveyed by the tape conveyor unit 23 with respect to a forward conveyance direction of the tape member Tp.

Abstract: An ultracapacitor includes at least one electrode that includes carbon nanotubes. The carbon nanotubes may be applied in a variety of ways, and a plurality of layers may be included. Methods of fabrication of carbon nanotubes and ultracapacitors are provided.

Abstract: A tape preparation is provided which does not use a backing such as a plastic film, knit or a woven fabric, or a nonwoven fabric, has very high conformability to skin, and is easy to use at the time of application. There is provided a tape preparation 1 that is produced by laminating a drug-containing adhesive layer 4 on the printed ink layer 3 side of a cover film 2 with printing thereon and covering the drug-containing adhesive layer with a release film 5. In this tape preparation, the adhesive strength between the cover film and the printed ink layer is higher than the adhesive strength between the drug-containing adhesive layer and the release film, and the adhesive strength between the printed ink layer and the drug-containing adhesive layer is higher than the adhesive strength between the cover film and the printed ink layer.

Abstract: A method of producing an electronic member includes: placing a laminated ink at a depression section of an intaglio plate having the depression section, or at a lyophilic part of a lithographic plate having the lyophilic part and a liquid-repellent part, the laminated ink including an electronic material layer and an adhesive material layer laminated in this order from a bottom side of the depression section or the lyophilic part; and transferring the laminated ink to a surface of a substrate directly or after transferring the laminated ink to a blanket temporarily, wherein surface free energy of each of the electronic material layer and the adhesive material layer satisfies relational expressions (1) and (2) as follows.

Abstract: Disclosed are a primer layer for plating process exhibiting high adhesiveness to an electroless copper plating and capable of coping with high density of wirings of semiconductor packages; a laminate for wiring board having the primer layer and a method for manufacture thereof; and a multilayer wiring board having the primer layer and a method for manufacture thereof. The primer layer is formed of a resin composition including (A) a polyfunctional epoxy resin, (B) an epoxy resin curing agent, and (C) a phenolic hydroxyl group-containing polybutadiene-modified polyamide resin having specified structural units, wherein a blending proportion of the component (C) is 5 parts by mass or more and less than 25 parts by mass based on 100 parts by mass of a total sum of the component (A) and the component (B).

Abstract: The invention relates to a method for the provision of activated temperature-sensitive and/or time-sensitive indicators for product marking. A first variant is characterized by the activation of an indicator and the subsequent application of a protective filter to the indicator, with the indicator being conveyed along an activation device and along a protective filter application unit subsequent to it in the conveying direction. A second variant is characterized by the activation of an indicator already provided with a protective filter. The invention furthermore relates to apparatus for the carrying out of the named methods as well as to a product marking which was manufactured in accordance with the methods in accordance with the invention.

Abstract: The invention relates to a highly flexible sheet composite material comprising a block flexible foam and a layer of whipped foam made of polyurethane-based dispersions two-dimensionally bonded thereto, a process for preparing such a composite material, and the use thereof.

Abstract: To deposit carbon nanotubes onto a substrate, an at least partially porous film is prepared so that a surface of the film has a layer of carbon nanotubes thereon. The film is positioned in relation to a surface of the substrate such that the surface of the film having the layer of carbon nanotubes is brought into contact with the surface of the substrate. Pressure is applied to the film to attach the film, including the layer of carbon nanotubes, to the surface of the substrate.

Abstract: The present disclosure relates to a method for making a graphene/carbon nanotube composite structure. In the method, at least one graphene film is located on a substrate. At least one carbon nanotube layer is combined with the at least one graphene film located on the substrate to form a substrate/graphene/carbon nanotube composite structure. The at least one graphene film is in contact with the at least one carbon nanotube layer in the substrate/graphene/carbon nanotube composite structure. The substrate is removed from the substrate/graphene/carbon nanotube composite structure, thereby forming a graphene/carbon nanotube composite structure.

Abstract: The present invention relates to a coating composition, comprising shaped transition metal, especially silver, particles and a binder, wherein the ratio of pigment to binder is such that the resulting coating shows an angle dependent colour change. When the coating compositions of the present invention are used in coating a hologram the obtained products show a an angle dependent colour change (flip/flop effect), different colours in reflection and transmission, an extremely bright OVD image and extremely strong rainbow effect, high purity and contrast.

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 having the following formula, wherein R1, R2, R5, and R6 are each independently selected from a straight or branched C1-C6 alkyl, and R3 and R4 are each independently selected from H, OH, OR, COOH, or COOR, wherein R is a straight or branched C1-C6 alkyl or alkene, and having a molecular weight of 600 or less, is described. The heat transferable material can be in one or more sections or patches on a thermal donor element to provide a protective overcoat material. Optionally, a patch in the donor element can also include a dye. The heat transferable material provides better image stability and improved iridescence when applied to a thermal, inkjet, electophotographic, or silver halide receiver.

Abstract: An object is to improve use efficiency of an evaporation material, to reduce manufacturing cost of a light-emitting device, and to reduce manufacturing time needed for a light-emitting device including a layer containing an organic compound. The pressure of a film formation chamber is reduced, a plate is rapidly heated by heat conduction or heat radiation by using a heat source, a material layer on a plate is vaporized in a short time to be evaporated to a substrate on which the material layer is to be formed (formation substrate), and then the material layer is formed on the formation substrate. The area of the plate that is heated rapidly is set to have the same size as the formation substrate and film formation on the formation substrate is completed by one application of heat.

Abstract: A via hole forming method and a multilayered board manufacturing method improve manufacturing yield by reducing the required processes. The via hole forming method includes a first step of forming a toner image by attaching toner particles, containing a conductive material and having a protruding portion, onto the surface of a first photosensitive member so that the protruding portion is directed to the outside; and a second step of opposing the surface of the first photosensitive member to one principal surface of a green sheet containing an insulating material and transferring the toner image to the one principal surface of the green sheet so that the protruding portions of the toner particles protrude into the green sheet so as to reach the other principal surface of the green sheet and the toner particles are buried in the green sheet. The via holes are formed using an electrophotographic printing method.

Abstract: A method for forming a dye sublimation image in a plastic substrate with a sheet having an image formed thereon of a sublimatic dyestuff is provided. The image on the sheet with a treatment that deposits a silicon compound is placed against a first surface of the substrate. The sheet is heated to a sublimation temperature, which causes the image of the sheet to sublimate into the substrate. The sheet is cooled to a release temperature. The sheet is removed from the substrate.

Abstract: A method of applying a durable process mark to a glass article using a laser. A transfer sheet is applied to the glass substrate, the transfer sheet includes a carrier layer with a first adhesive layer, adhered partially to a bottom side of the carrier layer. On the face of the carrier layer there are a first and a second pigment layer. The transfer sheet is lased, forming a durable process mark in the glass article.

Abstract: The present disclosure provides an apparatus for manufacturing a carbon nanotube heat sink. The apparatus includes a board, and a plurality of first and second carbon nanotubes formed on the board. The first carbon nanotubes and the second nanotubes are grown along a substantially same direction from the board. A height difference exists between a common free end of the first carbon nanotubes and a common free end of the second carbon nanotubes. A method for manufacturing multiple carbon nanotube heat sinks is also provided.