Design and Development of Small Turbomachinery: Advanced Mechanical and Fluid Dynamics Engineering Solutions

The design and development of small turbomachinery requires advanced skills in the fields of mechanical and fluid dynamics engineering. At our company, we offer tailor-made solutions to meet the needs of our customers, thanks to the expertise of our engineers and the use of cutting-edge technologies.

Small turbomachinery is used in a wide range of applications, including aerospace, automotive, electronics, and energy. Thanks to their small size, these turbomachinery can provide high performance in tight spaces and under particularly challenging operating conditions.

At our company, we offer design and development services for small turbomachinery, using the most advanced technologies in the fields of mechanical and fluid dynamics engineering. Our engineers work closely with our customers to understand their needs and design custom solutions for their specific applications.

Thanks to the use of advanced simulation software, such as those in the Cadence and Concepts NREC suites, we are able to accurately and reliably simulate the behavior of turbomachinery, providing valuable information for design and performance optimization.

Our engineers also use advanced structural analysis techniques, such as finite element modeling (FEA), to ensure that the turbomachinery is structurally robust and able to withstand the stresses it is subjected to during operation. In addition, our engineers take into account production needs and space limitations to ensure that the turbomachinery can be efficiently and reliably mass-produced.

Design Process

At our company, we provide our experience and expertise to offer tailor-made solutions for your small turbomachinery design and development needs. Contact us to request more information about our services and discover how we can help you develop high-quality turbomachinery for your specific applications.

Activities of our small turbomachinery design and development process:

• Analysis of project specifications and customer needs
• Conceptual design
• Aeromechanical analysis and optimization
• Detailed design, taking into account production needs
• Prototyping
• Experimental validation
• Performance optimization, using data collected during the experimental validation phase
• Series production