A printer includes a printing head that includes a plurality of heating elements arranged in a first direction and a processor, wherein printing data representing an image to be printed on a printing medium are divided into a plurality of line data, each of the plurality of line data representing a corresponding line segment of the image, extending in the first direction, by a series of dots constituted of printing dots to be printed on the printing medium and non-printing dots that are not printed on the printing medium, and wherein, for each of the line data, the processor obtains distribution information of the printing dots in the line data, and sets an energizing time, during which the selected heating elements are energized continuously, or intermittently by pulses, to print the corresponding printing dots, in accordance with the distribution information of the printing dots in the line data.

A method for introducing a reflective and/or diffractive metallic variable and/or non-variable image to a substrate by use of thermal transfer printing includes simultaneously transferring a defined portion of each of a protective coating layer, a metal layer, and an adhesive layer from a carrier film of a transfer ribbon to the substrate by applying heat to the transfer ribbon. The defined portions of the metal layer and the protective coating layer are adhered to the substrate using the adhesive layer. Subsequent to transferring the protective coating layer, the metal layer, and the adhesive layer, durability is provided to the metal layer by cross-linking the protective coating layer that is over the metal layer by exposing the protective coating layer to a radiation source after the defined portions of the protective coating layer, the metal layer, and the adhesive layer are transferred from the carrier film.

A method for introducing a reflective and/or diffractive metallic variable and/or non-variable image to a substrate by use of thermal transfer printing includes simultaneously transferring a defined portion of each of a protective coating layer, a metal layer, and an adhesive layer from a carrier film of a transfer ribbon to the substrate by applying heat to the transfer ribbon. The defined portions of the metal layer and the protective coating layer are adhered to the substrate using the adhesive layer. Subsequent to transferring the protective coating layer, the metal layer, and the adhesive layer, durability is provided to the metal layer by cross-linking the protective coating layer that is over the metal layer by exposing the protective coating layer to a radiation source after the defined portions of the protective coating layer, the metal layer, and the adhesive layer are transferred from the carrier film.

A printer includes a printing head that includes a plurality of heating elements arranged in a first direction and a processor, wherein printing data representing an image to be printed on a printing medium are divided into a plurality of line data, each of the plurality of line data representing a corresponding line segment of the image, extending in the first direction, by a series of dots constituted of printing dots to be printed on the printing medium and non-printing dots that are not printed on the printing medium, and wherein, for each of the line data, the processor obtains distribution information of the printing dots in the line data, and sets an energizing time, during which the selected heating elements are energized continuously, or intermittently by pulses, to print the corresponding printing dots, in accordance with the distribution information of the printing dots in the line data.

The present disclosure is directed to a printing assembly that includes an image transfer station and a blower configured to intermittently provide a cooling stream of air to a product being printed upon. The blower may include a centrifugal fan and may have a single plenum providing air to two nozzles. The nozzles may be positioned such that the air targets the edges of the product to facilitate removal of the intermediate transfer media from the targeted areas and reduce the occurrence of flash. The blower may be configured to provide air when the product is expelled from the transfer assembly or while the intermediate transfer media is peeled from the product, but not to provide air when the product is being received by the transfer assembly. The printing assembly may include sensors and control circuitry for detecting the position of the product and controlling the blower accordingly.