Abstract: In one aspect, build materials and support materials for use with a 3D printer are described herein. Such materials include a phosphor component in combination with other components. In some embodiments, the phosphor component of a build material or support material is present in the material in an amount of 0.001-0.5 wt. % and has a peak photoluminescence (PL) emission wavelength of 430-750 nm and a photoluminescence quantum yield (QY) of 0.10-1.

Abstract: The embodiments relate to a polyamide-based composite film that not only has excellent curl characteristics, mechanical properties, and optical properties, but also exhibits a privacy protection effect at a wide angle of view and glossiness characteristics similar to those glass at a main angle of view, and to a display device comprising the same. There are provided a polyamide-based composite film that comprises a base film comprising a polyamide-based polymer; and a functional layer disposed on the base film, wherein a glossiness control value according to Equation 1 is 0 or more, and a displace device comprising the same.

Abstract: Provided are a combination of a thermal transfer sheet and an intermediate transfer medium which is capable of accurately transferring only a transfer layer of the intermediate transfer medium desired to be transferred onto a transfer receiving article in the production of a print, and a thermal transfer sheet which is used in combination with an intermediate transfer medium. Also provided are a method for producing a print, comprising accurately transferring only a transfer layer of an intermediate transfer medium desired to be transferred onto a transfer receiving article, and a thermal transfer printer which is used in this method for producing a print. In the thermal transfer sheet which is used in combination with an intermediate transfer medium, inhibit layer 2 is disposed on substrate 1, and the inhibit layer 2 contains a carnauba wax.

Abstract: Methods, apparatus and system for decorating plastic articles having an uneven surface or hollow structure are disclosed. An assembly comprising a transfer pad and a flexible heat transfer die comprising a thermal interface material (TIM) replace the hard rubber die in a hot-stamping process to fuse indicia into the surface. The assembly modifies ordinary pad printing into a hot-stamping process that transfers indicia onto uneven surfaces. A pad printing machine or other robotics is used to move the assembly from a position of heating to a position of compressing the ink transfer to the surface of the article.

Abstract: In one aspect, build materials and support materials for use with a 3D printer are described herein. Such materials include a phosphor component in combination with other components. In some embodiments, the phosphor component of a build material or support material is present in the material in an amount of 0.001-0.5 wt. % and has a peak photoluminescence (PL) emission wavelength of 430-750 nm and a photoluminescence quantum yield (QY) of 0.10-1.

Abstract: Methods, apparatus and system for decorating plastic articles having an uneven surface or hollow structure are disclosed. An assembly comprising a transfer pad and a flexible heat transfer die comprising a thermal interface material (TIM) replace the hard rubber die in a hot-stamping process to fuse indicia into the surface. The assembly modifies ordinary pad printing into a hot-stamping process that transfers indicia onto uneven surfaces. A pad printing machine or other robotics is used to move the assembly from a position of heating to a position of compressing the ink transfer to the surface of the article.

Abstract: Methods, apparatus and system for decorating plastic articles having an uneven surface or hollow structure are disclosed. An assembly comprising a transfer pad and a flexible heat transfer die comprising a thermal interface material (TIM) replace the hard rubber die in a hot-stamping process to fuse indicia into the surface. The assembly modifies ordinary pad printing into a hot-stamping process that transfers indicia onto uneven surfaces. A pad printing machine or other robotics is used to move the assembly from a position of heating to a position of compressing the ink transfer to the surface of the article.

Abstract: Methods, apparatus and system for decorating plastic articles having an uneven surface or hollow structure are disclosed. An assembly comprising a transfer pad and a flexible heat transfer die comprising a thermal interface material (TIM) replace the hard rubber die in a hot-stamping process to fuse indicia into the surface. The assembly modifies ordinary pad printing into a hot-stamping process that transfers indicia onto uneven surfaces. A pad printing machine or other robotics is used to move the assembly from a position of heating to a position of compressing the ink transfer to the surface of the article.

Abstract: The present invention provides a transfer film that allows a transfer layer to have satisfactory transferability and can provide a print with high durability. The present invention solves the above problem by a transfer film 100 in which an adhesion layer 7, a release layer 2, and a transfer layer 10 are provided in this order on a substrate 1, wherein the transfer layer 10 has a layered structure in which a protective layer 3 and an adhesive layer 5 are layered in this order from the side of the substrate, the protective layer 3 is allowed to contain an active ray-cured resin formed by curing an active ray-curable resin by an active ray, and the adhesion layer 7 is allowed to contain a cured binder resin which is a cured product of a binder resin and a curing agent.

Abstract: Provided are energy curable high-stretch inks and coatings for heat transfer labels. The inks and coatings include monofunctional monomers/oligomers, thermoplastic inert resins, and zero or a limited amount of multifunctional monomers/oligomers and exhibit good stretchability and surface resistance, such as scratch resistance and solvent (water, oil) resistance. Also provided are methods of using the high stretch inks in heat-transfer label (HTL) applications.

Abstract: The thermal transfer sheet according to the present invention that has in the order mentioned, a substrate, a release layer, a colored layer, and an adhesion layer; and is characterized in that the colored layer contains a colorant and a polyester-based resin; the adhesion layer contains a polyester-based resin; a ratio of the thickness of the release layer to the total thickness of the colored layer and the adhesion layer (the thickness of the release layer/(the thickness of the colored layer+the thickness of the adhesion layer)) is not less than 2/3 and not more than 3/2; and the total thickness of the release layer, the colored layer, and the adhesion layer is not less than 1.0 ?m and not more than 2.0 ?m.

Abstract: The thermal transfer sheet according to the present invention that has, in the order mentioned, a substrate, a colored layer, and an adhesion layer; and wherein the colored layer contains a colorant, polyester-based resin A, and polyester-based resin B; the number average molecular weight of the polyester-based resin A is not less than 15,000; the number average molecular weight of the polyester-based resin B is not more than 5,000; a content ratio by mass of the polyester-based resin A to the polyester-based resin B (polyester-based resin A/polyester-based resin B) in the colored layer is not less than 2/3 and not more than 9/1; and the adhesion layer includes a polyester-based resin.

Abstract: An embossed heat transfer label includes a carrier, embossing layer, release coating, design layer, and adhesive layer, in which the embossing layer is formed to include an embossing pattern, and the design layer is configured to take up the embossing pattern from the embossing layer. The embossed heat transfer label is configured such that the design layer and the adhesive layer transfer to a target object upon application of heat and pressure, while the embossing layer and the release coating is removed and disposed with the carrier. The exposed design layer provides an embossed surface on the target object. The label can include a flat profile layer on which the design layer is printed.

Abstract: A protective layer for optical devices, comprising a replaceable, scratch resistant layer appliable to an optical device in such a way such that optical properties of said optical device are substantially unaltered. The optical device is undamaged by scratches made to the scratch resistant layer by a pencil having a 3H degree of hardness or by sand. The protective layer may comprise a polyvinyl butyral resin and polyvinyl alcohol.

Abstract: A substantially halo-free heat transfer label is made using a 3D printing method. The heat transfer label includes a graphic layer and an adhesive layer. The adhesive layer is printed using a 3D printing method, which provides a substantially reduced adhesive halo when compared to heat transfer labels including a screen printed adhesive layer or that printed via other conventional printing methods.

Abstract: This disclosure discloses an adhesive tape with print, comprising a transferred layer. The transferred layer is formed on a tape main body by transfer from an ink ribbon. In the tape main body, an adhesive layer is disposed on one side of a tape base layer, and a separation layer is provided on the other side of the tape base layer and comprises an olefin resin separating agent or an acrylic resin separating agent. A first layer is formed on a front surface of the other side of the transferred layer and has a solubility parameter value greater than or equal to 7 and less than or equal to 9. A second layer is formed on a front surface of the one side of the transferred layer and has a solubility parameter value greater than or equal to 7 and less than or equal to 9.

Abstract: The disclosure discloses an ink ribbon having a dimension in a thickness direction, comprising a ribbon base layer, a first layer, and a second layer. The first layer is disposed adjacent to one side of the ribbon base layer in the thickness direction, and includes a solubility parameter value greater than or equal to 7 and less than or equal to 9, and is configured to separate from the ribbon base layer. The second layer is disposed on the one side of the first layer in the thickness direction, and includes a solubility parameter value greater than or equal to 7 and less than or equal to 9, and is configured to stick to a transfer target.

Abstract: Heat transfers are provided that have indicia for enhancing the appearance of color dye sublimated fabric material, such as apparel and accessories including sportswear fabrics. The label assembly includes a transfer portion protected by a releasable support portion. The transfer portion includes a multi-layer barrier containing at least two differently formulated barrier layers. The second such barrier layer extends outwardly beyond the perimeter edge of the first barrier layer, which perimeter edge had left a recess gap in the transfer portion, which recess gap is covered by the overhang margin of the second barrier layer.

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: The system (10) includes at least one elastomeric, vulcanizable ink (18) that defines a decorative decal image (20). The decal image (20) has perimeter edges (22) and a display area (24) extending between the perimeter edges (22). The vulcanizable ink is vulcanized upon a carrier sheet (12). A heat-activated adhesive layer (26) is applied to overlie the display area (24) of the decal image (20), and the heat-activated adhesive layer (26) is also partially activated upon the display area (24) of the decal image (20). The decorative decal image (20) having the partially activated adhesive layer (26) is then thermally transferable to a vulcanized rubber product (28) such as a side wall (30) of an automotive tire (32), after which the carrier sheet (12) is removed.

Abstract: An organic light emitting diode (OLED) display device the present invention includes a substrate, a thin film transistor formed on the substrate, a pixel electrode formed on the thin film transistor and electrically connected to the thin film transistor, a pixel defining layer formed on the pixel electrode and defining a pixel area, an emission layer formed on the pixel electrode and contacting the pixel electrode in the pixel area, and an intermediate layer formed on the pixel defining layer and contacting a portion of the emission layer.

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 thermal-transfer laminate film includes a base film and an image protection layer. The image protection layer is provided an the base film and contains a thermoplastic resin and a pearl pigment, a content ratio of the pearl pigment with respect to 100 parts by mass of the thermoplastic resin being 0.5 parts by mass or more and 10 parts by mass or less.

Abstract: A heat transfer label assembly includes a heat transfer label including ink and adhesive, and a releasable support joined to the heat transfer label. The adhesive may include at least one of a polyketone resin and a polyamide resin. The heat transfer label may be used to decorate a metal article.

Abstract: An in-mold molded product of the present invention includes: molded resin; a transfer film sequentially including an adhesive layer in contact with the molded resin, and a coloring layer formed of ink; and a plurality of inorganic filler pieces contained in the coloring layer.

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: A thermal transfer sheet includes a protective layer and an adhesive layer which are laminated on a sheet base material in that order, the protective layer including a binder resin containing fine particles. The particle diameter of the fine particles is 0.9 to 2.8 times the thickness of the protective layer.

Abstract: A thermal transfer sheet includes a sheet substrate; a protective layer provided on the sheet substrate; and an adhesive layer provided on the protective layer, wherein a refractive-index difference between the protective layer and the adhesive layer is less than 0.10.

Abstract: A wax printing process, apparatus, formulation, and label. The process includes contacting a wax formulation with a surface having at least one etched region thereon, and confronting a carrier with the surface such that at least a portion of the wax transfers from the etched surface to the carrier. The apparatus includes a tray and a manifold positioned in the tray. In another aspect, the apparatus includes a gravure sleeve and a heatable mandrel disposed inside the gravure sleeve. The wax formulation includes a paraffin wax, an ester wax, a hydrocarbon resin, a microcrystalline wax, and an ethylene-vinyl acetate copolymer resin. The label includes a carrier and a wax release layer confronting a surface of the carrier. The wax release layer confronts less that the entire surface of the carrier.

Abstract: A transfer film includes a substrate, a decorative layer, and an adhering layer. The decorative layer is positioned by solidifying ultraviolet curing ink on the substrate. The adhering layer is positioned on the decorative layer.

Abstract: A wax printing process, apparatus, formulation, and label. The process includes contacting a wax formulation with a surface having at least one etched region thereon, and confronting a carrier with the surface such that at least a portion of the wax transfers from the etched surface to the carrier. The apparatus includes a tray and a manifold positioned in the tray. In another aspect, the apparatus includes a gravure sleeve and a heatable mandrel disposed inside the gravure sleeve. The wax formulation includes a paraffin wax, an ester wax, a hydrocarbon resin, a microcrystalline wax, and an ethylene-vinyl acetate copolymer resin. The label includes a carrier and a wax release layer confronting a surface of the carrier. The wax release layer confronts less that the entire surface of the carrier.

Abstract: A polyester laminated film includes at least a polyester layer, a highly crystalline polyester layer made of a highly crystalline polyester having a crystallinity parameter ?Tcg of 35° C. or lower, and a release layer laminated in that order, wherein the contact angle between the surface of the release layer and water in an atmosphere at room temperature of 23° C. and humidity of 65% is 85° or more. The polyester laminated film satisfies mold releasability, printability and thermoformability aspects, and is also excellent in cost performance.

Abstract: A selectively metallized heat transfer label for transfer to a substrate includes a support portion having a carrier layer and a release layer applied to the carrier layer, and a transfer portion including a protective layer applied to the release layer, a metallizable layer applied to the protective layer, a metal layer applied to the metallizable layer, a metal transferring adhesive layer applied to the metal layer and configured to adhere to both the metal layer and the desired substrate and a non-metal transferring ink layer applied to the metal layer and configured to adhere to the desired substrate but not to the metal layer. When heat and pressure are applied to the carrier, the metal transferring adhesive adheres to both the metal layer and the substrate while the non-transferring ink layer adheres only to the substrate.

Abstract: Provided is an image transfer material, comprising an optional support material, and a non-woven or woven fiber web layer, wherein the fiber web is impregnated or coated with a image receiving formulation. The fiber web layer is optionally attached to the support with an adhesion layer. Also provided is a heat transfer process wherein after imaging, the fiber web and adhesion layer are peeled from the optional support material and placed, preferably image side up (when imaged), on top of a receptor element. Alternatively, the fiber web and adhesion layer are peeled and then optionally imaged prior to being placed on the receptor element. Then, an optional non-stick sheet is placed over the imaged fiber web (if placed imaged side up) and heat is applied to the fiber web or the non-stick sheet, if present. The adhesion layer then melts and adheres the imaged web layer to the receptor element.

Abstract: This invention provides a hologram thermal transfer sheet that can realize thermal transfer treatment with high efficiency. The thermal transfer sheet comprises a base material sheet and a transparent transfer layer provided separably on the base material sheet, characterized in that a hologram layer is provided on at least a part of the transparent transfer layer. There are also provided a process for producing the thermal transfer sheet and an image formed material produced by the transfer of this thermal transfer sheet.

Abstract: A heat transfer label comprising a support portion and a transfer portion for transfer of the transfer portion from the support portion to an article. The article may be untreated polyethylene, polypropylene, PET, or acrylonitrile. Heat is applied to the support portion while the transfer portion is placed into contact with the untreated polyethylene, polypropylene, or acrylonitrile article. The transfer portion comprises an adhesive layer comprising a vinyl acetate resin, a tackifying petroleum hydrocarbon resin, and a microcrystalline wax.

Abstract: The present invention pertains to a donor element comprising a support layer, a transfer layer supported by the support layer, and a second layer disposed between the support layer and the transfer layer, wherein the second layer contains a binder and optionally an uncured crosslinking agent, but substantially no pigment. The binder in the second layer has a molecular weight Mn that causes the second layer to be substantially transferred with the transfer layer when the donor element is exposed to light.

Abstract: An article including: a porous substrate that includes a fibrous material; and a release coating disposed on the fibrous material of the porous substrate; wherein the release coating includes a thermoplastic silicone-containing polymer. A method of making an article, which method includes: providing a porous backing having a first major surface and a second major surface; applying a pressure sensitive adhesive to the first major surface of the porous backing; and applying an aqueous dispersion including a thermoplastic silicone-containing polymer to the second major surface of the porous backing to form a low adhesion backsize.

Abstract: Disclosed in this specification is a decal assembly comprising a decal support, a releasable covercoat, a heat activatable layer, and an ink layer. The ink layer forms a digital image. The heat activatable layer has a high adhesion to a ceramic substrate at high temperatures and a low adhesion to the substrate at lower temperatures. Thus the adhesive properties of the decal are activated by heat. The resulting image has excellent adhesion to the substrate and resists the effects of washing.

Abstract: Disclosed is a printing method which can form an image having a rainbow color and a metallic luster at a low cost. The printing method comprises the steps of: providing a substrate; forming, on a surface of the substrate, a first image using a pigment- or dye-containing first colorant; and then forming a second image using a pearl pigment-containing second colorant.

Abstract: The present invention provides an adhesive preparation superior in adhesion property, which does not peel off or fall off easily and which can be adhered for a long time. An adhesive preparation 10 has a support 1 made of a cloth, and a pressure sensitive adhesive layer 3 formed on one surface of the support 1, which contains a pressure sensitive adhesive and a drug. The ratio (CW/AW) of a mass (CW) per unit area of the support 1 and a mass (AW) per unit area of the pressure sensitive adhesive layer 3 is 1.0-5.0, an adhesive layer-free surface of the support 1 has a static friction coefficient of 0.25-0.75, and a 20% modulus (AM) in one direction of the adhesive preparation 10 and a 20% modulus (EM) in the direction perpendicular to that direction are each 0.5-1.5 N/cm, and the ratio thereof (AM/EM) is 0.5-2.0.

Abstract: The present invention provides an adhesive composition comprising a copolymer (a) of a methylmethacrylate (MMA) and/or a butylmethacrylate (BMA) and a styrene (St), also provides an adhesive composition comprising a mixture of an acrylic polymer (b) and a ketone resin, wherein the acrylic polymer (b) is at least one polymer selected from the group consisting of a poly MMA, a poly BMA, a MMA/BMA copolymer or a MMA/BMA/St copolymer, and also provides a thermal transfer sheet having a layer comprising the adhesive composition. The adhesive composition has excellent heat sealing characteristics and resistance to blocking when it is used for the formation of an adhesive layer, is also superior in miscibility with various organic or inorganic additives and allows these additives to exhibit their functions sufficiently when these additives are added and has high transparency.

Abstract: A transfer member includes a substrate sheet, a mold release layer of a belt-shaped pattern laminated on the substrate sheet, an ionizing radiation curing layer laminated all over a surface on mold release layer, a patterned layer laminated all over a surface or partially on the ionizing radiation curing layer, and an adhesive layer laminated on the patterned layer only partially in a portion where the adhesive layer overlaps with the mold release layer.

Abstract: The present invention relates to a protective heat transferable overcoat element comprising a support having thereon a protective polymer layer of at least one benzoated phenoxy resin of Formula I. The present invention also relates to a thermal transfer dye donor element comprising a support having on one side thereof at least one dye layer and a protective polymer layer of at least one benzoated phenoxy resin of Formula I and a thermal transfer assemblage comprising at least one thermal transfer donor element comprising a support having on one side thereof a protective polymer layer of at least one benzoated phenoxy resin of Formula I. Finally, the present invention relates to a protected image reproduction comprising a support, an imaging layer containing an image, and a transferred protective heat transferable overcoat comprising a protective polymer layer of at least one benzoated phenoxy resin of Formula I.

Abstract: The invention relates to a multi-layer laser transfer film for the permanent labeling of components, comprising at least one support layer, whereby a first adhesive layer is at least partly provided on the underside of the support layer, characterised in that on the side of the support layer for the laser transfer film on which the first adhesive layer is provided, at least two pigment layers containing a laser-sensitive pigment are at least partly provided, whereby the concentration of the laser-sensitive pigment in the pigment layers varies.

Abstract: There are provided a protective layer transfer sheet that is excellent in transferability of a thermally transferable protective layer from a substrate sheet and can yield a protective layer having excellent durability such as abrasion resistance and scratch resistance, weathering resistance, chemical resistance, solvent resistance, stampability and writability with an aqueous ink, and a thermally transferred image recorded object using the same.

Abstract: A multicolor image forming material comprising: an image receiving sheet comprising an image receiving layer; and at least five heat transfer sheets different in color each comprising a substrate, a light-heat conversion layer and an image forming layer, each of the heat transfer sheets being adapted to be superposed on the image receiving sheet with the image forming layer facing the image receiving layer and irradiated with laser light to transfer the irradiated area of the image forming layer to the image receiving layer to record an image on the image receiving sheet, wherein an area of the recording has a size of 515 mm by 728 mm or larger, the image forming layer of at least one of the heat transfer sheets has a thickness of 0.6 ?m or greater, and the at least one of the heat transfer sheets has an adhesive strength of 8 g/cm or higher between the light-heat conversion layer and the image forming layer in a non-irradiated area thereof.

Abstract: According to the present invention, in a thermosensitive transfer film F in which at least a fluorescent substance layer 3 and an adhesive agent layer 4 are deposited onto a base film 1, this adhesive agent layer 4 is produced by mixing at least a pigment corresponding to a color of the fluorescent substance layer 3, a thermosensitive agent and a photosensitizer. Also, a display device manufacturing method comprises the steps of forming patterning by exposure and development and using the adhesive agent layer 4 as a color filter layer after the fluorescent substance layer 3 and the adhesive layer 4 have been transferred onto the inner surface of the display panel from this thermosensitive transfer film F. Thus, in the thermosensitive transfer film in which layers are formed by the transfer process, work efficiency of the transfer process can be improved, and the sharp pattern can be formed.

Abstract: A thermal transfer sheet is provided that can yield thermally transferred images, which possess excellent various fastness or resistance properties even under severe service conditions, and comprises a transferable protective layer having good transferability. In a thermal transfer sheet comprising a substrate sheet and a thermally transferable protective layer on the substrate sheet, the thermally transferable protective layer comprises a scratch-resistant layer which is repeatedly provided one by one for each picture plane unit in the thermal transfer sheet. An area of the scratch-resistant layer for each picture plane unit is smaller than an area of an object in its transfer surface. By virtue of this construction, at the time of the transfer of a protective layer onto an object, layer cutting does not occur within the scratch-resistant layer but within other layer (such as peel layer or adhesive layer), and, consequently, the protective layer can be transferred with good transferability.

Abstract: The present invention provides a protective layer transfer sheet, which has excellent folding resistance, plasticizer resistance, scratch resistance, transparency, layer transferability and other properties, and a print using the same. The protective layer transfer sheet comprises: a substrate sheet; and a thermally transferable resin layer provided separably on at least a part of one side of the substrate sheet. The thermally transferable resin layer comprises at least a thermally transferable protective layer and a heat-sensitive adhesive resin layer stacked in that order from the substrate sheet side. The thermally transferable protective layer comprises a layer comprising submicron particles of a layered inorganic material dispersed in a binder resin. The print is formed using the thermally transferable protective layer.