A foil stamping system includes a foil stamping apparatus capable of arranging and mounting a plurality of foil rolls about a direction orthogonal to a sheet feeding direction for forming a foil image by applying an adhesive on the sheet and stamping foil thereon, and a hardware processor, wherein the hardware processor includes: a foil roil information acquisitor that acquires foil roll information from the foil stamping apparatus; a job information acquisitor that receives and analyzes a job, and acquires job information; and an instructor that specifies a foil roll on the basis of the foil roll information and the job information transmits data for designating the region to be applied to the foil stamping apparatus, and instructs the foil stamping apparatus to perform foil stamping by the specified foil roll.

A transfer medium producing apparatus is equipped with an ink ejection unit 20 that ejects ink onto a peelable sheet, an adhesive solution application unit 30 that applies an adhesive solution onto the peelable sheet onto which the ink has been ejected, and a control unit 2 that controls the ejection of ink and the application of the adhesive solution to be performed by a wet on wet method.

A multi-application module (1), a multi-application device (2) and a working method for a multi-application device (2). The multi-application module (1) for printing on a substrate (6) or a transfer product (7) includes a printing unit (8) and a multifunctional element (9), wherein a printing nip (10) is formed between the printing unit (8) and the multifunctional element (9), and wherein the multifunctional element (9) has a first multifunctional roller (91) and/or at least one second multifunctional roller (92) and/or a printing table (13), and wherein the printing unit (8) is designed such that it can print along two running directions in the printing nip (10).

The invention relates to a method of printing onto the surface of a substrate, which method comprises a. coating a donor surface with a monolayer of individual particles, b. treating the surface of the substrate to render the affinity of the particles to at least selected regions of the surface of the substrate greater than the affinity of the particles to the donor surface, and c. contacting the surface of the substrate with the donor surface to cause particles to transfer from the donor surface only to the treated selected regions of the surface of the substrate, thereby exposing regions of the donor surface from which particles are transferred to the corresponding regions on the substrate, and characterised in that at least 50 wt. % of the particles are flaky metal pigments comprising a flaky metallic substrate and a surface modification layer of the metallic substrate, wherein the surface modification layer has been made by a treatment of the metallic substrate surface by at least one of the modification substances from the group consisting of phosphate ester, phosphonic esters, phosphonic acids, phosphinate esters, organofunctional silanes, organofunctional titanates, organofunctional zirconates, organofunctional aluminates and mixtures thereof.

A device including a computing unit that is adapted to read a pattern of transfer portions to be realized by means of a printing process prior to operation of the device and to evaluate various options as to input of at least one foil web to the device and reuse of a length of foil web in the device so as to determine that option involves the most efficient use of the foil for realizing the pattern, so that output is obtained that is suitable to be used for realizing optimal control of the device.

Disclosed are systems and methods, including a method that includes depositing a curable adhesive onto a first surface of a substrate in a pre-determined pattern, placing topping material onto the substrate with the deposited adhesive, and applying UV energy to the substrate including the deposited adhesive and the placed topping material to cause curing of the deposited adhesive.

A device including a computing unit that is adapted to read a pattern of transfer portions to be realized by means of a printing process prior to operation of the device and to evaluate various options as to input of at least one foil web to the device and reuse of a length of foil web in the device so as to determine that option involves the most efficient use of the foil for realizing the pattern, so that output is obtained that is suitable to be used for realizing optimal control of the device.

A method and a device for producing and transferring diffractive microstructures to a printing material include applying a fluid to an embossing cylinder and there, during the rotation of the embossing cylinder, solidifying the fluid to such an extent that the fluid is transferred to a printing material in the manner of a film with a solidified microstructure. The embossing cylinder has a cover which is preferably constructed to be either soft as a flexoshim or hard as a nickel shim. A web-fed or sheet-fed rotary printing press having the device is also provided.

Apparatus for picking a garment having a front and a back and placing the garment over a pallet such that the front and the back of the garment are on the front and the back sides respectively of the pallet. The apparatus comprises a picking arm to approach the garment and then withdraw towards the pallet; and one or more adherence locations on the picking arm, the adherence location being smaller than the first side, the adherence location for contacting the garment and causing adherence of the garment at the contact location, thereby causing the picking arm to pull the front of the garment over the front of the pallet, the back of the garment sliding under the first side onto the back of the pallet. Adherence may involve freezing.

A multi-step process involves formulation and treatment of silicone to break the surface tension transforming silicone texture from traditional rubbery-feeling to smooth satin finish. A low viscosity, translucent silicone rubber compound is separated and cured at room temperature. Part A (Base) is modified to include silicone thinner. Part B (Catalyst) is modified to include retarder. Both Parts A and B are weighed to equal parts. Part A is further modified by including color pigment and colorized mica powder. Parts A and B are mixed at a 1:1 ratio. This formulated silicone is poured into a syringe and applied to hand-painted silk fabric to create scarf border and decorative design. Silicone is allowed to set. Silicone is then treated by: (1) applying 170 heat for period of time, contingent on air temperature and humidity; and (2) dusting and lightly brushing the silicone with a 50/50 mixture of mica and rice powder.