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With these simulation results, users can optimize material usage based on an automated iterative process which produces high quality designs.Īltair Inspire is used by designers and design engineers to optimize products, components and whole assemblies, generating value over the whole part lifecycle.Website Home Page :Languages Supported:english

The baseline of every optimization is a robust simulation which Altair Inspire provides with the capabilities of the industry proven Optistruct and MotionSolve solvers. Different boundary conditions and simulation cases from linear static to motion analysis and more make a holistic approach possible that’s uniquely Altair. What is Altair Inspire?Īltair Inspire is a sophisticated and highly efficient topology and structure optimization and simulation suite, leveraging the power of Altair’s Optistruct and SimSolid solvers. By utilizing Altair Inspire in the concept design phase, users can arrive at an ideal design concept extremely early in the process and reduce, or even eliminate re-design iterations. Inspire helps them to streamline the production of high-performance, quality parts and products. Simulation-driven design equips its users with the tools necessary to accelerate their overall design process. Leveraging simulation-driven design with Altair Inspire early and often in the design process enables cost savings by reducing material usage, re-design iterations, and overall design time. This enables users to ensure quality and dependable design prior to any prototyping or production. If by using topology optimization we reduce 40% of steel requirement then it would result in direct reduction of 40% of CO2 Key benefits of Topology Optimization apart from sustainabilityĪltair Inspire allows users to rapidly explore and assess designs for static loads, normal modes, buckling and motion through an intuitive user experience leveraging its embedded physics engine. Making 1 ton of steel produces about 1.8 tons of carbon dioxide.

Embedded early in the design process, it enables the creation of designs with minimal mass and maximal stiffness. Topology optimization is a technology for developing optimized structures considering design parameters like expected loads, available design space, materials, and cost.