Abstract: A thermal transfer image receiving sheet includes: a substrate made of paper; a polyolefin resin layer formed on a first surface of the substrate; an adhesive layer formed on a second surface of the substrate facing away from the first surface; a porous layer formed on the adhesive layer; a foundation layer formed on the porous layer; and an image receiving layer formed on the foundation layer. A surface of the substrate, as defined in JIS B 0601:2001, has a maximum valley (undulation) depth Wv of 2.00 ?m or less and a root mean square slope for the waviness W?q of 0.013 or less. The porous layer has a thickness of 25 ?m or more, and a thickness of the polyolefin resin layer is 0.2 to 3.0 times the thickness of the porous layer.

Abstract: A decorative board in the present disclosure includes a primer layer, a concealing layer, a colorant layer and a topcoat layer containing ultraviolet-curable resin on a base material in this order. A method for manufacturing the decorative board in the present disclosure includes a stretching process, an irradiation process, and a separation process. The stretching process includes forming the primer layer, the concealing layer, and the colorant layer on the base material in this order; applying a ultraviolet-curable coating material containing ultraviolet-curable resin; placing a plastic film on the applied ultraviolet-curable coating material, placing a roller on the plastic film, and stretching the ultraviolet-curable coating material by rolling the roller. The irradiation process includes forming the topcoat layer by hardening the ultraviolet-curable coating material by ultraviolet ray irradiation. The separation process includes separating the plastic film after the irradiation.

Abstract: A vehicle applique includes a base structure and a polymeric coating disposed on the base structure. The polymeric coating at least partially covers an outer surface of the base structure. A diffraction grating is integrally defined by the polymeric coating. The diffraction grating has a thickness in a range of from about 100 nm to about 300 nm.

Abstract: A shock-absorbing sheet comprises a foamed resin layer having a thickness of 200 ?m or less, a void ratio (P0.1) of a plane directional cross section at a thickness of 0.1 T, a void ratio (P0.5) of a plane directional cross section at a thickness of 0.5 T, and a void ratio (P0.9) of a plane directional cross section at a thickness of 0.9 T from one surface of the foamed resin layer each ranging from 10 to 70 area %; and the standard deviation (P?) for an average void ratio found from the void ratio (P0.1), the void ratio (P0.5) and the void ratio (P0.9) ranging from 1.0 to 20.

Abstract: An object of the present invention is to provide an intermediate transfer medium having high durability, as well as high smudge resistance and image stability. The intermediate transfer medium of the present invention includes: a substrate, and a transfer layer including a first intermediate layer, a second intermediate layer and a receiving layer; in which the first intermediate layer contains a (meth)acrylic polyol resin with a glass transition temperature of 80° C. or higher; in which the second intermediate layer contains a polyester with a glass transition temperature of 45° C. or higher and a filler with a mean particle diameter of 2 ?m or more and 5 ?m or less; and in which the content of the filler in the second intermediate layer is 0.5% by mass or more and 5% by mass or less.

Abstract: The present invention provides a thermal transfer sheet which can provide a thermal transfer image-receiving sheet capable of forming a printed product of high designability, provides a thermal transfer image-receiving sheet capable of forming a printed product of high designability and a method for forming a printed product, and provides a printed product of high designability. In a thermal transfer sheet 100 in which a transfer layer 10 is provided on a substrate 1, the transfer layer 10 has a layered structure in which a receiving layer 2, an intermediate layer 3, and a masking layer 4 are layered in this order from the side of the substrate 1, and the intermediate layer 3 contains inorganic particles.

Abstract: In a thermal transfer sheet in which a transfer layer is provided on a substrate, the transfer layer has a layered structure in which a receiving layer, an intermediate layer, and a masking layer are layered in this order from the side of the substrate, the receiving layer is a solvent-based receiving layer containing a solvent-based resin and a silicone oil, the intermediate layer is a water-based intermediate layer containing a water-based resin, and the masking layer is a solvent-based masking layer containing a solvent-based resin and a colorant.

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: The present invention relates to a thermally printable paper article with an elastomeric underlayer, which imparts improved printing performance.

Abstract: A composite film material usable in a data carrier card body includes a first outer plastic layer, an inner plastic layer and a second outer plastic layer, all the layers together forming a co-extruded composite. The plastic material of the first outer layer is a polyethylene terephthalate glycol copolymer (PETG) or contains a PETG, the plastic material of the inner layer is a thermoplastic elastomer (TPC) or containes a TPC, and the plastic material of the second outer layer is a PETG or contains a PETG.

Abstract: A composition for a protection layer of a thermal recording material includes emulsion (A) and non-crosslinkable urea compound (B), and emulsion (A) has a pH of 6 or more, and contains copolymer resin (a) produced by copolymerizing reactive monomer component (a?) containing at least a vinyl monomer component having a carboxyl group and a vinyl monomer component that is copolymerizable with the vinyl monomer component having a carboxyl group.

Abstract: An optical mask including a transmissive base substrate, a reflective pattern layer, and a photothermal conversion pattern layer. The reflective pattern layer is disposed on the transmissive base substrate. The reflective pattern layer includes reflectors. The photothermal conversion pattern layer is disposed on the transmissive base substrate among the reflectors. The photothermal conversion pattern layer includes first regions with a first light absorptivity and second regions with a second light absorptivity. The second light absorptivity is greater than the first light absorptivity. The first regions are disposed among the second regions.

Abstract: An image transfer article can include an image-imparting member and a removable substrate disposed adjacent to the image-imparting member. The image-imparting member can have a softening point temperature less than about 220° C. The image-imparting member can include at least one surface configured to receive and carry indicia to be transferred and at least one portion comprising a pigment providing an opaque background for received indicia. In some examples, the image-imparting member can comprise a first polymer including the indicia and at least a second polymer including the pigment. In some examples, the image-imparting member can comprise a polymer including the indicia and the pigment. The indicia and the opaque background can be arranged to concurrently transfer to a woven- or fabric-based article or paper in contact with the image-imparting member, upon application of iron pressing temperatures.

Abstract: A donor substrate includes a base substrate; a light reflection layer disposed on the base substrate and overlapped with a portion of the base substrate, a heat blocking pattern disposed on the light reflection layer, overlapped with the light reflection layer, and including a plurality of air holes; a light-to-heat conversion layer disposed on the base substrate; and a transfer layer disposed on the light-to-heat conversion layer.

Abstract: A thermal transfer printable multilayer label tape for identifying fluid lines, the tape comprising: (A) A clear topcoat layer; (B) A clear first primer layer in contact with the topcoat layer; (C) A clear face sheet layer in contact with the first primer layer; (D) A clear second primer layer in contact with the face sheet layer; (E) A color layer in contact with the second primer layer; and (F) An adhesive layer in contact with the color layer.

Abstract: A thermal image receiver element dry image receiving layer has a Tg of at least 25° C. and is the outermost layer. The dry image receiving layer has a dry thickness of at least 0.5 ?m and up to and including 5 ?m. It comprises a water-dispersible release agent and a polymer binder matrix that consists essentially of: (1) a water-dispersible acrylic polymer comprising chemically reacted or chemically non-reacted hydroxyl, phospho, phosphonate, sulfo, sulfonate, carboxy, or carboxylate groups, and (2) a water-dispersible polyester that has a Tg of 30° C. or less. The water-dispersible acrylic polymer is present in an amount of at least 55 weight % and at a dry ratio to the water-dispersible polyester of at least 1:1. The thermal image receiver element can be used to prepare thermal dye images after thermal transfer from a thermal donor element.

Abstract: Disclosed herein is a multi-layered matte film comprising at last one layer of a coating comprising the condensation reaction product of the combination of a polyalkylimine and an acetoacetonate (“AcAc”)-functional material or an oxirane-functional material, each comprising an ethenic unsaturation group, the coating adhered to a sealant film layer; a sealant layer comprising a polyolefin and having a Tm, within the range of from 120° C. to 170° C.; and a Flexural Modulus within the range from 500 to 1200 MPa; a core polypropylene layer; and a matte layer between the sealant layer and core layer, the matte layer comprising a blend of at least two incompatible polymers such that the Haze is at least 50%.

Abstract: The invention relates to a special layer construction and a special film of plastic for the production of such a layer construction which is suitable for printing by means of dye diffusion thermal transfer printing, a process for the production thereof and a security and/or valuable document comprising such a layer construction.

Abstract: A thermal image receiver element dry image receiving layer has a Tg of at least 25° C. as the outermost layer. The dry image receiving layer has a dry thickness of at least 0.5 ?m and up to and including 5 ?m. It comprises a polymer binder matrix that consists essentially of: (1) a water-dispersible acrylic polymer comprising chemically reacted or chemically non-reacted hydroxyl, phospho, phosphonate, sulfo, sulfonate, carboxy, or carboxylate groups, and (2) a water-dispersible polyester that has a Tg of 30° C. or less. The water-dispersible acrylic polymer is present in an amount of at least 55 weight % of the total dry image receiving layer weight and at a dry ratio to the water-dispersible polyester of at least 1:1 to and including 20:1. The thermal image receiver element can be used to prepare thermal dye images after thermal transfer from a thermal donor element.

Abstract: An image transfer sheet includes an image-receiving layer, a substrate, and a rear outermost layer containing an alkali metal salt of an aliphatic carboxylic acid. The image-receiving layer, the substrate, and the rear outermost layer are arranged in that order.

Abstract: The present invention relates to improved self-adhesive labels which are suitable far use in adhering to wet surfaces or wet irregularly shaped surfaces such as that found on fruits and vegetables. The self-adhesive label is made of a water absorbent backing layer having opposing sides and a rubber-based pressure sensitive adhesive applied on one side of the backing layer. The adhesive is discontinuously coated as a pattern onto the backing layer to provide areas of the adhesive interspersed with areas which are free of adhesive.

Abstract: To provide a thermosensitive recording label, which contains a base, an under layer, a thermosensitive coloring layer, a barrier layer, a release layer, and an adhesive layer, where the under layer, the thermosensitive coloring layer, the barrier layer, and the release layer are disposed on one surface of the base in this order, and the adhesive layer is disposed on the other surface of the base, wherein the release layer contains a cured product of a heat curing silicone resin, and the barrier layer contains a cured product of a water-soluble resin with a crosslinking agent, and inorganic filler.

Abstract: An object of the present invention is to provide a water-insoluble coloring matter compound having high solubility for a solvent and high lightness and chroma and providing a chromaticity closer to the magenta chromaticity represented by the Adobe RGB color space, A water-insoluble coloring matter compound represented by the formula (1) is provided; wherein R1 and R2 represent an alkyl group, and R3 represents an alkyl group, an aryl group, or an alkoxy group. And the alkyl group, the aryl group and the alkoxy group regarding to R1 to R3 are capable of having a substituent.

Abstract: A thermal image receiver element dry image receiving layer has a Tg of at least 25° C. and is the outermost layer. The dry image receiving layer has a dry thickness of at least 0.5 ?m and up to and including 5 ?m. It comprises a water-dispersible release agent and a polymer binder matrix that consists essentially of: (1) a water-dispersible acrylic polymer comprising chemically reacted or chemically non-reacted hydroxyl, phospho, phosphonate, sulfo, sulfonate, carboxy, or carboxylate groups, and (2) a water-dispersible polyester that has a Tg of 30° C. or less. The water-dispersible acrylic polymer is present in an amount of at least 55 weight % and at a dry ratio to the water-dispersible polyester of at least 1:1. The thermal image receiver element can be used to prepare thermal dye images after thermal transfer from a thermal donor element.

Abstract: A thermal transfer printable multilayer label tape for identifying fluid lines, the tape comprising: (A) A clear topcoat layer; (B) A clear first primer layer in contact with the topcoat layer; (C) A clear face sheet layer in contact with the first primer layer; (D) A clear second primer layer in contact with the face sheet layer; (E) A color layer in contact with the second primer layer; and (F) An adhesive layer in contact with the color layer.

Abstract: An identification device, preferably a wristband or adhesive label, is configured to receive identifying indicia by means of a direct thermal printer. A direct thermal layer includes antimicrobial particles embedded therein and is exposed, i.e., does not have a protective overcoat or varnish covering the direct thermal layer. The antimicrobial particles increase the surface available silver ions and are preferably formed of an aqueous dispersion of silver chloride-coated titanium dioxide particles. The antimicrobial particles may also be formed of an inorganic silver-containing compound such as silver zirconium phosphates or a silver substituted zeolite.

Abstract: An image transfer sheet includes an image-receiving layer, a substrate, and a rear outermost layer containing an alkali metal salt of an aliphatic carboxylic acid. The image-receiving layer, the substrate, and the rear outermost layer are arranged in that order.

Abstract: Thick, compressible, multilayer labels with the appearance and feel of hard plastic identification shields comprise: A. A printable film having first and second opposing facial surfaces; B. A first adhesive having first and second opposing facial surfaces, the first facial surface of the adhesive in intimate contact with the second facial surface of the film; and C. Foam having first and second opposing facial surfaces, the first facial surface of the foam in intimate contact with the second facial surface of the first adhesive. In certain embodiments of the invention, the labels include one or more of a printable coating on the first facial surface of the film, a second adhesive in intimate contact with the second facial surface of the foam, and a release liner in contact with the second adhesive.

Abstract: This disclosure discloses a tape cassette comprises a tape roll, a guide shaft, and a housing. In the tape roll, a tape is wound around an outer periphery of a winding member. The tape includes a base layer and a hot melt adhesive layer. The hot melt adhesive layer is provided on one side from the base layer. The hot melt adhesive layer is formed of a hot melt adhesive configured to melt at a temperature of a predetermined melting point or more so as to exert adhesiveness. The hot melt adhesive layer is applied so that a surface of the hot melt adhesive layer on the one side becomes smooth. The guide shaft is for guiding the tape fed out of the tape roll. The housing accommodates the tape roll and the guide shaft therein.

Abstract: Thick, compressible, multilayer labels with the appearance and feel of hard plastic identification shields comprise: A. A printable film having first and second opposing facial surfaces; B. A first adhesive having first and second opposing facial surfaces, the first facial surface of the adhesive in intimate contact with the second facial surface of the film; and C. Foam having first and second opposing facial surfaces, the first facial surface of the foam in intimate contact with the second facial surface of the first adhesive. In certain embodiments of the invention, the labels include one or more of a printable coating on the first facial surface of the film, a second adhesive in intimate contact with the second facial surface of the foam, and a release liner in contact with the second adhesive.

Abstract: An image transfer article can include an image-imparting member and a removable substrate disposed adjacent to the image-imparting member. The image-imparting member can have a softening point temperature less than about 220° C. The image-imparting member can include at least one surface configured to receive and carry indicia to be transferred and at least one portion comprising a pigment providing an opaque background for received indicia. In some examples, the image-imparting member can comprise a first polymer including the indicia and at least a second polymer including the pigment. In some examples, the image-imparting member can comprise a polymer including the indicia and the pigment. The indicia and the opaque background can be arranged to concurrently transfer to a woven- or fabric-based article or paper in contact with the image-imparting member, upon application of iron pressing temperatures.

Abstract: A thermal image receiver element dry image receiving layer has a Tg of at least 25° C. as the outermost layer. The dry image receiving layer has a dry thickness of at least 0.5 ?m and up to and including 5 ?m. It comprises a polymer binder matrix that consists essentially of: (1) a water-dispersible acrylic polymer comprising chemically reacted or chemically non-reacted hydroxyl, phospho, phosphonate, sulfo, sulfonate, carboxy, or carboxylate groups, and (2) a water-dispersible polyester that has a Tg of 30° C. or less. The water-dispersible acrylic polymer is present in an amount of at least 55 weight % of the total dry image receiving layer weight and at a dry ratio to the water-dispersible polyester of at least 1:1. The thermal image receiver element can be used to prepare thermal dye images after thermal transfer from a thermal donor element.

Abstract: The present invention relates to a multilayer article comprising a first substrate with a first backing layer and comprising at least one further (second) substrate with a second backing layer, where these have been provided on respectively one side at least to some extent with a cold-seal adhesive layer and have been bonded to one another specifically via the contact between their respective cold-seal adhesive layers, to a process for the production of an article of this type, and also to the use of a printer with at least two unwind systems and with at least one cutting device for the production of articles of this type.

Abstract: A thermal image receiver element dry image receiving layer has a Tg of at least 25° C. and is the outermost layer. The dry image receiving layer has a dry thickness of at least 0.5 ?m and up to and including 5 ?m. It comprises a water-dispersible release agent and a polymer binder matrix that consists essentially of: (1) a water-dispersible acrylic polymer comprising chemically reacted or chemically non-reacted hydroxyl, phospho, phosphonate, sulfo, sulfonate, carboxy, or carboxylate groups, and (2) a water-dispersible polyester that has a Tg of 30° C. or less. The water-dispersible acrylic polymer is present in an amount of at least 55 weight % and at a dry ratio to the water-dispersible polyester of at least 1:1. The thermal image receiver element can be used to prepare thermal dye images after thermal transfer from a thermal donor element.

Abstract: A thermal dye image receiver element has a substrate comprising a voided compliant layer and metalized layer. Disposed on the metalized layer is an opacifying layer that includes an opacifying agent and a dye receiving layer. This thermal dye image receiver element can be a duplex element with image receiving layers on both sides of the substrate, and it can be used in association with a thermal donor element to provide a thermal image on either or opposing sides of the receiver element. The metalized layer provides increased specular reflectance under resulting thermal dye images.

Abstract: When a plurality of images is printed on both the surfaces of a continuous sheet, an optimum scheduling is carried out including maintenance of a print head, thereby suppressing amount of consumption of a sheet as a whole. For such a purpose, acquiring information regarding on which of the first and second surfaces and where on the surface of the continuous sheet a unique portion exists, the unique portion is unsuitable for image printing that exists on the continuous sheet; and setting, based on the acquired information, a print unavailable region including the unique portion and a maintenance region posterior thereto on a specific sheet surface having the unique portion existing thereon, and another print unavailable region and a maintenance region posterior thereto on a reverse side of the specific sheet surface, the another print unavailable region being set so as to include a region corresponding to the maintenance region.

Abstract: Disclosed is a thermal transfer image-receiving sheet which excels in adhesiveness to a receiving layer and solvent resistance, and a manufacturing method thereof. In the thermal transfer image-receiving sheet, which includes a porous layer, a barrier layer, a receiving layer which are stacked in this order on a substrate, the porous layer includes a binder resin and hollow particles, and the barrier layer includes (i) (A) a first acrylic resin and (B) one or more kinds of resins selected from the group consisting of polyester resins, polyvinyl pyrrolidone type resins, polyester type urethane resin, and a second acrylic resin which differs from the first acrylic resin; or (ii) a polyvinyl pyrrolidone type resin.

Abstract: A thermal image receiver element dry image receiving layer has a Tg of at least 25° C. as the outermost layer. The dry image receiving layer has a dry thickness of at least 0.5 ?m and up to and including 5 ?m. It comprises a polymer binder matrix that consists essentially of: (1) a water-dispersible acrylic polymer comprising chemically reacted or chemically non-reacted hydroxyl, phospho, phosphonate, sulfo, sulfonate, carboxy, or carboxylate groups, and (2) a water-dispersible polyester that has a Tg of 30° C. or less. The water-dispersible acrylic polymer is present in an amount of at least 55 weight % of the total dry image receiving layer weight and at a dry ratio to the water-dispersible polyester of at least 1:1. The thermal image receiver element can be used to prepare thermal dye images after thermal transfer from a thermal donor element.

Abstract: A thermal image receiver element dry image receiving layer has a Tg of at least 25° C. as the outermost layer. The dry image receiving layer has a dry thickness of at least 0.5 ?m and up to and including 5 ?m. It comprises a polymer binder matrix that consists essentially of: (1) a water-dispersible acrylic polymer comprising chemically reacted or chemically non-reacted hydroxyl, phospho, phosphonate, sulfo, sulfonate, carboxy, or carboxylate groups, and (2) a water-dispersible polyester that has a Tg of 30° C. or less. The water-dispersible acrylic polymer is present in an amount of at least 55 weight % of the total dry image receiving layer weight and at a dry ratio to the water-dispersible polyester of at least 1:1 to and including 20:1. The thermal image receiver element can be used to prepare thermal dye images after thermal transfer from a thermal donor element.

Abstract: A thermal image receiver element dry image receiving layer has a Tg of at least 25° C. and is the outermost layer. The dry image receiving layer has a dry thickness of at least 0.5 ?m and up to and including 5 ?m. It comprises a water-dispersible release agent and a polymer binder matrix that consists essentially of: (1) a water-dispersible acrylic polymer comprising chemically reacted or chemically non-reacted hydroxyl, phospho, phosphonate, sulfo, sulfonate, carboxy, or carboxylate groups, and (2) a water-dispersible polyester that has a Tg of 30° C. or less. The water-dispersible acrylic polymer is present in an amount of at least 55 weight % and at a dry ratio to the water-dispersible polyester of at least 1:1. The thermal image receiver element can be used to prepare thermal dye images after thermal transfer from a thermal donor element.

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

Abstract: Thick, compressible, multilayer labels with the appearance and feel of hard plastic identification shields comprise: A. A printable film having first and second opposing facial surfaces; B. A first adhesive having first and second opposing facial surfaces, the first facial surface of the adhesive in intimate contact with the second facial surface of the film; and C. Foam having first and second opposing facial surfaces, the first facial surface of the foam in intimate contact with the second facial surface of the first adhesive. In certain embodiments of the invention, the labels include one or more of a printable coating on the first facial surface of the film, a second adhesive in intimate contact with the second facial surface of the foam, and a release liner in contact with the second adhesive.

Abstract: A resin composition used to form a dye-receiving layer of a thermal transfer-receiving sheet in which the dye-receiving layer is formed on at least one surface of a substrate contains a core/shell-type latex including a core containing (A) and a shell containing (B) and a cross-linking agent that reacts with a carboxyl group contained in the shell. (A) is an acrylic resin at least containing, as one of its monomers, a substituted or unsubstituted phenoxyalkyl (meth)acrylate and/or a substituted or unsubstituted phenoxy polyalkylene glycol (meth)acrylate. (B) is a urethane resin containing a carboxyl group.

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

Abstract: A linerless label roll of repositionable labels adapted to be printed in varying lengths comprising a web of thermally printable paper wound along a running axis and having a continuous length of adhesive on one side of the web so that when a length of the web is caused to be thermally printed it will have an adhesive on the reverse side thereof that extends in a uninterrupted manner along the entire length of the thermally printed web.

Abstract: A thermal, non-silver halide-containing image receiver element includes a support and an aqueous-coated image receiving layer. This receiving layer comprises a water-dispersible polymer having a polyurea or polyurethane backbone and up to 25 weight % of the water-dispersible polymer comprising polysiloxane side chains that are covalently attached to the backbone, each of the side chains having a molecular weight of at least 500. Aqueous dispersions of polyester ionomers and crosslinking agents can also be present.

Abstract: In an intermediate transfer medium, a substrate, protective layers having a layered structure of two or more layers, and a receiving layer are layered in this order. One layer in the protective layers having the layered structure contains, as a main component, one material or a mixture of two or more materials selected from the group consisting of polyesters having a high polymerization degree, a number-average molecular weight (Mn) of not less than 12,000 and a Tg of not less than 60° C., polycarbonates and polyester urethanes. Another layer in the protective layers having the layered structure contains one or more materials selected from the group consisting of polyvinyl alcohols, polyvinyl butyrals, polyvinyl acetals and polyvinyl pyrrolidones or includes a cationic resin, and the receiving layer contains a side chain-type aralkyl-modified silicone in an amount of 0.5-5% by weight on a base of the total weight of the receiving layer.

Abstract: A heat-sensitive transfer image-receiving sheet, having, on a transparent support, a lenticular lens and at least one receptor layer in which the heat-sensitive transfer image-receiving sheet has a subbing layer which contains a resin that is identical with at least one resin constituting the lenticular lens, on the side of the transparent support opposite to the side on which the lenticular lens is provided, and the heat-sensitive transfer image-receiving sheet has a receptor layer containing a latex polymer on the subbing layer.

Abstract: A film transfer sheet including a sheet substrate provided with a layer via a resin layer and a peelable transparent sheet provided with an adhesive layer. The sheet substrate and the peelable transparent sheet are laminated together such that the layer is overlapped on the peelable transparent sheet and peeling is designed to occur between the layer and the peelable transparent sheet so as to transfer the peelable transparent sheet provided with the adhesive layer to a transfer-receiving member. The resin layer includes as an essential component a pressure-sensitive adhesive having a storage elastic modulus of 3.0 ×105 Pa to 1.2 ×106 Pa at a temperature of 130° C. to 150° C. Also provided is an intermediate transfer recording medium including a sheet substrate provided with a layer via resin layer and a peelable transparent sheet provided with a dye receptive layer, in which the sheet substrate and the peelable transparent sheet are laminated together.

Abstract: A method of producing a heat-sensitive transfer image-receiving sheet, having the steps of: conveying a transparent support by web handling; providing at least one receptor layer on the transparent support; and drying the heat-sensitive transfer image-receiving sheet, in which the at least one receptor layer contains a latex polymer having a weighted average glass transition temperature of 30° C. or more, the heat-sensitive transfer image-receiving sheet is dried at a temperature that is higher than the weighted average glass transition temperature by 30° C. or more, and the heat-sensitive transfer image-receiving sheet has a lenticular lens on the side of the transparent support opposite to the side on which the receptor layer is provided.