Carbon Emission Analysis of Tunnel Construction of Pumped Storage Power Station with Drilling and Blasting Method Based on Discrete Event Simulation

Carbon Emission Analysis of Tunnel Construction of Pumped Storage Power Station with Drilling and Blasting Method Based on Discrete Event Simulation

Under the “dual-carbon” strategy, accurately quantifying carbon emissions in water conservancy projects is crucial to promoting low-carbon construction. However, existing life cycle assessment (LCA) methods for carbon emissions during the mechanical construction stage often fail to reflect actual pr...

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Bibliographic Details
Main Authors: Yong Zhang, Shunchuan Wu, Haiyong Cheng, Tao Zeng, Zhaopeng Deng, Jinhua Lei
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Buildings
Subjects:
tunnel of pumped storage power station
carbon emissions
mechanical construction
discrete event simulation
different surrounding rock grade
Online Access:https://www.mdpi.com/2075-5309/15/11/1846
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Summary:Under the “dual-carbon” strategy, accurately quantifying carbon emissions in water conservancy projects is crucial to promoting low-carbon construction. However, existing life cycle assessment (LCA) methods for carbon emissions during the mechanical construction stage often fail to reflect actual processes and are limited by high costs and lengthy data collection, potentially leading to inaccurate estimates. To address these challenges, this paper proposes a carbon emission evaluation method for the mechanical construction stage, based on carbon footprint theory and discrete event simulation (DES). This method quantifies equipment operation time and energy consumption during the drilling and blasting processes, enabling a detailed and dynamic emission analysis. Using the Fumin Pumped Storage Power Station Tunnel Project as a case study, a comparative analysis is conducted to examine the carbon emission characteristics of drilling and blasting operations under different surrounding rock conditions based on DES. The validity of the proposed model is confirmed by comparing its results with monitoring data and LCA results. The results show a clear upward trend in carbon emission intensity as surrounding rock conditions deteriorate, with emission intensity rising from 8405.82 kgCO<sub>2</sub>e/m for Class II to 16,189.30 kgCO<sub>2</sub>e/m for Class V in the headrace tunnel. The total carbon emissions of the water conveyance tunnels reach 40,019.64 tCO<sub>2</sub>e, with an average intensity of 13,565.98 kgCO<sub>2</sub>e/m. This study presents a refined and validated framework for assessing the carbon emissions of pumped storage tunnels. It addresses key limitations of traditional LCA methods in the mechanical construction stage and provides a practical tool to support the green transition of hydraulic infrastructure.
ISSN:2075-5309

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