The present invention relates to a movable laminator and a plastic flooring laminating device applied by same. A laminating mechanism, a driving mechanism and a conveying mechanism assembled on a rack compose the laminator which can make continuous reciprocating movements. The movable laminator is then disposed in an automatic production line for plastic flooring to cooperate with an extruder, a rolling unit and a drawing mechanism to laminate a plastic flooring material composed of a substrate layer, a printed layer and a wear-resisting layer into a finished plastic flooring product in an automatic operation manner. Because the time of the lamination of the material by the movable laminator can match the speed at which the material is conveyed and moved, the laminating mechanism is driven by the second power source to move from the front section position to the rear section position on the rack.

Systems, devices, and methods for fabricating finished parts include a system that includes a plurality of die assemblies located at a plurality of respective locations, each die assembly being configured to fabricate a respective finished part. The system further includes a movable gantry press and a robot, each configured to move between the plurality of respective locations. The system further includes a controller configured to receive a input to fabricate a finished part and identify a die assembly of the plurality of die assemblies. The controller is further configured to instruct the movable gantry press and the robot to move to the location of the die assembly. The controller is further configured to instruct the robot to load a blank into the die assembly, and instruct the movable gantry press to operate the die assembly to fabricate the finished part.

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.

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.

Embodiments of the present disclosure are directed to new and improved self-contained compactor systems incorporating a straight-push cylinder design, in which the compactor system is actuated in a horizontal direction. The improved design accommodates increased storage volume, long wear parts, simplified reservoir cleaning, and easier external access to the components, cylinders, and hoses of the self-contained compactor system.

Embodiments of the present disclosure are directed to new and improved self-contained compactor systems incorporating a straight-push cylinder design, in which the compactor system is actuated in a horizontal direction. The improved design accommodates increased storage volume, long wear parts, simplified reservoir cleaning, and easier external access to the components, cylinders, and hoses of the self-contained compactor system.

Retrofit systems for converting a manual press to an automated press. The retrofit systems include a first shaft, a second shaft, a first spacer, and a second spacer. The first shaft is mounted to a first vertical member and is coupled to a first cross member and to a second cross member. The second shaft is mounted to a second vertical member and is coupled to the first cross member and to the second cross member. The first spacer is supported by the first shaft and is disposed between the first vertical member and the first cross member. The second spacer is supported by the second shaft and is disposed between the second vertical member and the first cross member. The first spacer and the second spacer are selected to increase the space between the first cross member and the second cross member to accommodate an automatically actuated press.

An arrangement for pressing liquid-containing raw materials includes a press container which is rotatable about an axis of rotation and the interior of which is subdivided by a pressing membrane into a pressure-medium space and a pressing medium chamber. A filling and emptying opening, which can be closed in a pressure-tight manner and via which liquid-containing material to be pressed can be introduced into the pressing medium chamber, is arranged in the press container. At least one drainage element is located in the pressing medium chamber. The interior of the drainage element communicates with a juice outlet of the press container, via which liquid juice can be supplied to a juice collecting vessel during a pressing process. The press container is formed of a pressure-resistant flexible plastics material and is received in an inherently rigid support framework that is rotatable about the axis of rotation.

An arrangement for pressing liquid-containing raw materials includes a press container which is rotatable about an axis of rotation and the interior of which is subdivided by a pressing membrane into a pressure-medium space and a pressing medium chamber. A filling and emptying opening, which can be closed in a pressure-tight manner and via which liquid-containing material to be pressed can be introduced into the pressing medium chamber, is arranged in the press container. At least one drainage element is located in the pressing medium chamber. The interior of the drainage element communicates with a juice outlet of the press container, via which liquid juice can be supplied to a juice collecting vessel during a pressing process. The press container is formed of a pressure-resistant flexible plastics material and is received in an inherently rigid support framework that is rotatable about the axis of rotation.

A press frame assembly includes a base plate, a load cell, and an overload protection element; a first plate, a plurality of guideposts disposed on the base plate; a plurality of springs disposed on the plurality of guideposts, a displacement transducer arranged to monitor a linear displacement of the first plate, and a controller, in communication with the load cell and the displacement transducer. The first plate is disposed to translate on the plurality of guideposts, and wherein the springs are disposed to urge movement of the first plate in relation to the base plate. The load cell is arranged to monitor a load exerted upon the base plate. The controller generates a signal that is based upon the load exerted upon the base plate or the linear displacement of the first plate in relation to the base plate.