An exemplary method for simulating an injection molding process may include first generating a mesh model of a structure, and generating a mesh model of an injection unit molding machine, including at least a screw tip of the injection unit. The method may then include providing the ability to specify a material to be injected into the structure, configuring parameters in different zones of at least the injection unit, combining the mesh models of the structure and the injection unit, and providing the ability to apply at least one of a velocity and a pressure profile of the screw tip. The method may then include running a simulated operation of the combined mesh models of the injection unit and the structure.

A three-dimensional printing method for a three-dimensional printer is provided. The three-dimensional printer includes a model printing head and a color printing head arranged along an X-axis and co-constructed, wherein the model printing head prints a forming layer on an X-Y plane of a platform of the three-dimensional printer, and the color printing head colors a coloring zone of the forming layer along a Y-axis. The three-dimensional printing method includes: providing information of the coloring zone of the forming layer; determining the number of colorings of the color printing head according to the information of the coloring zone by a processor; and driving the model printing head by the processor to print the forming material outside a region of the forming layer.

According to examples, computer-readable instructions may cause a processor to obtain a digital model of a screen to be fabricated by a 3D fabrication system, the digital model of the screen including digital pores. The processor may obtain a digital model of a mold body on which the screen is to be removably mounted, the digital model of the mold body including a plurality of digital holes. In addition, the processor may, for a digital pore, determine a distance between the digital pore and a digital hole when the digital model of the screen is positioned on the digital model of the mold body. The processor may further determine whether the determined distance falls below a first threshold and based on a determination that the determined distance falls below the first threshold, cause a parameter of the digital pore to be modified in a first manner.

According to examples, a computer-readable medium may have stored thereon instructions that may cause a processor to obtain a first 3D model of a first portion of a component, the first 3D model may include a first digital attachment edge corresponding to a first attachment edge on the first portion. The processor may obtain a second 3D model of a second portion of the component, the second 3D model may include a second digital attachment edge corresponding to a second attachment edge on the second portion, in which the second portion is to be joined with the first portion to form the component. The processor may modify the first 3D model to include a first digital rib including holes along a segment of the first digital attachment edge and the second 3D model to include a second digital rib including protrusions along a segment of the second attachment edge.

The invention notably relates to a method for determining specifications of the input of a manufacturing operation that outputs a part having cut-outs. The method comprises providing specifications of the output part, including a user-designed B-Rep having cycles of edges and modeling the part, the cut-outs being represented by the user with tunnels in the B-Rep, determining the set that consists of all cycles being the one having the smallest length in a respective equivalence class, performing a process on the set that includes iterating replacing a cycle when this reduces the length, and deleting a cycle when a sum results in a boundary cycle, otherwise replacing the cycle by the sum when this reduces the length. The invention offers an improved solution to detect, in a B-Rep having cycles of edges and modeling a part having cut-outs represented by tunnels, location of at least part of the tunnels.

A system and method for a three-dimensional (3D) printing quoting tool and system is provided for in the present invention. The 3D printing tools contemplated are capable of taking information from and presenting information to customers in order for the customer to have selective input into various aspects of such design and fabrication which affect price of a customized 3D part, and the printer to accurately price a customized 3D part.

The present disclosure provides a method for operating a molding system. The molding system includes a molding machine and a mold disposed on the molding machine, wherein the mold has a mold cavity for being filled with a molding material from the molding machine. The method comprises a step of obtaining a predetermined state waveform expressing a predetermined volumetric variation of the molding material. Next, the method further comprises obtaining a measured pressure and a measured temperature of the molding material in the mold cavity while performing a molding process for filling the molding material into the mold cavity. Next, the method includes obtaining a detected volumetric property of the molding material corresponding to the measured pressure and the measured temperature. Subsequently, the method comprises displaying the detected volumetric property of the molding material with the predetermined state waveform.

A method of setting metal sheet anisotropy information and sheet thickness information for an analysis model of a press-formed panel includes spreading the analysis model of the press-formed panel into a blank shape by analysis of reverse press-forming; acquiring sheet thickness information obtained by the analysis of reverse press-forming; based on a spread-blank-shape and a panel-taking blank shape, acquiring a reference direction of the spread-blank-shape; calculating an angle formed between the reference direction of the spread-blank-shape and each element in the spread-blank-shape, and setting the reference direction for each element of the analysis model of the press-formed panel based on the calculated angle; and setting the sheet thickness information acquired in the sheet-thickness-information acquiring step for each element of the analysis model of the press-formed panel.

The invention relates to a method for transferring a stress state of an FE simulation result to a new FE mesh geometry of a simulated construction system, such as a component for motor vehicles that has a 3-D shape, in a simulation chain of production operations, comprising: a) providing a first data set, which describes the FE simulation result with a stress state of the FE simulation of the construction system or component of a first production operation, b) creating the new FE mesh geometry of the simulated construction system or component, which new FE mesh geometry is associated with a second production operation, c) transferring the stress state of the provided first data set to the new FE mesh geometry of the construction system or component, d) performing an equilibrium calculation by using the stress tensor in the FE mesh geometry, wherein deformation of the construction system or component results, which deformation differs from the deformation in the FE mesh by a shape alteration u>tolerance value , e) iteratively repeating the equilibrium calculation as a cyclic equilibrium iteration in the new FE mesh geometry (in the new target FE mesh) of the construction system or component, wherein, in each cycle, a new stress state is applied to the FE mesh geometry of the construction system or component and stress components that lead to undesired shape alterations are decreased until a displacement/termination criterion of shape alteration u<tolerance value is achieved, and f) displaying the fulfilled condition of u<.

A method for molding analysis of a plate-like intermediate base material containing resin and reinforcing material when the base material is molded, including applying a base material model having anisotropy between out-of-plane direction and an in-plane direction orthogonal to the out-of-plane direction, and calculating viscosity distribution in a cross-section direction of a molded article using each viscosity in accordance with a flow field, and the viscosity distribution indicates that under a boundary condition there is no slip flow of the base material on a wall surface of the mold, as a result of a shear field in the vicinity of the wall surface, a low viscosity layer that is more affected by an out-of-plane shear viscosity than a central portion of the base material is automatically formed in the vicinity of the wall surface, and the base material in the vicinity of the wall surface functions as a lubricating layer.