A process and apparatus for sublimating printed images onto two or more products substantially simultaneously are disclosed. Software components are configured to receive input of a desired number of products to sublimate, and then determine a spatial arrangement of the printed images on transfer media to sublimate the desired number of products substantially simultaneously. The apparatus is configured to print the images onto the media according to the spatial arrangement, then position the media onto a substrate. The products are automatically placed on the media proximate to their corresponding printed images. The apparatus manipulates the media to substantially surround the products and places at least one image onto each side of each product to be sublimated. One or more heating platens engage the media to sublimate the images. The heating platens are configured, using a control, to sublimate multiple products substantially simultaneously in a single thermal cycle.

A process and apparatus for sublimating printed images onto two or more products substantially simultaneously are disclosed. Software components are configured to receive input of a desired number of products to sublimate, and then determine a spatial arrangement of the printed images on transfer media to sublimate the desired number of products substantially simultaneously. The apparatus is configured to print the images onto the media according to the spatial arrangement, then position the media onto a substrate. The products are automatically placed on the media proximate to their corresponding printed images. The apparatus manipulates the media to substantially surround the products and places at least one image onto each side of each product to be sublimated. One or more heating platens engage the media to sublimate the images. The heating platens are configured, using a control, to sublimate multiple products substantially simultaneously in a single thermal cycle.

A heat press including a body, a heat plate, a handle, a cover, a control compartment and an insulation portion. The body includes a first end and a second end. The heat plate is located proximate the first end of the body and is configured to engage ironable materials. The handle is located proximate the second end of the body and is configured to withstand forces from a user. The cover covers a portion of the body and the handle. The control compartment includes an electrical circuit, controls and a display. The control compartment is spaced away from and is at least indirectly electrically coupled to the heat plate. The insulation portion is positioned between the control compartment and the heat plate. The insulation portion includes a first layer of insulating material.

An apparatus for continuous sublimation thermal printing and/or reactivation, which includes a calendering unit and a

vacuum chamber which is adapted to contain the calendering unit in the phase of operation. The vacuum chamber has a body closed by a door at an open and flanged end of the body and a substantially horizontal axis of extension.

An apparel printing system for printing on regions of tubular fabrics with repeating patterns includes a textile printer having a print head and a tubular platen that includes features on the platen surface to retain and register the tubular fabric on the platen surface during printing.

An apparel printing system for printing on regions of tubular fabrics with repeating patterns includes a textile printer having a print head and a tubular platen that includes features on the platen surface to retain and register the tubular fabric on the platen surface during printing.

A heat press docking station base (52) comprises a nest portion (75) and one or more legs (58). The nest portion (52) includes a body shell (60, 62) and a perforated floor (54). The body shell (60, 62) includes a lower surface (63). The perforated floor (54) is connected to the body shell (60, 62). The one or more legs (58) extend from a lower surface (63) of the body shell (60, 62).

A heat press docking station base (52) comprises a nest portion (75) and one or more legs (58). The nest portion (52) includes a body shell (60, 62) and a perforated floor (54). The body shell (60, 62) includes a lower surface (63). The perforated floor (54) is connected to the body shell (60, 62). The one or more legs (58) extend from a lower surface (63) of the body shell (60, 62).

The present disclosure relates to a pretreatment device capable of increasing a number of media on which a pretreatment can be performed within a fixed period. The pretreatment device includes a platen, a pretreatment portion configured to perform the pretreatment on a medium set on the platen, and a belt configured to convey the platen from a set position to the set position via the pretreatment portion. The medium is placed on the platen at the set position. Thus, since the belt conveys the platen on which the medium is set, the pretreatment device is able to perform the pretreatment on a plurality of the media within the fixed period.

A press can include an upper platen, a lower platen, a support arm, and an adjuster. The support arm can be adapted to move the upper platen substantially parallel to the lower paten between an open position and a closed position. The adjuster can have a cam adapted to engage a surface of the support arm and to rotate between a first rotational position and a second rotational position relative to the support arm. Rotation of the cam from the first rotational position to the second rotational position can move the upper platen toward the lower platen.