A method for printing a three-dimensional optical structure, in particular an ophthalmic lens, wherein the three-dimensional optical structure is built up from layers of printing ink deposited through targeted placement of droplets of printing ink at least partially side by side in consecutive printing steps, wherein a slicing (3) of the three-dimensional structure to be printed is adapted depending on a predefined true layer shape (2) so that during at least one printing step at least one layer is printed depending on the predefined true layer shape (2), wherein the predefined true layer shape (2) comprises the shape and/or volume characteristics of a typical printed layer.

A method for printing a three-dimensional optical structure, in particular an ophthalmic lens, wherein the three-dimensional optical structure is built up from layers of printing ink deposited through targeted placement of droplets of printing ink at least partially side by side in consecutive printing steps, wherein a slicing (3) of the three-dimensional structure to be printed is adapted depending on a predefined true layer shape (2) so that during at least one printing step at least one layer is printed depending on the predefined true layer shape (2), wherein the predefined true layer shape (2) comprises the shape and/or volume characteristics of a typical printed layer.

A 3D printing method providing an improved manufacturing process by providing a plurality of layers forming at least a part of the component, wherein the plurality of layers contains at least one first layer part and at least one second layer part, wherein the at least one first layer part and the at least one second layer part have been manufactured with different manufacturing speeds.

A system and method for manufacturing three-dimensional structures is provided. The system includes plurality of printing stations and a robotic unit configured to interact with the plurality of printing stations, each of the plurality of printing stations being arranged to be accessible by the robotic unit. Each printing station includes a station controller for controlling at least one deposition control parameter. The system further includes a system controller configured to operate the robotic unit, and wherein the system controller is communicatively coupled to the plurality of printing stations for controlling at least an execution of printing tasks being performed on the plurality of printing stations. The station controllers are at least partially controllable by means of the system controller, wherein the system controller is configured to adjust at least one deposition control parameter of each printing station independent of deposition control parameters of other printing stations of the plurality of printing stations.

A system and method for manufacturing three-dimensional structures is provided. The system includes plurality of printing stations and a robotic unit configured to interact with the plurality of printing stations, each of the plurality of printing stations being arranged to be accessible by the robotic unit. Each printing station includes a station controller for controlling at least one deposition control parameter. The system further includes a system controller configured to operate the robotic unit, and wherein the system controller is communicatively coupled to the plurality of printing stations for controlling at least an execution of printing tasks being performed on the plurality of printing stations. The station controllers are at least partially controllable by means of the system controller, wherein the system controller is configured to adjust at least one deposition control parameter of each printing station independent of deposition control parameters of other printing stations of the plurality of printing stations.

A method of printing a 3D object comprising a plurality of discrete elements, the method comprising: receiving a 3D digital model of a shell group comprising one or more shells representing the plurality of discrete elements; defining, in the 3D digital model, a unifying shell to at least partly envelop one or more shells of the shell group to provide a unified digital model comprising the shell group and the unifying shell; assigning the unifying shell with at least one transparent building material that is transparent upon dispensing and solidifying thereof; assigning the one or more shells of the shell group with one or more building materials; and dispensing, in layers, the at least one transparent building material and the one or more building materials according to the unified digital model to form a 3D object comprising one or more discrete elements that are at least partly connected by a unifying element.

A method of printing a 3D object comprising a plurality of discrete elements, the method comprising: receiving a 3D digital model of a shell group comprising one or more shells representing the plurality of discrete elements; defining, in the 3D digital model, a unifying shell to at least partly envelop one or more shells of the shell group to provide a unified digital model comprising the shell group and the unifying shell; assigning the unifying shell with at least one transparent building material that is transparent upon dispensing and solidifying thereof; assigning the one or more shells of the shell group with one or more building materials; and dispensing, in layers, the at least one transparent building material and the one or more building materials according to the unified digital model to form a 3D object comprising one or more discrete elements that are at least partly connected by a unifying element.

A processing system includes: an irradiation part for irradiating an object with an energy beam; a powder supply part for supplying powder to a melt pool formed by an irradiation of the energy beam; an illumination apparatus for illuminating a position of a solidified part where the melt pool is solidified with a second light having a wavelength different from a wavelength of a first light emitted from the melt pool; an imaging apparatus for optically receive at least a part of the first light and at least a part of a third light from a part of the solidified part that is illuminated with the second light; and a display apparatus for displaying, based on an output of the imaging apparatus, an image related to the melt pool and the solidified part.

A system comprising a support member to support a three-dimensional printed job. The three-dimensional printed job has at least one printed part and associated excess build material. The system further includes a force generating arrangement to impart a force on a three-dimensional printed job supported by the support member; and a build material outlet to allow removal of excess build material from a three-dimensional printed job supported by the support member. The system further includes a sensor to sense a change in the support member, a three-dimensional printed job supported by the support member or a combination thereof wherein the change is due to removal of excess build material from the three-dimensional printed job; and a controller to modify the force imparted on a three-dimensional printed job supported by the support member, wherein the controller modifies the force in dependence upon the change sensed by the sensor.

A system comprising a support member to support a three-dimensional printed job. The three-dimensional printed job has at least one printed part and associated excess build material. The system further includes a force generating arrangement to impart a force on a three-dimensional printed job supported by the support member; and a build material outlet to allow removal of excess build material from a three-dimensional printed job supported by the support member. The system further includes a sensor to sense a change in the support member, a three-dimensional printed job supported by the support member or a combination thereof wherein the change is due to removal of excess build material from the three-dimensional printed job; and a controller to modify the force imparted on a three-dimensional printed job supported by the support member, wherein the controller modifies the force in dependence upon the change sensed by the sensor.