Examples include apparatuses, processes, and methods for generating three-dimensional objects. An example apparatus comprises build material distributor and a controller. Examples distribute a particular build layer in a build area of the apparatus over a previous build layer. Examples determine a build layer temperature corresponding to the particular build layer. Examples analyze build layer coverage for the particular build layer based at least in part on a build layer temperature of the previous build layer and the build layer temperature of the particular build layer. Examples selectively recoat the particular build layer with additional build material based at least in part on the build layer coverage for the particular build layer.

Examples include apparatuses, processes, and methods for generating three-dimensional objects. An example apparatus comprises build material distributor and a controller. Examples distribute a particular build layer in a build area of the apparatus over a previous build layer. Examples determine a build layer temperature corresponding to the particular build layer. Examples analyze build layer coverage for the particular build layer based at least in part on a build layer temperature of the previous build layer and the build layer temperature of the particular build layer. Examples selectively recoat the particular build layer with additional build material based at least in part on the build layer coverage for the particular build layer.

The present disclosure relates to a 3D bioprinter (1) comprising a base unit (2). The base unit (2) has a support (3) adapted for mounting of at least one toolhead (4), a communication interface part (5) for communication of data with the at least one toolhead (4), when mounted, and a base unit processing element (7) adapted to communicate with a toolhead processing element (8) of the at least one toolhead over said communication interface part (5). The present disclosure relates further to a 3D bioprinter toolhead. The present disclosure relates further to a method for bioprinting a construct.

The present disclosure relates to a 3D bioprinter (1) comprising a base unit (2). The base unit (2) has a support (3) adapted for mounting of at least one toolhead (4), a communication interface part (5) for communication of data with the at least one toolhead (4), when mounted, and a base unit processing element (7) adapted to communicate with a toolhead processing element (8) of the at least one toolhead over said communication interface part (5). The present disclosure relates further to a 3D bioprinter toolhead. The present disclosure relates further to a method for bioprinting a construct.

A fin block is provided for a calibrating device for the calibrating of an extruded profile. The fin block includes a fin structure, which has a plurality of fins which are spaced apart from one another by grooves and are arranged in longitudinal direction of the fin block, wherein the fins of the fin structure have a variable dimension in longitudinal direction of the fin block. Further, there is provided a method for the production of the above-mentioned fin block and a calibrating device, which includes a plurality of the above-mentioned fin blocks. Furthermore, there is provided a system for the additive manufacture of the above-mentioned fin block, a corresponding computer program and corresponding data set.

The present disclosure provides various aspects for mobile and automated processing utilizing additive manufacturing and the methods for their utilization. In some examples, discrete material formats for use in an Additive Manufacturing Array are disclosed. Methods of using the additive manufacturing robot, discrete materials, and the roadways produced with the additive manufacturing robot are provided. A combined function Addibot, with Additive Manufacturing capabilities, cleaning capabilities, line painting capabilities and seal coating capabilities which may be used in concert with a camera equipped aerial drone for design and characterization function is described.

A machine and method of forming an article generally comprising extruding a molten bead of thermoplastic material along x, y and z axes in forming an article consisting of a strata of such material, and passing a roller over each applied portion of such molten bead to compress such bead portion, enhancing the fusion of engaging plies of such extruded material.

A machine and method of forming an article generally comprising extruding a molten bead of thermoplastic material along x, y and z axes in forming an article consisting of a strata of such material, and passing a roller over each applied portion of such molten bead to compress such bead portion, enhancing the fusion of engaging plies of such extruded material.

A cooling assembly, and method, for an article being printed using a selective toner electrophotographic printing system is disclosed. The assembly includes a surface for delivering and returning cooling gas, the surface containing first plurality of elongate openings in communication with a cooling gas supply; and a second plurality elongate openings in communication with a cooling gas return; wherein the first plurality of elongate openings and second plurality of elongate openings are substantially parallel to one another and alternate with one another.

A cooling assembly, and method, for an article being printed using a selective toner electrophotographic printing system is disclosed. The assembly includes a surface for delivering and returning cooling gas, the surface containing first plurality of elongate openings in communication with a cooling gas supply; and a second plurality elongate openings in communication with a cooling gas return; wherein the first plurality of elongate openings and second plurality of elongate openings are substantially parallel to one another and alternate with one another.