Abstract: An image-forming method, containing: providing a heat-sensitive transfer image-receiving sheet having at least one heat insulation layer containing hollow polymer particles and at least one receptor layer containing at least one latex polymer, in this order on a support, and a heat-sensitive transfer sheet having a thermal transfer layer containing a thermal transferable dye; feeding the sheets through, between a rotatable platen roller and a thermal head having heating elements aligned in a main scan direction, to move the sheets in a sub scan direction approximately perpendicular to the main scan direction, to form an image on the image-receiving sheet, in which the thermal head has a glaze provided with the heating elements and formed in a convex shape, and the glaze's convex vertex is shifted to an upstream side in the sub scan direction, with respect to the center's position of the heating elements.

Abstract: Methods and products for forming a coated image on a substrate are generally disclosed. The methods can include forming an image on a printable surface of a transfer coating layer of a printable transfer sheet. In a separate step, the negative mirror image of that same image is printed with toners on a toner printable sheet. After registering the sheets together, a portion of the transfer coating layer of the printable transfer sheet is transferred to the toner printable sheet, such that the portion of the transfer coating layer transferred to the toner printable sheet corresponds to the imaged areas on the toner printable sheet. However, the image formed on the printable surface of the transfer coating layer and the underlying transfer coating substantially remain on the printable transfer sheet. Thereafter, the image and the transfer coating layer remaining on the printable transfer sheet are transferred to a substrate.

Abstract: Methods of making a stenciled screen for use in screen printing an image onto a substrate are generally disclosed. The method involves removing a portion of a transfer coating from a transfer sheet via heat transfer with a printable sheet defining a printable surface. The portion of the transfer coating removed from the transfer sheet corresponds to areas where an ink is present on the printable surface of the printable sheet. The transfer coating can then be transferred to a screen to form a stenciled screen having closed mesh areas corresponding to where the transfer coating is present. The stenciled screen can then be used to screen print an image onto any of a variety of fibrous substrates.

Abstract: A thermal transfer method for selectively transferring a red organic light material of a transfer layer from a donor substrate to a recipient substrate to form a red organic light emitting element. The donor substrate has a reflecting layer in a planned formation region of the transfer layer and an absorbing layer in a region other than the planned formation region of the transfer layer. The transfer layer is formed on an area on the front face side of the base. The transfer layer in the region where the absorbing layer is formed is selectively removed. the donor substrate and the other substrate are placed in opposition. The transfer layer on the reflecting layer is transferred to the recipient substrate.

Abstract: Methods of creating and transferring chemical patterns and physical patterns of deposited materials or molecules using block copolymers are provided. The methods involve providing block copolymer materials blended with one or more transfer molecules or inks. The differences in chemistry of the blocks of the copolymer that result in micro-phase separation (e.g., self-assembly into nanoscale domains) also allow inks to be sequestered into specific blocks. By designing the ink molecules to react, adsorb, or otherwise interact with a second substrate, inks are transferred to the second substrate in a pattern dictated by the pattern of block copolymer domains present at the surface of the block copolymer film.

Abstract: The present disclosure provides systems, methods and apparatus for providing interferometric modulator displays using flexible films. In one aspect, a method of forming an interferometric modulator device includes providing a conductive element, depositing a reflective layer over at least a portion of the conductive element, and depositing a plurality of spacing elements over the conductive element. The absorber layer and the substrate are provided over the conductive element such that the absorber layer is disposed between the substrate and the spacing elements.

Abstract: A group of size-adjustable wristbands is disclosed. The group of wristbands includes a backing sheet that is connected to a stub area disposed at an end of the backing sheet. A plurality of elongated strips is connected to the stub area in a side-by-side fashion. Each strip includes a first end attached to an additional stub area and a second end attached to the stub area. Each strip further includes a top surface. The group of wristbands further includes a plurality of top sheets, each top sheet having a first end and a second end. The first end of each top sheet is attached to one of the strips along a top surface thereof. Each top sheet is clear and includes a bottom side coated with a top adhesive layer. Finally, the group of wristbands includes a plurality of top liners with each top liner being sandwiched between one of the top adhesive layers and one of the strips.

Abstract: A printing machine contains a transfer unit for transferring a transfer layer onto a print carrier in a transfer nip. The printing machine further has at least one applicator unit for applying an adhesive to the print carrier. The applicator unit precedes the transfer unit, and the transfer layer is detached from the carrier film in the transfer unit in the regions in which adhesive is applied. By printing units being converted into transfer units or applicator units, the functionality of the printing unit for a printing operation is lost. If the applicator device and the transfer device are located in this order on an impression cylinder of a printing unit, the applied adhesive is not predried sufficiently. To overcome these disadvantages, the transfer unit is a further processing unit and has at least one further processing device which follows the transfer nip and which acts on the print carrier.

Abstract: An adhesive transfer device can reliably transfer by simple operation an adhesive onto a transfer target surface by either of spot-like transfer and linear transfer that are alternately selected. The adhesive transfer device has a supply reel (20) around which a transfer tape (1) having a backing material (2) provided with an adhesive (3) on one surface thereof is wound, a take-up reel (30) for taking up the transfer tape, and a transfer head (40) for transferring the adhesive onto the transfer target surface. The transfer head is pivotally supported at one end thereof and includes a first transfer section (45a) formed at a free end portion thereof and having a circular arc-shaped contact surface for mutual contact with the transfer target surface, a second transfer section (45b) having a flat transfer surface (45c) between the first transfer section and a pivot portion of the transfer head, and a spring member (46) for urging the free end portion of the transfer head toward the transfer target surface.

Abstract: A defect testing apparatus for testing defects of optical film sheet-shaped product of an optical displaying apparatus, which includes a defect detecting means for detecting defects of a monolayer body and/or a laminate body constituting the sheet-shaped product in a state in which a protective layer on a surface of the sheet-shaped product is not disposed and defect information preparing means for preparing defect information which is information related to the defects detected by the defect detecting means, and the defect information is used for producing the sheet-shaped product provided in a roll form or in separate sheets.

Abstract: A vehicle identification number (VIN) label is provided. The label includes an adhesive layer; a self-destruct layer positioned on the adhesive layer; a first facestock layer positioned on the self-destruct layer; a second facestock layer positioned on the first facestock layer and defining a first window relative to the first facestock layer; and an indicia layer with a first vehicle identification number (VIN) within the first window of the second facestock layer.

Abstract: A special patch is adhered to the bare metal of a dash panel in covering relation to one or more pass-through holes and their margins before a truck cab is primed and painted. After painting, a cover of the patch is peeled off to expose an electrically conductive medium that remains adhered to the bare metal. A ground block is mounted on the dash panel with a stud passing through a pass-through hole. The electrically conductive medium establishes conductivity of the body of the ground block to the dash panel.

Abstract: A closure for a product retaining container constructed for being inserted and securely retained in a portal forming neck of the container has a substantially cylindrical shape and substantially flat terminating surfaces forming the opposed ends of said closure, wherein at least one of said terminating surfaces is at least partially covered by a decorative layer. Indicia may be applied on at least one of the two substantially flat terminating surfaces forming the opposed ends of a closure by means of hot stamping.

Abstract: A tool and a method for packaging lens module are provided. The method for packaging lens module includes the following steps. Firstly, a carrier having at least one cavity is provided. Next, a holder is disposed in the cavity. Then, a die is disposed on a surface of a substrate. After that, the substrate is inversely placed on the carrier, wherein the surface where the die is disposed faces the carrier, and the die corresponds to the holder. Then, a cover plate covers the carrier and the substrate, such that the substrate is fixed on the holder.

Abstract: A method of imaging thermoplastics, such as acrylic glass, is presented. An image is formed on a transfer sheet or medium, and is heat transferred to the acrylic glass substrate on which the image is to permanently appear. An opaque pass-through coating is applied to one surface of the clear or transparent acrylic glass article. Heat activatable dye forms the image, and the heat activatable dye, when heat activated in close relationship to the opaque pass-through coating, passes through the opaque pass-through coating to the thermoplastic substrate. The image reflects light through the thermoplastic material and is visible through the material and from the side opposite the opaque coating. The opaque pass-through coating layer permanently bonds to the acrylic glass surface.

Abstract: A plurality of adhesive labels (10), each of a rectangular strip shape, are applied at predetermined spaced intervals to a peel-off sheet (14) of paper, which is then rolled into an adhesive label roll (12). Each of the adhesive labels (10) has a non-adhesion area (10a) centrally on a reverse side thereof facing the peel-off sheet (14), the non-adhesion area (10a) having no or weak adhesion force, and a first adhesion area (10b) and a second adhesion area (10c) which are disposed respectively on both sides of the non-adhesion area (10a).

Abstract: In a method and apparatus for transferring carbonaceous material layer, a carbonaceous material layer is grown on a growth substrate, and a first continuous conveying unit is used to feed the growth substrate and a transfer material, so that a gluing layer of the transfer material is attached to the carbonaceous material layer on the growth substrate. Then, a transformation device changes a viscosity of the gluing layer for the latter to adhere to the carbonaceous material layer. A second continuous conveying unit is further used to transfer and then separate the mutually adhered transfer material and growth substrate from each other, so that some part of the carbonaceous material layer is transferred onto the gluing layer while other part of the carbonaceous material layer remains on the growth substrate. Thus, at least a one-layer-thickness of the carbonaceous material layer is transferred.

Abstract: Provided is a patterning method, wherein a donor substrate, in which a light-to-heat conversion layer and a division pattern are formed on a substrate and a transferring material exists within said division pattern, is opposed to a device substrate and said transferring material is transferred on the device substrate by irradiating the light-to-heat conversion layer with light so that at least a part of said transferring material and at least apart of said division pattern are simultaneously heated. The patterning method enables large size and highly accurate fine patterning without degrading characteristics of thin films such as organic EL materials.

Abstract: A method of forming a metallic material on a receptor that includes the steps of: placing a donor element proximate a receptor, wherein the donor element includes a donor substrate and a thermal transfer layer, wherein the thermal transfer layer includes a catalytic material, and wherein the thermal transfer layer of the donor element is placed proximate the surface of the receptor; thermally transferring at least a portion of the thermal transfer layer from the donor element to the receptor; and electrolessly depositing a metallic material on the receptor by growth of the metallic material on the catalytic material.

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: An embodiment of the inventive method of transfer lamination bonding a first metallized side of a film to a substrate. Then a breakaway coating is applied to a second, non-metallized side of the film after the first metallized side has been bonded to the substrate. The bonded film and substrate are then placed in an oven. The film is then stripped from the substrate leaving metal from the film deposited on the substrate. The application of the breakaway coating is performed as an inline part of the transfer lamination process thereby providing an ease of manufacture presently unknown.

Abstract: A tape for use in automated tape laying machines that includes a multi-layer substrate composed of a plastic layer that includes at least one plastic film having an outer film surface and an inner film surface. The plastic film is adhered to a fibrous layer so that the inner surface of the fibrous layer is bonded to the inner film surface. An uncured composite material layer composed of a fibrous reinforcement and an uncured resin matrix is releasably adhered to either the plastic layer surface or the outer fiber layer surface to provide a tape suitable for use in an automatic tape layer.

Abstract: A thermal transfer sheet having a subbing layer and a dye layer in this order on a substrate film, wherein the subbing layer contains colloidal silica or colloidal alumina, and the dye layer contains a polyvinyl acetal resin having an acetacetal group in an amount of from 3.0 to 30.0 molar times the butyral group therein, and a dye of the following formula (1): wherein A represents a phenylene group; R1 and R2 represent a hydrogen atom, an alkyl group, or an aryl group; R3 represents an amino group, an alkoxy group, or an aryloxy group; and R4 represents an alkyl group, or an aryl group.

Abstract: A method of image formation comprising putting a thermal transfer sheet and a thermal transfer image-receiving sheet one upon another wherein the thermal transfer sheet has on a substrate film a subbing layer of a titanium oxide film, the dye layer on a part of the subbing layer and a transferable protective layer laminate on the other part of the subbing layer than the part for the dye layer thereon, and wherein the thermal transfer image-receiving sheet has on a support the receiving layer containing a polymer latex, in which vinyl chloride is polymerized in at least 95 mol % of all the polymerization monomers, and a polyether-modified silicone, and a heat-insulating layer; recording an image on the receiving layer by a heating device; and transferring at least a part of the transferable protective layer laminate onto the receiving layer by the heating device.

Abstract: This invention relates to a process for preparing a substrate-supported aligned carbon nanotube film including: synthesizing a layer of aligned carbon nanotubes on the substrate capable of supporting nanotube growth, applying a layer of a second substrate to a top surface of aligned carbon nanotube layer, removing said substrate capable of supporting nanotube growth to provide an aligned carbon nanotube film supported on said second substrate.

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: Method and systems are provided for decorating product packaging. A substrate suitable for product packaging to a thermal printer, such as a thermal transfer printer. A decoration is selected for printing on the substrate. The thermal printer is operated to print at least a portion of the decoration on the substrate.

Abstract: An image-forming method, containing: providing a heat-sensitive transfer image-receiving sheet having at least one heat insulation layer containing hollow polymer particles and at least one receptor layer containing at least one latex polymer, in this order on a support, and a heat-sensitive transfer sheet having a thermal transfer layer containing a thermal transferable dye; feeding the sheets through, between a rotatable platen roller and a thermal head having heating elements aligned in a main scan direction, to move the sheets in a sub scan direction approximately perpendicular to the main scan direction, to form an image on the image-receiving sheet, in which the thermal head has a glaze provided with the heating elements and formed in a convex shape, and the glaze's convex vertex is shifted to an upstream side in the sub scan direction, with respect to the center's position of the heating elements.

Abstract: A retransfer intermediate sheet for receiving an image to be printed onto an article by thermal retransfer comprises a substrate; and an image-receiving coating on one side of the substrate for receiving an image by printing of dye-containing ink, the coating comprising a fluid-absorbing layer and a superposed dye management layer comprising functionalised polyvinyl alcohol and/or an ionic polymer. The dye management layer functions to reduce back diffusion and to increase dye transfer efficiency, resulting in production of printed images of improved optical density. The sheet can be heat-deformable, and finds particular use in printing on 3D articles, e.g. being heated and vacuum formed to conform to an article. The invention also covers a method of printing and an article bearing a printed image.

Abstract: A transfer film including a protection layer and a substrate is provided. The substrate has a first surface with a first three-dimensional pattern and a second surface. The first three-dimensional pattern has at least one protrusion portion or at least one recess portion. The protection layer is disposed on the substrate and has a third surface and a fourth surface. The third surface contacts the first surface and has a second three-dimensional pattern complementary to the first three-dimensional pattern. The second three-dimensional pattern of the third surface is formed by covering the first three-dimensional pattern of the first surface. The protection layer and the substrate are separated after transfer, so as to expose the second three-dimensional pattern.

Abstract: A heat-sensitive transfer sheet, having: a base film; a dye layer; and a heat-resistant lubricating layer; wherein the heat-resistant lubricating layer contains a specific compound, and wherein, when a characteristic X-ray intensity originated from K-line of phosphorus element in the heat-resistant lubricating layer is measured with respect to each points within a 200 ?m square region, the largest value of the characteristic X-ray intensity is at least 2.5 times or more relative to the smallest value of the characteristic X-ray intensity within the 200 ?m square region, and a plurality of maximum regions having a maximum value of the characteristic X-ray intensity exist in the 200 ?m square region, and a variation coefficient that is obtained by dividing a standard deviation of the maximum values of the characteristic X-ray intensity among these maximum regions with an average value of the characteristic X-ray intensities is 0.25 or less.

Abstract: A heat-sensitive transfer sheet, containing: a base film; a dye layer; and a heat-resistant lubricating layer containing talc particles; wherein, when a projected area corresponding to each of the talc particles in the heat-resistant lubricating layer is obtained from an electron beam image that is obtained by irradiating electron beams accelerated at 20 kV from a side of the heat-resistant lubricating layer of the heat-sensitive transfer sheet using a scanning electronic microscope, an average projected area of talc particles each having the projected area of 10 square ?m or more is 80 square ?m or less, and a variation coefficient that is obtained by dividing a standard deviation of the projected areas of talc particles each having the projected area of 10 square ?m or more by the average projected area is 0.8 or less.

Abstract: A heat-sensitive transfer sheet at least having a polyester support, a barrier layer, a heat-sensitive transfer layer containing a dye and a binder, both layers being applied on a surface of the support in this order, and having the heat-sensitive transfer layer including yellow, magenta, and cyan heat-sensitive transfer layers, and the yellow, magenta, and cyan heat-sensitive transfer layers and a protective layer being formed in area order, wherein the barrier layer contains a polyvinylpyrrolidone and cyan heat-sensitive transfer layer contains at least one silicone oil and at least one dye represented by the following formula (C1): wherein Ar represents a substituted or unsubstituted p-phenylene group; R1 represents a substituted or unsubstituted alkyl group; R2 represents a substituted or unsubstituted acylamino group, or a substituted or unsubstituted alkoxycarbonylamino group; R3 and R4 each independently represent a substituted or unsubstituted alkyl group, a substituted or unsubstituted alkenyl gr

Abstract: An image formation apparatus includes a transporting section configured to transport a thermal transfer sheet; a carrying section configured to carry a thermal transfer receiving sheet; a thermal head configured to sequentially thermally transfer the color material layer and the protective layer of the thermal transfer sheet onto the thermal transfer receiving sheet by applying thermal energy; and a controlling section configured to control the thermal energy, wherein the controlling section is configured to print an image under printing conditions where variation ?H in a thickness of the thermal transfer receiving sheet in an increase direction before and after the thermal transfer of the color material layer satisfies 0<?H, and variation ?L in the thickness of the thermal transfer receiving sheet in the increase direction before and after the thermal transfer of the protective layer satisfies ?L<0.

Abstract: A process for creating and applying a soft, high-definition, complex shaped appliqué such that the shape of the appliqué is not distorted when stitched onto a garment and the appliqué can optionally be embroidered without requiring additional alignment processes. The appliqués are made by sublimating a high-definition image onto an upper fabric capable of retaining the high-definition image, affixing the upper fabric to a soft backing fabric capable of resisting dimensional distortion, and then laser cutting the complex shape such that the resulting appliqué can be stitched onto a garment.

Abstract: The double-sided pressure-sensitive adhesive tape or sheet is a double-sided pressure-sensitive adhesive tape or sheet containing a support having a pressure-sensitive adhesive layer on the both surfaces thereof, characterized in that the double-sided pressure-sensitive adhesive tape or sheet has a total thickness including the thickness of the support and the two pressure-sensitive adhesive layers formed on the both surfaces of the support of 0.003 mm or more and less than 0.03 mm and a breaking strength of from 2 to 26 MPa/10 mm-width. The support preferably has a thickness of from 0.002 to 0.012 mm. As the support, plastic films (especially, a polyethylene terephthalate film) are suitable. The double-sided pressure-sensitive adhesive tape or sheet may have a length of 5 m or more and have a roll-wound form.

Abstract: An apparatus and method for laminating personalized cards, which includes a frame that supports a supply spindle for delivering a patch film disposed on a web to a personalized card. The frame supports a platen structure for affixing a portion of the patch film to a portion of one side of the personalized card when the supply spindle delivers the patch film to the personalized card. The frame supports a take-up spindle for receiving the web after the patch film has been delivered to the personalized card. The frame supports a lamination assembly for laminating the entire patch film to the entire side of the personalized card after the personalized card has had the patch partially affixed thereto.

Abstract: The present invention pertains to a heat transfer label that can be modified by an end user in order to indicate variable data prior to transfer of the heat transfer label to a substrate. The label can include fixed data and a region where the variable data is provided or applied and through which the data is viewed when the label is affixed to an object or item. A method for marking the variable data or graphic into the heat transfer label includes punching holes through, or selectively removing ink from, an area of ink located on the heat transfer label tape or strips. The blocks of inked areas are punched or the ink is removed from portions of the block inked area to form a pattern or code correlating to the variable data or graphic and may be configured to be read by human or machine.

Abstract: A method and an apparatus for reducing web tension change during intermittent driving of a transfer film in a film transfer unit, include severely impairing the web tension by contact sections before and after a transfer nip of the film transfer unit as the transfer film runs through a channel at the transfer nip. In order to reduce the web tension changes, front and/or rear guide elements before and after the transfer nip are moved time-asynchronously in relation to one other in order to at least reduce web tension fluctuations of the transfer film as it passes through the transfer nip.

Abstract: A method of making an electrically conductive patterned film (74), such as an RFID antenna, is disclosed. The method includes the steps of providing a layer of conductive metal (24) adjacent a layer of release coating (20); providing a patterned adhesive layer (400) adjacent a target substrate (42); contacting the layer of conductive metal (24) and the patterned adhesive layer (40), such that a corresponding portion (70) of the layer of conductive metal (24) contacts the patterned adhesive layer (40); and the patterned adhesive layer (40) stripping the corresponding portion (70) of the layer of conductive metal (24) from the release coating (20). The patterned adhesive layer (40) can be formed in the shape of an RFID antenna. An electrical component or a computer chip (80) can be directly applied to the layer of conductive metal (24). An RFID device, such as an RFID tag or label is also disclosed.

Abstract: A film transfer apparatus includes an application unit, a transfer unit downstream of the application unit, and at least one third unit for further processing a printing material with a transfer layer applied. In the prior art, if contact pressure is exerted on coated printing material again in a following nip, the adhesive layer under the transfer layer can be pressed out. A blanket can then be contaminated with adhesive, ink itself can be contaminated and parts of the transfer layer can be detached from the coated sheet. In order to avoid pressing out the adhesive, measured values in the transfer unit are compared with corresponding values in the third unit. At least one controlled variable in the units can then be readjusted on the basis of a difference, to at least reduce the quantity of adhesive squeezed out. A transfer method and a covering surface are also provided.

Abstract: A printer apparatus including a printing-medium conveying unit conveying a printing medium, a sheet conveying unit conveying a thermal transfer sheet having an image protecting layer to be thermally transferred onto an image formed on the printing medium, a thermal head with heating elements linearly arranged in a direction orthogonal to a conveyance direction of the printing medium, and a control unit driving and controlling the thermal head. For selectively applying different amounts of thermal energy to the heating elements to form an uneven pattern on the image protecting layer thermally transferred onto the image on the printing medium, the control unit randomly divides a row of the heating elements into heating element groups each including at least two adjacent heating elements, applies the same amount of thermal energy to heating elements in the same heating element group, and applies different amounts of thermal energy to adjacent heating element groups.

Abstract: The invention concerns a process for the production of a conductor track structure on a flexible plastic film, a conductor track structure produced in accordance therewith, wherein the conductor track structure is connected to the plastic film by means of an adhesive layer hardened by irradiation, and is formed from an electrically conducting thin film layer in pattern form, which is galvanically reinforced with at least one metal layer, as well as an electronic component or an electronic circuit having such a conductor track structure.

Abstract: A method that combines a cold film transfer method with an inline embossing apparatus within a sheet-fed printing press is provided. The method includes the step of applying an adhesive coating to image areas on a printed sheet using an application mechanism. The printed sheet with the adhesive is conducted to a coating module. Image-forming layers are transferred from a transfer film that is guided through a transfer nip defined by an impression cylinder and a pressing roller in the coating module. The transfer film is guided through the transfer nip in such a way that a side of the transfer film coated with an image forming layer lies on the printed sheet guided on the impression cylinder and is guided together with the printed sheet under pressure through the transfer nip. The image-forming layer adheres in the image areas provided with adhesive on the printed sheet and is lifted from the carrier film.

Abstract: A manufacturing apparatus (20) has first and second reel-out mechanisms (32a, 32b), first and second processing mechanisms (36a, 36b), first and second label bonding mechanisms (40a, 40b), first and second reservoir mechanisms (42a, 42b), first and second peeling mechanisms (44a, 44b), a substrate feed mechanism (45), an attachment mechanism (46), and a base peeling mechanism (186). A cooling mechanism (122) is disposed between the attachment mechanism (46) and the base peeling mechanism (186), for cooling an attached substrate (24a), the attached substrate (24a) being made up of a glass substrate (24) and a photosensitive web (22) attached thereto, from which a protective film (30) has been peeled off, together with a heating mechanism (182) for heating a resin layer, for example a cushion layer (27), inside the cooled attached substrate (24a) to within a predetermined temperature range, which is at or below the glass transition temperature.

Abstract: In an image-forming method, a ribbon-shaped thermal transfer sheet with a dye layer and a protective material layer arranged side-by-side in the longitudinal direction is moved, and thermal energy is applied from a thermal head while arranging a recording medium to face the dye layer to thermally transfer the dye layer onto the recording medium to form an image. Thermal energy is applied while arranging the image to face the protective material layer to thereby form a protective layer on the image by thermal transfer. A ribbon-shaped surface-property-modifying sheet including a surface-property-modifying region for modifying the surface of the protective layer is moved, and the protective layer is aligned with the surface-property-modifying region of the surface-property-modifying sheet. Heat and pressure are applied from the thermal head and the surface-property-modifying sheet is detached after cooling to modify the surface condition of the protective layer.

Abstract: A transfer-type adhesive material A is obtained by applying a adhesive 1 composed of a adhesive composition 10 (not shown) containing an acrylic polymer or a styrene-based polymer onto a release substrate in an intermittent pattern. The present invention includes pressing a nut N and a washer W as hard articles against the above-mentioned transfer-type adhesive material A, transferring a plurality of dots 1d of the adhesive 1 onto pressed surfaces Na and Wa of the nut N and the washer W, and applying onto a target surface C1b the plurality of dots 1d of the adhesive 1 transferred onto the pressed surfaces Na and Wa.

Abstract: A repair device which includes an intermittent coating of PSA on a first side of a sheet of release paper. The cured PSA may be easily transferred to a surface by pressing the release paper against the surface thereby effectively transferring the intermittent coating of PSA to the surface. The improved repair device is useful for repairing delaminated or detached wallpaper; holding wall patch repair devices in place during the application of spackling or repair compound and holding door hinges in place during the installation thereof.

Abstract: An imprinting device includes a first substrate, a light blocking layer formed on the first substrate corresponding to a light blocking area, and a patterned layer formed on the first substrate. The patterned layer includes an etch pattern and a flow control pattern formed on the first substrate corresponding to a transmittance area and the light blocking area, respectively. When the patterned layer presses a resin layer, the resin layer pressed by the etch pattern moves towards the flow control pattern or a photosensitive resin layer pressed by the flow control pattern moves towards the etch pattern according to a shape of the flow control pattern. Thus, when the shape of the flow control pattern is controlled, the resin layer pressed by the patterned layer may be formed with a uniform thickness.

Abstract: A method and an apparatus for automated application of paint film to bodywork parts (1) and to a paint film composite (5) which is suitable for automation. A paint film composite (5) which is suitable for automation is created and adhesively bonded onto the bodywork part (1) in an accurate position and without any bubbles or creases by means of a robot-controlled application tool that is appropriate for this purpose. To securely hold the film composite (5), which has been picked up from a substrate, the suction grippers (30, 31) which grip the ends are angled in mirror-image form, in order in this way to prevent the ends from becoming detached from the suction grippers. The lower protective strip (9) is then at least partially pulled off, thus exposing the adhesive face of the useful part (6) of the paint film. The film composite (5) is aligned in the correct orientation at a short distance from the bodywork part (1) and the useful part (6) of the paint film is wiped onto the bodywork surface (1).