A build plate for a three-dimensional printer includes: a rigid, optically transparent, gas-impermeable planar base having an upper surface and a lower surface; and a flexible, optically transparent, gas-permeable sheet having an upper and lower surface, the sheet upper surface comprising a build surface for forming a three-dimensional object, the sheet lower surface positioned on the base upper surface. The build plate includes a gas flow enhancing feature configured to increase gas flow to the build surface.

Provided herein are methods, compositions, devices, and systems for the 3D printing of biomedical implants. In particular, methods and systems are provided for 3D printing of biomedical devices (e.g., endovascular stents) using photo-curable biomaterial inks (e.g., or methacrylated poly(diol citrate)).

Provided herein are methods, compositions, devices, and systems for the 3D printing of biomedical implants. In particular, methods and systems are provided for 3D printing of biomedical devices (e.g., endovascular stents) using photo-curable biomaterial inks (e.g., or methacrylated poly(diol citrate)).

A 3D printer and method for increasing the speed of 3D printing, wherein said 3D printer comprises a heating block, a nozzle (1) attached to the heating block, and a hole through the heating block and the centre of the nozzle (1). In said hole there is a heat conductive material (7) attached in at least one place on the inner side wall of the hole for transferring heat (5) from the side wall towards the centre of the hole.

A 3D printer and method for increasing the speed of 3D printing, wherein said 3D printer comprises a heating block, a nozzle (1) attached to the heating block, and a hole through the heating block and the centre of the nozzle (1). In said hole there is a heat conductive material (7) attached in at least one place on the inner side wall of the hole for transferring heat (5) from the side wall towards the centre of the hole.

A method for checking a component to be produced in an additive manner, having the steps of mechanically exciting at least one additively constructed layer of the component during the additive production of the component, measuring a mechanical response signal of the component, and displaying a warning and/or interrupting the additive production of the component if the mechanical response signal lies outside of a specified tolerance range. A device for the additive production of a component, includes a device for mechanically exciting the at least one additively constructed layer of the component, a measuring unit for measuring the mechanical response signal of the component, and a control unit. The control unit is designed to display the warning and/or interrupt the additive production if the mechanical response signal lies outside of a specified tolerance range.

In example implementations, a method for extracting layers of build material into a carrier. The method includes providing a layer of build material onto a bed. Portions of the layer of build material on the bed are digitally printed with a liquid functional material (LFM). The method repeats providing the layer of build material and digitally printing without applying energy to the LFM to define a structure in layers of build material on the bed. The layers of build material are extracted into a carrier and the carrier is removed.

The present invention relates to a walking robotic cell for the manufacture of on-site printed buildings using a multi-axis 3D printing system, and a method for operating said walking robotic cell. The walking robotic cell comprises a quadruped mobile robotic system acting autonomously and remotely operated, a feeding device, and a multi-axis actuator, which is a reprogrammable electromechanical system, automatically controlled, and programmable offline or online in all its degrees of freedom from an external or remote computer.

A method of printing one or more three-dimensional objects comprises: providing a volume of a photopolymerizable liquid in a closed container including an entry port and an exit port, the entry port and the exit port being connected by a channel therebetween, the container including at least one printing zone comprising at least an optically transparent window to facilitate irradiating excitation light at a first wavelength into a printing zone through the at least an optically transparent window, wherein the photopolymerizable liquid displays non-Newtonian rheological behavior such that the object formed in the photopolymerizable liquid within the printing zone remains at a fixed position or is minimally displaced in the unpolymerized photopolymerizable liquid during formation, directing the excitation light through the at least an optically transparent window into the printing zone to selectively photopolymerize the photopolymerizable liquid in the printing zone without support structures to form a printed object, wherein the printed object remains at a fixed position or is minimally displaced in the unpolymerized photopolymerizable liquid during formation, and applying pressure to the contents of the closed container and/or pumping additional photopolymerizable liquid into the closed container through the entry port to at least transport the printed object out of the printing zone toward the exit port, thereby discharging at least a portion of contents of the closed container out of the closed container through the exit port. Systems for printing one or more three-dimensional objects are also disclosed.

A shaping device for producing a layered body by repeatedly performing a step of forming a powder layer and a step of fixing powder in at least a partial region of the powder layer includes a first liquid application unit configured to apply a first liquid including a binder for binding the powder, a second liquid application unit configured to apply a second liquid for suppressing a flow of the first liquid, and a control unit that controls the first liquid application unit and the second liquid application unit so that where the powder in a first region of the formed powder layer is to be fixed, the first liquid is applied to the first region and the second liquid is applied to a second region adjacent to the first region. The second liquid is a liquid having higher permeability to the powder layer than the first liquid.