GE’s Catalyst turboprop engine has reached a critical milestone with its recent Federal Aviation Regulation (FAR) Part 33 certification, ensuring its airworthiness and bringing it a step closer to operational deployment. This achievement is not only a technical success but also a testament to the significant innovations behind the engine, including the extensive use of 3D printing in its design. Nearly a third of the Catalyst’s internal components have been created using 3D printing technology, replacing 855 traditionally manufactured parts with just 12 3D-printed ones. The result is a lighter, more efficient engine that promises substantial cost savings in maintenance and fuel consumption.

The Catalyst turboprop engine features optimized components, including the high-temperature turbine and compressor, which have been designed for improved performance. Notably, the engine consumes 18% less fuel than comparable engines, which represents a significant financial advantage for operators. With turboprop fuel costs ranging from $250 to $600 per hour, this reduction in fuel consumption can have a considerable impact on overall operational costs.

A cutting-edge burner has been developed to improve methane combustion efficiency, featuring a unique nozzle design that directs methane flow in three distinct directions, alongside an impeller that guides gas toward the flame. This innovative configuration ensures optimal oxygen-methane mixing and enables complete combustion before external factors like crosswinds can disrupt the process. The burner’s design was made possible through a combination of machine learning, computational fluid dynamics, and additive manufacturing techniques.

Extensive testing at Southwest Research Institute’s (SwRI) indoor facility confirmed the burner’s effectiveness in simulating controlled crosswind conditions. “Even a slight crosswind drastically reduced the efficiency of most burners. We discovered that the structure and movement of the fins inside the burner played a critical role in maintaining optimal performance,” explained SwRI Principal Engineer Alex Schluneker.