There is provided a process for heat transfer printing, comprising: electrostatically printing a transparent release composition onto a transfer material (1) to form a release layer (2) disposed on the transfer material; (1) electrostatically printing an electrostatic ink composition to form an image layer (3) disposed on the release layer (2); applying a heat-activatable adhesive composition to the image layer to form a heat-activatable adhesive layer (4); contacting the heat-activatable adhesive layer (4) with a target substrate (5) under conditions such that the heat-activatable adhesive layer (4) is activated to adhere to the target substrate and the release layer (2) is softened; and separating the target substrate (5) and the transfer material (1) such that the heat-activatable layer (4), image layer (3) and release layer (2) are transferred to the target substrate.

There is disclosed a layered article that can be used in indirect printing, in analog or digital processes. The layered article, when configured as a transfer member, may serve to receive an ink in any form, allow the ink to be treated so as to form an ink image, and permit the application of the ink image on a substrate. The transfer member comprises a support layer and an imaging layer, which may be formed of a silicon matrix including dispersed carbon black particles. Methods for preparing the same are also disclosed.

A transfer material is provided that can be more firmly attached to an image substrate without deteriorating printing characteristics concerning image bleeding, printing resolution, and the like. An ink receiving layer is of a gap-absorbing type. An adhesive layer includes discretely disposed adhesive pieces provided on a surface of the ink receiving layer so as to leave exposed portions on the surface of the ink receiving layer.

A digitally produced heat transfer can be manufactured by digitally printing an image onto the protective coating that is receptive to ink and/or toner to form a printed area and an unprinted area of the protective coating, and digitally printing an attractant precisely onto the printed area and not onto the unprinted area. An adhesive powder can be applied onto the printed area and the unprinted area. The adhesive powder can then be removed from the unprinted area and the remaining adhesive powder can be bonded to the printed area. A digitally produced heat transfer can include a protective coating that is receptive to ink and/or toner, a digital image printed onto the protective coating to form a printed area and an unprinted area of the protective coating, an attractant digitally printed precisely onto the printed area, and an adhesive powder applied onto the attractant.

A recording medium, including: an ink-receiving layer configured to receive an ink for inkjet recording; and a transparent sheet having a total luminous transmittance of 50% or more, wherein the recoding medium has a layered structure in which the transparent sheet and the ink-receiving layer are sequentially stacked, and the ink-receiving layer includes a gap-absorption-type ink-receiving layer including a composition including at least inorganic fine particles and polyvinyl alcohol having a weight-average polymerization degree of 2,000 or more and 5,000 or less and a saponification degree of 70 mol % or more and 90 mol % or less.

A transfer printing paper is provided. The transfer printing paper includes a release layer and a conductive layer. The conductive layer is formed on the release layer and is suitable for being transferred to a flexible material layer. After being transferred to the flexible material layer, the conductive layer is configured to be electrically in contact with a wearer wearing the flexible material layer, so as to conduct a physiological signal of the wearer.

A thermal transfer sheet, which includes a transfer layer, is superposed on a transfer receiving article, and while the transfer layer is continuously transferred onto the article by a printer comprising a sheet supplying device, heating device, sheet winding device, measuring device located between the heating and sheet winding devices to measure the tensile strength of the thermal transfer sheet conveyed along a conveyance path, and release device located between the heating and the measuring devices, under conditions including an applied power for printing: 0.15 W/dot and a conveying speed for the thermal transfer sheet: 84.6 mm/sec., the transfer layer transferred on the article is released from a constituent member in contact with the transfer layer of the thermal transfer sheet, has a tensile strength measured by the measuring device of 0.1 N/cm or less.

The present invention provides a thermal transfer sheet including at least a transfer layer and a substrate. The transfer layer includes at least a protective layer adapted to be peelable from the substrate, and the transfer layer has a peel force in a non-heated state of 1 N/m or more and a peel force in a heated state of 10 N/m or less. The thermal transfer sheet exhibits a high level of adhesion therebetween, even when used in a compact printer that causes the thermal transfer sheet to be heated by the heat of a thermal head. The transfer layer exhibits a high level of releasability when being transferred.

Provided is a releasing member-integrated transfer sheet capable of improving both the conveyability on forming an image on a transfer layer and the transferability on transferring the transfer layer onto a transfer receiving article. A releasing member-integrated transfer sheet includes a releasing member including a first support and an adhesive layer provided on the first support, and a transfer sheet including a second support and a transfer layer provided on the second support, the transfer sheet being integrated with the releasing member such that the adhesive layer is opposed to the second support. The transfer layer is peelable from the second support, and the adhesive force between the second support and the adhesive layer is smaller than the adhesive force between the first support and the adhesive layer to thereby make the releasing member separable from the transfer sheet.

An image recording method includes a first intermediate image forming step of applying an ink onto an intermediate transfer member to form a first intermediate image, a second intermediate image forming step of applying a transfer assisting liquid containing thermoplastic resin particles and rosin-based resin particles to the first intermediate image formed on the intermediate transfer member to form a second intermediate image, and a transfer step of bringing the second intermediate image formed on the intermediate transfer member into contact with a recording medium, peeling off the second intermediate image from the intermediate transfer member while the contact state with the recording medium is maintained, and transferring the second intermediate image to the recording medium. In the transfer step, the second intermediate image brought into contact with the recording medium has a temperature not less than the glass transition temperature of the thermoplastic resin particles.