Abstract
Global sustainable development relies heavily on stable and efficient grain production, where reliable and durable harvesting machinery plays a crucial role. However, the harsh operating conditions experienced by these machines in the field often lead to premature failure. These failures not only cause crop losses and economic burdens but also undermine sustainability goals by increasing the lifecycle environmental footprint through the consumption of materials and energy for repairs and replacements. Furthermore, unexpected downtime can lead to harvest delays, resulting in food waste and inefficient fuel use. This review focuses on research aimed at enhancing the operational fatigue reliability and durability of harvesting machinery. It specifically reviews the latest advancements in the application of sensor technology, signal processing methods, computer simulation techniques, and data analysis methods to advance harvesting machinery durability research. Furthermore, it identifies the challenges in current research, including obtaining accurate load data, handling uncertainties, and validating models. Looking ahead, this review highlights a necessary shift towards integrated, intelligent systems that can transform harvester design and maintenance from a reactive process into a proactive strategy for ensuring lifecycle sustainability.