Projects using AnsysProjects using AnsysMany sheet metal components appear simple, but achieving stable production requires careful control of material flow, blank holding force, forming geometry, springback, and tooling design.
This project involved the complete development of a sheet metal forming system, from product development and forming strategy through tooling design, manufacturing, tryout, and production implementation.
As project lead, I was responsible for product engineering, process development, tooling design, manufacturing support, and production validation. The tooling combined blanking and forming operations within a single system to improve production efficiency while maintaining dimensional consistency and part quality.
The project required balancing manufacturability, tooling durability, production repeatability, and cost efficiency to ensure reliable mass production.
Projects like this are where product development, tooling engineering, and manufacturing execution come together. Many wire forming projects fail not because of the final geometry, but because of incorrect forming sequences, uncontrolled springback, tooling interference, or poor production repeatability.
This project involved the complete development of a wire forming die system, from product definition and forming strategy through tooling design, manufacturing, tryout, and production implementation.
As project lead, I developed the forming sequence, springback compensation strategy, tooling architecture, and manufacturing validation process to ensure the product could be produced consistently at volume rather than simply formed in simulation.
The result was a production-ready wire forming solution capable of transforming straight steel wire into a complex multi-bend component through a controlled single-cycle forming process.
Projects like this are where product development, tooling engineering, and manufacturing execution come together. Many plastic parts can be modeled in CAD. Far fewer successfully make the transition into stable, repeatable production.
This project involved the complete development of a multi-cavity injection molding system, from product design and DFM review through mold flow analysis, tooling development, mold trials, and production launch.
As the project lead, I coordinated product engineering, tooling design, manufacturing support, and process validation to reduce production risk before mass manufacturing. Flow analysis and runner balancing were used to optimize cavity filling and improve process stability prior to cutting steel.
The result was a production-proven injection molding program that successfully moved from concept and CAD development to molded production parts.
Projects like this sit at the intersection of product development, tooling engineering, and manufacturing execution. A plastic part is easy to model in CAD. Producing it consistently across multiple cavities is where the real engineering begins.
This project involved the complete development of a production injection molding system, including DFM review, mold flow analysis, runner balancing, multi-cavity tooling development, and production validation.
The objective was to identify manufacturing risks before steel was cut, improve cavity balance, reduce molding variation, and achieve a smooth transition from CAD design to production parts.
Projects like this sit at the intersection of product development, tooling engineering, and manufacturing reality.