SOLIDWORKS Plastics là một công cụ mạnh mẽ để cải thiện khả năng sản xuất và dự đoán kết quả của một thiết kế chi tiết khuôn phun.
Tại sao chọn SOLIDWORKS Plastics?
SOLIDWORKS Nhựa dễ sử dụng mô phỏng ép phun trực tiếp cho các nhà thiết kế của các bộ phận nhựa và khuôn phun, cũng như phân tích CAE nâng cao. Nó mô phỏng làm thế nào đẻ dòng chảy nhựa chảy trong quá trình ép phun để dự đoán các khuyết tật liên quan đến sản xuất trên các bộ phận và khuôn mẫu.
Các Tính Năng Của SOLIDWORKS Plastics
SOLIDWORKS Plastics is fully embedded in SOLIDWORKS 3D CAD for ease of use and data integrity. Using the same user interface (UI) as SOLIDWORKS in toolbars, menus, and context-sensitive right-click menus ensures rapid familiarization. Built-in tutorials and searchable online help aid learning and troubleshooting.
SOLIDWORKS Plastics supports SOLIDWORKS materials and configurations for easy analysis of multiple loads and product configurations.
With 4,000+ commercial thermoplastic grades, you can browse and select the desired from the customizable built-in material library.
SOLIDWORKS Plastics includes these meshing features:
Wizard for mesh generation and analysis setup
Local Mesh Refinement
Global Mesh Refinement
Boundary Mesh (Shell)
Solid 3D mesh
Parallel Computing (Multi-core)
The 3D Solver benefits from a multi-core CPU (multiple threads).
Predicts how material fills the cavity. Results include distributions of pressure and temperature within the cavity, and detection of potential short shots and weld lines.
Defines up to 10 injection locations on the part cavity automatically. SOLIDWORKS Plastics adds injection locations onto the part based on the geometry and optimized balanced fill pattern.
Predicts the plastic flow pattern through the cavity at the end of fill.
Predicts the depth of sink marks after the part has been ejected and cooled to room temperature.
Results can be exported to eDrawing®
Time needed to fill the whole mold.
Displays the quality of the injection process with ‘confidence of fill’ legend.
User assistant for interpreting results.
Analyzes the part thickness and locates the high thickness ratio.
Displays the maximum pressure to fill the cavity
Displays the melt front temperature history.
Displays the Cavity Temperature field at the end of fill.
Displays the shear rate reached at the end of fill to check the injection process quality.
Estimates cooling time at fill time analysis.
Displays weld lines formed at locations of the part where two (or multiple) melt fronts meet.
Shows the location where high pressure air may be trapped inside the cavity.
Displays the location of sink marks.
Displays the fraction of frozen material into the part at end of fill.
Displays the minimum clamp force for the current injection process.
Displays the cycle time for the current injection process.
Avoid simulating both cavities in a symmetrical mold layout, saving computer time for the simulation.
Evaluates the material freezing process in the cavity. Predicts the temperature to evaluate hot spots, gate freeze, and cycle time. Distributions of pressure, stress, and shrinkage results are also available.
Determines the runner parameters to balance filling between parts
Automates the process of creating common flow control devices and components such as sprues, runners, and gates.
Quickly and easily simulate the impact of the sprues and runners layout.
Hot runners are initially filled with hot polymer at the start of the filling simulation.
Simulates multiple cavities of the same part in the same mold.
Simulates a set of different cavities parts in the same mold.
Include the impact of mold inserts on the simulation
Displays volumetric shrinkage distribution at the end of fill or pack.
Displays density distribution at post-filling end to check the pack phase quality.
Enables you to export part geometry in STL or NASTRAN formats
Exports mesh, residual stress, fiber orientation and material data to run non-linear analysis.
Simulates the coolant flowing inside for the mold cooling analysis
Specific cooling line for narrow channel into the cavity.
Cooling passageway follows the shape or profile of the mold core or cavity to perform rapid uniform cooling process.
Domain category assigned to the runner allows easy selection for runner’s conditions.
Displays the location of sink marks and their depth.
Displays the mold temperature distribution at cooling end.
Displays the displacement distribution due to in-mold stress.
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Tìm Hiểu Thêm Về SOLIDWORKS Plastics
SOLIDWORKS Plastics Datasheet
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Reject Risk in Mold Injection with SOLIDWORKS Plastics
SOLIDWORKS® Plastics takes the guesswork—and the risk—out of designing plastic parts, allowing you to accurately assess manufacturability, functionality, and quality, throughout the design process. The result is shortened cycle times, reduced defects, and the elimination of costly rework.
Turn Your Design Data into Engaging Content
Whether looking for initial approval for your concept, or creating final sales, marketing, and customer service content, you’ll want to present your ideas and products in the best way possible. With the associativity in SOLIDWORKS® solutions, you can create shop-floor and customer-facing content throughout the whole design process. Check out the final chapter in our newly updated Integrated Design–to-Manufacturing Solutions ebook series, to learn more about creating detailed and exciting content to sell and support your products.
Bridge the Gap Between Your Design and Manufacturing Processes
Shorten cycle times. Lower costs. Improve quality. Bringing design and manufacturing together might just be single smartest decision you can make when it comes to streamlining your workflow. In the latest updated eBook series from SOLIDWORKS®, Integrating Design-to-Manufacturing Solutions, you'll learn more about the advantages to be gained by using better tools to integrate your teams and processes.
Bring Your Design and Build Processes Closer Together
Great products start with great design, but even the most innovative ideas will fail if they can’t be manufactured efficiently. What’s required is a set of tools that enable design and manufacturing teams to work concurrently—so that potential manufacturability issues can be identified and resolved earlier in the process. Check out our newly updated Integrated Design-to-Manufacturing Solutions eBook series Chapter 2, and learn more about the benefits of a connected platform of design tools to streamline the handoff to manufacturing.
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