Palatable pellets -- a fundamental framework to produce sustainable pellets via extrusion

In pellet manufacturing various ingredients in powder or particle form are pressed together into a dense product, a pellet, with better nutritional, calorific, and handling properties than the individual input ingredients themselves. For this reason, pellet manufacturing is applied to up-convert industrial co-products from various sectors like agriculture, forestry, human food, or bio-energy production, to valorize their waste-streams into more valuable products. However, processing such diverse ingredient streams presents an industrial challenge and raises the important scientific question: "Under which process conditions do loose pellet ingredients bind together to form a mechanically rigid and durable pellet?" In this work we provide new answers to this old research question by determining the causal relationships between processing parameters and physical pellet quality. Systematic pelleting experiments reveal that the interplay of typical process parameters such as steam conditioning temperature, production rate, and die geometry, can be understood in an overarching framework of process interactions. We introduce the concept of the "stickiness temperature," $\mathrm{T^*}$, marking the onset of critical enthalpic reactions necessary for pellet agglomeration, the boundary condition for bond formation within a pellet. Our framework demonstrates how $T^*$ is achieved through a combination of steam conditioning and friction, and how these conditions can be controlled by adjusting process parameters. Our findings underscore the significance of pellet temperature in conjunction with die residence time, for optimizing physical pellet quality while reducing energy consumption per kilogram of product. Validating our results in a trial and leveraging existing literature data, our framework provides handles to intelligently enhance the efficiency and sustainability of pelleting processes.