Technology never stands still. While ixForten 4000 set a massive benchmark in the industry, it has since paved the way for newer iterations. Most notably, its direct successor emerged as ixCube 4-10 .
The software can simulate various load cases, such as uplift or down-pressure from wind, to ensure the fabric doesn't overstress and the supporting steel (columns and beams) meets safety standards.
Tensile membrane structures cannot be designed using standard linear engineering programs because fabrics have no initial stiffness or compression capacity. ixForten 4000 addresses this through specialized numerical analysis modules: ixforten 4000
Evaluates the structural behavior of membrane surfaces, boundary cables, and supporting steel members simultaneously under external loads. Key Capabilities and Features 1. Form-Finding and Geometry Optimization
Non-rigid textile membranes (warp and weft thread properties) Technology never stands still
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: Determining the optimal shape of a tensile structure based on force density and reference strategy modules. The software can simulate various load cases, such
Disclaimer: Information regarding the Ixforten 4000 is based on preliminary industrial analysis.
The software operates through integrated modules that handle the unique physics of flexible membranes:
This is a game-changer for industries where downtime for recoating costs thousands of dollars per hour.
The system is engineered to consume less power while providing maximum output, contributing to reduced operational costs. Applications in Industry