To provide a numerical controller, a numerical control method and a numerical control program enabling to improve laser cutting speed. A numerical controller for dividing a laser cutting range into a plurality of sections and performing cutting in the respective sections with individual laser outputs includes a nonvolatile memory for storing division conditions and laser output conditions for the plurality of respective sections in association with a cutting condition identifier, and a CPU for specifying the cutting condition identifier as a command value along with an axial movement command in a cutting program, thereby sequentially applying the stored laser output conditions to the plurality of respective sections.

Provided is a material-inspection system for planning a cutting pattern for a composite material sheet based on a detected defect. The system comprises one or more sensors to measure one or more material properties of the composite material sheet; a cutter assembly having a cutter tool to cut the composite material sheet; a control system comprising a processor and a storage medium comprising instructions, that when executed by the processor, configured to: obtain an initial cutting pattern for the composite material sheet, wherein the initial cutting pattern comprises a plurality of shapes to be cut; determine a defect in the composite material based on a sensor; determine a reject region in the composite material around the defect; shift one or more shapes of the plurality of shapes away from the reject region; and provide a revised cutting pattern based on the shifting to be cut by the cutter assembly.

A mobile-unit station dedicated to pipe cutting is provided. The station comprises an intermodal container including: a pipe cutting room comprising a first exterior door for egress to an ambient environment at a first end and an interior door at a second end, respectively, of the pipe cutting room and an at least one portal door for egress to the ambient environment on the first end; a temperature controlled clean room separated from the pipe cutting room with a fireproof wall with the interior door therethrough, the pipe cutting room housing a plurality of components therein including: a monorail extending substantially a length of the pipe cutting room, a powered hoist and a powered trolley moveably mounted on the monorail, a pipe conveyor mounted on a floor and aligned with the monorail to provide a hallway between the first door and the second door, a Computer Numerical Control (CNC) pipe cutter and an at least one dust extraction duct of a dust extraction system proximate the pipe supports, the clean room housing a plurality of components therein including: a CNC pipe cutter control box, a computer for the CNC pipe cutter, a heating and air conditioning unit, and a data management system.

The present invention relates to a process for generating a CAM dataset, having the steps of providing (S201) a digital CAD dataset for a dental prosthesis having first reference data for a first spatial reference geometry; providing (S202) a digital CAM dataset having second reference data for a second spatial reference geometry; and integrating (S203) the CAD dataset in the CAM dataset by aligning the first spatial reference geometry of the CAD dataset with the second spatial reference geometry of the CAM dataset.

A method for generating a numerical control program includes first-fourth steps. In the first step, elements related to the shape of a material are created on the basis of information related to the shape of the material. In the second step, processing is executed in which the elements related to the shape of the material which were created in the first step are read into areas to be subjected to processing in the third step. In the third step, a tool path is generated for each element read in the second step. In the fourth step, the tool paths generated for each element in the third step are connected.

Systems and methods are provided for machining dental prostheses including, over a network, receiving data concerning a dental prosthesis, selecting a material from which to machine the dental prosthesis, and determining machining instructions for machining the dental prosthesis based on a nominal enlargement factor corresponding to the selected material. The method can also include storing the machining instructions, receiving a request from a milling machine for a dental prosthesis to be milled by the milling machine, and associating the dental prosthesis with the milling machine. The method can also include selecting a material blank comprised of the selected material, determining a material blank enlargement factor of the selected material blank, modifying the machining instructions according to a difference between the nominal enlargement factor and the material blank enlargement factor, and machining the dental prosthesis according to the modified machining instructions.

A machining state display apparatus includes an achievement degree data storage (9) storing machining condition data relating to each of sets of machining conditions and achievement degree data relating to degrees of achievement of evaluation items to be obtained in machining under each of the sets of machining conditions, with the machining condition data and the achievement degree data being associated with each other, a display part (2) displaying a set of machining conditions and degrees of achievement of the evaluation items corresponding thereto on a display (5), and an input part (6) inputting a signal for selecting one from the evaluation items and a required degree of achievement for the selected evaluation item. The display part (2) recognizes, based on the selected evaluation item and the required degree of achievement, a set of machining conditions corresponding to the required degree of achievement for the selected evaluation item as well as the degrees of achievement of other evaluation items to be obtained under the set of machining conditions by referring to the achievement degree data storage (9), and displays the recognized degrees of achievement on evaluation-item basis and displays the recognized set of machining conditions.

To provide a numerical controller, a numerical control method and a numerical control program enabling to improve laser cutting speed. A numerical controller for dividing a laser cutting range into a plurality of sections and performing cutting in the respective sections with individual laser outputs includes a nonvolatile memory for storing division conditions and laser output conditions for the plurality of respective sections in association with a cutting condition identifier, and a CPU for specifying the cutting condition identifier as a command value along with an axial movement command in a cutting program, thereby sequentially applying the stored laser output conditions to the plurality of respective sections.

A machining condition selecting device includes a machining condition contribution data management unit configured to manage machining condition contribution data in which each of a plurality of machining conditions is associated with a 3-dimensional surface roughness parameter and degrees of contribution to each item of a required condition related to productivity of a target product; a matter of priority acquisition unit configured to acquire a combination of the 3-dimensional surface roughness parameter and at least one item of the required condition as a matter of priority; and a machining condition selection data management unit configured to manage, for each of the plurality of machining conditions, machining condition selection data in which a combination pattern of the matters of priority is associated with a sum of the degrees of contribution to each item in the combination pattern.

A method of additive manufacture of a constituent part of an item is described. The method comprises the following steps. A specification of characteristics is provided for the constituent part. A composition determination system is then used to identify a composition comprising a plurality of component materials predicted to comply with the specification of characteristics. The composition determination system is a system trained using a database of known materials. The constituent part of the item is then manufactured according to the composition identified by the composition determination system using an additive manufacturing system. Items may be manufactured with a plurality of constituent parts each manufactured this way. A method of establishing a computer-implemented composition determination system for manufacture of items and a control system for additive manufacture of an item using heterogeneous materials by an additive manufacturing system are also described.