An automatic component fabrication system, for use in fabricating a component, includes a control system having a memory that includes a computerized model of the component to be fabricated. A first monitoring system including a first illumination device and at least one camera is communicatively coupled to the control system and is configured to determine a position of the material at a first location. A cutting system is communicatively coupled to the control system and is configured to cut the component from a sheet of material based on the determined position and the computerized model. The automatic component fabrication system also includes a second monitoring system including a second illumination device and at least one camera. The second monitoring system is communicatively coupled to the control system and is configured to compare the fabricated component to the computerized model.

Embodiments provide a pre-cut infeed system for a machine center, such as an edger. A pre-cut infeed system may include an infeed, one or more saws arranged along the infeed, and a scanner optimizer system. The scanner optimizer system may scan a workpiece and determine whether greater value can be obtained from the workpiece by cutting the workpiece transversely into two or more pieces upstream of the machine center. If so, the workpiece may be cut transversely by the saw(s) positioned along the infeed, and the cut pieces may be fed sequentially into the machine center.

The method can include obtaining a digital image of a wood board having a defect, the digital image including a representation of the defect; using a computer: mapping the position and shape of the representation of the defect, and generating blasting instructions based on the mapped position and shape; positioning the wood board in a given position in a cleaning station, the cleaning station having a blasting nozzle and holding the wood board in its coordinate system; and the cleaning station automatically moving the blasting nozzle relative to the wood board and blasting the defect based on the blasting instructions, including moving at least one of the blasting nozzle and the wood board relative to a frame of the cleaning station.

A method includes processing a first substrate in a process chamber of a substrate processing system according to a recipe while the first substrate is supported by a substrate support of the process chamber. The first substrate includes a first surface profile after the processing. The method further includes generating a first profile map of the first surface profile of the first substrate using a substrate measurement system of the substrate processing system. The method further includes processing data from the first profile map using a model. The model outputs a first estimated substrate placement value for a placement of the first substrate relative to one or more components of the substrate support. The method further includes determining a recommended placement for substrates on the substrate support based on the first estimated substrate placement value.

The present disclosure relates to nesting sub-spaces for a machine tool by reading in evaluation criteria for an arrangement of nested sub-spaces, generating sequence data for an arrangement of nested sub-spaces, repeatedly performing a process until the result data exceeds a specified range. The process includes: generating evaluation data by evaluating the sequence data with an evaluation algorithm, generating result data based on a combinatorial logic of the evaluation data with the evaluation criteria, generating calculation data from the sequence data, the evaluation data, and the result data using the evaluation algorithm, generating further sequence data taking into account the calculation data with the evaluation algorithm, and repeating the process until the result data exceeds a specified range. The calculation data acts onto the generation of new sequence data to improve an arrangement of nested sub-spaces with respect to evaluation criteria.

The invention relates to methods and systems for preparing a cutting path for machine cutting of a plurality of parts from a sheet material using beam cutting technology. Each one of the plurality of parts is formed by one of a plurality of two dimensional free form shapes, comprising at least a first shape. The method comprises a step of identifying at least one segment of the first shape, which segment prevents a part of the first shape to be positioned and cut so close to another shape in the plurality of shapes so that only one cut of the cutting beam is found between the parts. The method further comprises a step of modifying the segment to provide a modified first shape. The modified first shape comprises a modified segment, which is configured such that the modified segment allows a part of the first shape to be positioned so close to another shape in the plurality of shapes so that only one cut of the cutting beam is found between the parts whenever the shape of the parts allows it.

A program generator extracts at least one machining process from a machining program, analyzes the machining process, generates information regarding the machining process, gives the machining process a score based on the information regarding the machining process, and determines a sequence of the machining process based on the given score. The information regarding the machining process includes a machining shape to be formed by the machining process. The machining process is given a score based on the machining shape.

Methods for providing a workpiece computer model including a plurality of objects defined in a body of material. A temporary support frame is provided as part of a two-sided machining process in which the workpiece is partially milled from an obverse side. The machine-control instructions are also based on one or more occupying structures added to the workpiece to fill in one or more excess unoccupied regions of the workpiece that would otherwise be machined away during machining of the objects. Providing such occupying structure(s) reduces the amount of machining that needs to be performed.

Planner insight analytics identifies orders and sizes customers can execute to achieve business and operational efficiency. Generating optimal trimming patterns for trimming raw rolls and/or sheets of a flat sheet stock/customer orders includes: (a) receiving customer orders, primary and secondary machine specifications, warehouse inventory, and trade constraints; and (b) generating solutions for (i) order quantity fulfillment, (ii) a primary cutting pattern for the primary machine, (iii) a secondary cutting pattern for the secondary machine, and (iv) inventory details, wherein the solutions are generated with consideration of the initial trade constraints; (c) executing a batch and generating suggestions; (d) generating modified solutions for the parameters in step (b) using revised trade constraints derived from the suggestions generated that override the initial trade constraints in (c); and (e) operating a cutting apparatus. Trim optimization knapsack algorithm with objective function with term relating to trim loss which is eventually minimized is employed.

Methods and apparatus for optimally positioning objects for automated machining are described herein. An example build file generator described herein includes an object file manager to identify a first toolpath volume associated with a first object to be formed via an additive manufacturing (AM) process. The first toolpath volume is based on a first toolpath of a first post-manufacturing process to be used on the first object. The object file manager is also to identify a second toolpath volume associated with a second object to be formed via the AM process. The second toolpath volume is based on a second toolpath of a second post-manufacturing process to be used on the second object. The example build file generator also includes a layout determiner to determine a layout of the first and second objects to be formed on a substrate by the AM process based on the first and second toolpath volumes.