Simufact.forming铆接解决方案

Title: Simufact.forming: Comprehensive Finite Element Analysis Software for Metal Forming Processes

Simufact.forming is a revolutionary platform designed for professionals to harness the power of simulation in crafting complex metal forming processes, from design to evaluation. With its userfriendly graphical user interface (GUI) and proficiency in supporting common Windows operation, Simufact.forming helps streamline the workflow for engineers, enabling them to easily model, plan, and execute processes while also facilitating the postanalysis of results.

Product Overview




Simufact.forming is a tool based on a robust GUI that aids engineers in automating crucial tasks involved in metal forming processes. It allows users to build models, set up processes, and adjust parameters simply, all within the same application. A dedicated module is integrated within the interface for accurately simulating the intricacies of the riveting process. The software's intuitive design and versatility in managing simulations provide a powerful arsenal for innovation and efficiency in manufacturing settings.

重点关注：Riveting Process Simulation


Simufact.forming for Riveting

Simufact.forming's riveting simulation module is a key component geared towards product development and process optimization in the realm of mechanical engineering. This component mitigates the complexities often encountered during the virtual assessment of assemblies prior to physical production. By propelling the visualization of predicted outcomes, this tool can prevent expensive mistakes and iterative problems by offering insights into the design's behavior under realistic conditions.

Software Features

1. Advanced Finite Element Analysis (FEA) capability: Simufact.forming employs a sophisticated FEA solver, derived from Marc, to ensure fast and precise calculation. This feature allows the software to generate complex models and perform previously impossible simulations, culminating in a comprehensive analysis and quick assessment of numerous variables.

2. Precise Material Properties Handling: The material database, encompassing 700 different material types including steels, stainless steels, tool steels, aluminum alloys, and more, provides an integral aspect of the software. This allows for the detailed simulation of compositions such as steel, titanium, magnesium, copper, cast iron, nickel alloys, and cobalt alloys, ensuring that the testing conditions reflect realistic manufacturing scenarios.

3. Rubberlike Performance for Component Evaluation: Simufact.forming's ability to simulate the behavior of rubberlike components overflows traditional FEA limitations. It enables engineers to conduct testing and simulations regarding viscoviscosity, viscoelasticity, and fluidity, ensuring that the software can handle realworld issues in materials engineering.

Case Study: Virtual Testing in Riveting

A practical example is the simulation of rivetting outcomes with prior experimental data. The following scenario showcases how the Simufact.forming application interfaces with realworld conditions to provide informed predictions:

1. Wanguficular Nail Riveting: This simulation illustrates the field of application in general, connecting realworld examples with theoretical predictions. Users are encouraged to match obtained outcomes with experimental data, ensuring accuracy and practical applicability.

2. Solid Riveting Processes: Similar comparisons highlight the transferability and application of the software across various riveting tasks. Whether it's a solid riveting process, pin and slip riveting, blind hole riveting, throughhole riveting, or quickpin riveting, the software mirrors real industrial challenges.

Simufact.forming stands out in its approach towards rationalizing the complexities of metal working processes, offering engineers a powerful yet intuitive tool for simulation and design. Whether crafting detailed models or calculating performance metrics under various conditions, Simufact.forming ensures that every stage of the manufacturing process is optimized for accuracy, productivity, and costeffectiveness.