The invention relates to a method and packing system for producing a package for a product to protect the product, during transportation or storage. The method includes digitizing the product so as to form a virtual key form and determining geometric data. The virtual key form is laminated according geometric data in order to form stratoconception layers. Then, the sheet material is cut into packaging layers corresponding the stratoconception layers, and the packaging layers are stacked to form a package for the more stable protection of the product. The packing system includes the product, package and shipping container.

A card manufacturing system includes a locating device and a separation device. A laminate sheet comprising a plurality of cards is received by the locating device and is imaged using first and second imaging modalities. The first imaging modality identifies a location of each of the plurality of information carrying cards within the laminate sheet and the second imaging modality images at least one graphic formed on a surface of the laminate sheet. A position of the at least one graphic with respect to at least one information carrying card is determined and the plurality of cards are removed from the laminate sheet using information corresponding to the location of each of the plurality of information carrying cards when the position of the at least one graphic with respect to the information carrying cards is within a predetermined range.

A method for manufacturing a three-dimensional object includes converting model data of the three-dimensional object into slice data, sintering powder based on the slice data after the conversion, and manufacturing the three-dimensional object by a layered manufacturing process of stacking a plurality of sintered layers. The method includes a part data correction process of correcting positional information of at least one of mutually adjoining part data of the model data of the three-dimensional object, and laying part data on each other by a predetermined amount of overlap, converting the model data corrected in the part data correction process into slice data, and after forming a sintered layer based on the slice data corresponding to one part, forming a sintered layer based on the slice data corresponding to the other part.

A method for depositing composite material onto a tool using an automated machine. The method includes coupling a first mobile platform with a second mobile platform to form a coupled system, the first mobile platform supporting the automated machine and the second mobile platform supporting the tool. The method further includes indexing the automated machine relative to the tool. The method further includes depositing composite material from the automated machine onto the tool while the coupled system moves along a production line.

A card manufacturing system includes a locating device and a separation device. The locating device is configured to identify a position of one or more information carrying cards formed integrally with a laminate sheet and generate information corresponding to the position of the one or more information carrying cards. The separation device includes at least one singulation mechanism configured to separate each of the one or more information carrying cards from the laminate sheet. The singulation mechanism separates the one or more information cards based on the information corresponding to the position of the one or more information carrying cards.

A card manufacturing system includes a locating device and a separation device. A laminate sheet comprising a plurality of cards is received by the locating device and is imaged using first and second imaging modalities. The first imaging modality identifies a location of each of the plurality of information carrying cards within the laminate sheet and the second imaging modality images at least one graphic formed on a surface of the laminate sheet. A position of the at least one graphic with respect to at least one information carrying card is determined and the plurality of cards are removed from the laminate sheet using information corresponding to the location of each of the plurality of information carrying cards when the position of the at least one graphic with respect to the information carrying cards is within a predetermined range.

A hybrid manufacturing apparatus utilizing both additive and subtractive manufacturing processes has a cutting mechanism, a magazine, and a deposition nozzle. A cutting mechanism engages and modifies material fed from a magazine, the finished material of this process to be positioned by a deposition nozzle. More specifically, the cutting mechanism provides a chamber supporting an inlet, an outlet, and at least one cutting head. The inlet receives fresh material, the cutting head is positioned within the chamber to create the desired contours in or on the material, and the material then exits the chamber via the outlet to be deposited according to instructions extracted from a digital model in a form of numerical control (NC) programming language. This model is natively subdivided into individual constructs each defining a set of values to guide creation of corresponding physical sections, and the placement thereof.

The present invention relates to a system and a method for optimizing printing parameters, such as slicing parameters and tool path instructions, for additive manufacturing. The present invention comprises a property analysis module that predicts and analyses properties of a filament object model, representing a constructed 3D object. The filament object model is generated based on the tool path instructions and user specified object properties. Analysis includes comparing the predicted filament object model properties with the user specified property requirements; and further modifying the printing parameters in order to meet the user specified property requirements.

Process control parameters are predicted to fabricate an object using deposition. An input design geometry is provided for the object. A training data set includes past post-build physical inspection data for a plurality of objects that comprise at least one object that is different from the object to be physically fabricated; and training data generated through a repetitive process of randomly choosing values for each of multiple process control parameters and scoring adjustments to the multiple process control parameters as leading to either undesirable or desirable outcomes, the outcomes based respectively on the presence or absence of defects detected in a fabricated object arising from the process control parameter adjustments. A machine learning algorithm is trained using the provided training data set and a predicted optimal set of the multiple process control parameters is generated for initiating and performing the deposition process to fabricate the object.

In a track determination device, a CAD data acquisition unit acquires shape data that represents a shape of a three-dimensional formed object. A deposition direction setting unit generates control information for controlling a lamination device that laminates the molten metal in order to form a formed object, based on the shape data acquired by the CAD data acquisition unit. The control information is information indicating at least a specific deposition direction of the molten metal such that an error between a first deposition position set in advance and a second deposition position in accordance with an actual laminated state is reduced. A control program output unit outputs the control information generated by the deposition direction setting unit.