With the increasing global emphasis on ecological conservation and the sustainable use of resources, the effective utilization of mineral resources has become a pressing priority. Accurate mineral classification helps reduce resource waste, mitigate ecological impact, and improve processing efficiency. This paper proposes a deep learning model for mineral image classification based on the YOLOv8-CLS architecture, specifically targeting seven minerals: bornite, quartz, malachite, pyrite, muscovite, biotite, and chrysocolla, which are the focus of this study. The model was trained and tested on an open-source mineral image dataset, achieving Top-1 and Top-5 accuracy rates of 0.92053 and 0.99399, respectively, after 120 training epochs. During the testing phase, the model was evaluated on the test set, achieving a Top-1 accuracy of 0.90681 and a Top-5 accuracy of 0.99283, demonstrating high accuracy and stability. Although a decline in Top-1 accuracy to 0.80219 was observed when testing the model against a new batch of data and comparing it to the classic ResNet50 and ResNet101 models, the YOLOv8-CLS model still outperforms these models by 0.00684 and 0.04278, respectively, while also having lower performance overhead. Despite some remaining flaws, this study demonstrates that the YOLOv8-CLS model is more efficient than traditional models in intelligent mineral classification, contributing to resource efficiency and promoting the development of sustainable mining practices.