A heat press includes a lower platen and an upper swing arm attached to a base, and an upper platen having a heater therein. The upper platen is coupled to the upper swing arm via a piston rod, and operable via a linkage. The linkage includes a coupler linked between the upper swing arm and a print handle and includes an input link that rotationally couples the print handle to the piston rod such that a motion of the print handle moves the piston rod up or down. The heat press includes a control housing that is electrically coupled to the heater. The upper swing arm is operable to swing the upper platen away from the lower platen when not in contact with the lower platen. The control housing remains in a stationary position regardless of a position of the upper swing arm.

A method for regulating a hot-pressing device, a tool component and a hot-pressing device are described, wherein the closing of the hot-pressing device and the pressing of a first tool component and a second tool component are effected according to a boiling temperature, ascertained in advance, of the liquid contained in a fiber-containing material of at least one preform and a surface temperature of a first molding device of the first tool component.

A thermoforming apparatus is provided having a frame, a pair of opposed platens, a toggle shaft, a kinematic linkage, a form air manifold, and a pair of articulating bearing assemblies. The pair of opposed platens is carried by the frame each with a die, one die configured to engage an opposed face of another die across a heated sheet of thermoformable material in sealed relation there between. The toggle shaft is carried by the frame for rotation. The kinematic linkage is coupled between the toggle shaft and one of the dies. The form air manifold and a source of differential pressure is coupled with a die face on one of the dies. The pair of articulating bearing assemblies is carried by the frame and configured to support the at least one toggle shaft for translation towards and away from the another die and platen. A method is also provided.

A hand-operated screw press for users to press cannabis flower or isolated trichome heads without an air compressor, hydraulic unit or solvents used in the process. A digital load cell is provided, as is a full color LCD touch screen display for showing and recording force in real time. A mechanism for detecting the end point of a process is also provided. A recipe representative of heat plate temperature, time of operation, pressure ramping, capacity of the screw press, type of raw material, or mass of raw material can be created and stored for use on any suitable rosin press machine.

In accordance with some aspects of the present disclosure, a method producing a composite board comprising plastic and cellulose is described. The method includes transmitting a first signal to a pair of opposing hot-platens, receipt of the first signal causing the pair of opposing hot-platens to compress and heat a composite mat; transmitting a second signal to the pair of opposing hot-platens, receipt of the second signal causing the pair of opposing hot-platens to heat and compress the composite mat at substantially a first pressure for a first time period; transmitting a third signal to the pair of opposing hot-platens, receipt of the third signal causing the pair of opposing hot-platens to release the composite mat from the first pressure; and transmitting a fourth signal to a pair of opposing cold-platens, receipt of the fourth signal causing the pair of opposing cold-platens to compress and cool the composite mat.

A heat press includes a base, a handle, a controller, a heater arm, a pressure link, a lower platen, and an upper platen. The handle is pivotally coupled to the base. The controller is integrally formed with the handle. The heater arm is pivotally coupled to the base. The pressure link is pivotally coupled to the handle and the heater arm. The lower platen is connected to base. The upper platen is connected to the heater arm. A surface of the upper platen is separated from a surface of the lower platen in a first position, and the surface of the upper platen is in contact with the surface of the lower platen in a second position.

A heat press includes a handle portion and a curved heat plate. That handle portion may be configured to be grasped by a user, and the curved heat (i.e., having a curved engagement surface) may be configured to engage a heat-activated design implement to transfer a design of the heat-activated design implement to a curved surface of a workpiece. Also disclosed herein, according to various embodiments, is a heat press stand having a curved floor and a hat form for supporting a workpiece (e.g., a hat) during a heat-activated design transfer using the heat press. Associated methods are also disclosed herein.

A heat press includes a lower platen and an upper swing arm attached to a base, and an upper platen having a heater therein. The upper platen is coupled to the upper swing arm via a piston rod, and operable via a linkage. The linkage includes a coupler linked between the upper swing arm and a print handle and includes an input link that rotationally couples the print handle to the piston rod such that a motion of the print handle moves the piston rod up or down. The heat press includes a control housing that is electrically coupled to the heater. The upper swing arm is operable to swing the upper platen away from the lower platen when not in contact with the lower platen. The control housing remains in a stationary position regardless of a position of the upper swing arm.

A heat press device is provided that includes a support structure, a first platen and a heating element assembly that includes a heating element and a second platen. The heat press device further includes a movement assembly configured to change a pressure state between the first platen and the second platen when the heat press device is in a closed configuration. The heat press device can also include an indicator that is configured to convey the pressure state between the first platen and the second platen when the heat press device is in the closed configuration.

In accordance with some aspects of the present disclosure, a method producing a composite board comprising plastic and cellulose is described. The method includes transmitting a first signal to a pair of opposing hot-platens, receipt of the first signal causing the pair of opposing hot-platens to compress and heat a composite mat; transmitting a second signal to the pair of opposing hot-platens, receipt of the second signal causing the pair of opposing hot-platens to heat and compress the composite mat at substantially a first pressure for a first time period; transmitting a third signal to the pair of opposing hot-platens, receipt of the third signal causing the pair of opposing hot-platens to release the composite mat from the first pressure; and transmitting a fourth signal to a pair of opposing cold-platens, receipt of the fourth signal causing the pair of opposing cold-platens to compress and cool the composite mat.