The majority of existing methodologies for tunnel assessment and classification are rooted in empirical construction practices. Traditionally, these approaches ascertain the magnitude of a tunnel's scale by relying on a solitary parameter, such as its length or cross-sectional dimensions, often neglecting the critical role of environmental factors. This oversight significantly restricts the methods' broader utility. Hence, there is a pressing need to innovate a comprehensive tunnel assessment and grading framework that seamlessly incorporates both geological and environmental parameters, thereby broadening its applicative horizons. To achieve a more nuanced understanding of tunnel scales, an encompassing classification paradigm has been conceived. This paradigm takes into account a spectrum of six critical determinants: tunnel length, cross-sectional dimensions, the geological influence coefficient, the structural importance of the tunnel, the gradient of the tunnel's slope, and the net distance between interconnected tunnels. A sophisticated formula has been devised to calculate the total volume of excavation, with geological considerations primarily hinged on the tunnel's length and cross-sectional dimensions. Additionally, the formula is calibrated to integrate other pivotal factors, notably environmental impacts. Upon this robust foundation, a novel tunnel assessment and classification protocol has been articulated. This protocol harmoniously blends geological and environmental attributes with pragmatic considerations. A case study, focusing on a quintessential tunnel, has been meticulously conducted, yielding results that substantiate the method's efficacy and reliability. The research's deliverables offer a substantive benchmark for tunnel assessments and classifications within contexts characterized by intricate environmental dynamics.