基于多目标寻优的低碳混凝土智能设计OA
Intelligent Design of Low-Carbon Concrete Based on Multi-Objective Optimization
本工作基于人工智能(AI)的低碳混凝土性能预测与配合比优化设计方法.建立了低碳混凝土数据集处理模块,采用归一化处理和基于密度的空间聚类算法(DBSCAN)显著提升了数据质量.建立了粒子群优化算法(PSO)优化的极限梯度提升(XGB)模型,实现了低碳混凝土抗压强度和电通量的准确预测.为实现低碳混凝土性能与碳排放的最优平衡,引入了碳强度指标(Ci)和抗氯离子渗透碳效指标(Qi)并建立了相关预测优化模型,并通过沙普利加性解释方法(SHAP)分析讨论了各组分的影响机制.最后,采用第三代非支配排序遗传算法(NSGA-Ⅲ)进行了碳排放、经济成本、力学性能与耐久性能间的协调寻优,在工程性能与环境影响中寻找最优平衡,确定了针对不同设计需求的最佳配比.研究发现,在满足力学性能要求(抗压强度>50 MPa)和抗氯离子渗透性(电通量<500 C)的前提下,通过优化再生骨料和辅助胶凝材料掺量,可将碳排放控制在 240~260 kg/m3范围内.该研究为低碳混凝土材料性能和碳排放之间的平衡设计提供了新思路和方法,推动了AI技术在低碳混凝土配合比设计中的应用.
Introduction With increasing global emphasis on sustainable development,the CO2 emissions from concrete as the most widely used building material have attracted much attention.Statistics show that cement production accounts for approximately 8%of global CO2 emissions.Low-carbon concrete minimizes lifecycle CO2 emissions through optimized cementitious materials,use of solid waste,and low-carbon technique(e.g.,carbon capture),while still meeting engineering performance standards.However,incorporating recycled aggregates or mineral admixtures,although reducing CO2 emissions,often leads to a deterioration in mechanical properties and durability of concrete.Therefore,how to effectively balance reduced CO2 emissions while maintaining the engineering performance of concrete remains a challenge in low-carbon concrete mix designs. The complex interactions among multiple components of concrete materials make mix proportion design highly complex.Conventional trial-and-error methods show obvious deficiencies in efficiency,cost and precision.Previous research established some performance prediction models based on machine learning methods,which often focused on single performance indicators.There is little systematic research on multi-objective collaborative optimization of mechanical properties.This failure to adequately balance environmental benefits with performance hinders the effective use of AI in designing low-carbon concrete.The result demonstrates that optimizing the proportions of recycled aggregates and supplementary cementitious materials can effectively limit carbon emissions to the range of 240-260 kg CO2/m3 when the mechanical property requirements(i.e.,compressive strength>50 MPa)and chloride ion permeability resistance(i.e.,electric flux<500 C)are satisfied.This study was to offer an approach for achieving a balanced design between material performance and CO2 emissions in low-carbon concrete,and to promote the application of Artificial Intelligence(AI)technology in its mix proportion design. Methods This study introduced an AI-based intelligent design optimization method for low-carbon concrete.The process started with data preprocessing,including normalization and outlier treatment,to enhance dataset quality.Subsequently,various models,optimized via different hyperparameter tuning methods,were benchmarked for high-precision prediction of key performance indicators.The SHapley Additive Explanations(SHAP)analysis was employed to elucidate the impact of mix proportion parameters on concrete performance.The The Non-dominated Sorting Genetic Algorithm Ⅲ(NSGA-Ⅲ)algorithm was then utilized for multi-objective optimization of CO2 emissions,cost,strength,and chloride ion penetration resistance.Two indices,Ci(Carbon intensity index)and Qi(Chloride ion penetration carbon efficiency index),were introduced to quantify the balance between environmental impact and concrete performance.These indices were subsequently employed to evaluate the solutions from the multi-objective optimization,guiding the decision-making process towards a comprehensive and synergistic optimization of material properties and low-carbon characteristics. Results and discussion During data preprocessing,normalization addresses dimensional inconsistencies among feature variables,enhancing their comparability.Furthermore,the Density-Based Spatial Clustering of Applications with Noise(DBSCAN)algorithm effectively identifies specific outliers(i.e.,43 related to compressive strength and 4 concerning electric charge passed),leading to a marked improvement in overall data quality.Comparison of machine learning models shows that eXtreme Gradient Boosting(XGB)model exhibits a superior performance in all prediction tasks,with Particle Swarm Optimization(PSO)achieving R2 of 0.91 for compressive strength and 0.89 for electric charge passed on test sets.Interpretability through SHAP analysis reveals that cement content and water content are the main factors affecting compressive strength,while superplasticizer dosage is a key factor affecting electric charge passed.For carbon efficiency indices,fly ash replacement of cement is an important approach to reduce Ci and Qi,while the negative impact of recycled aggregates on performance often exceeds their carbon reduction benefits.Multi-objective optimization results indicate significant trade-offs among compressive strength,durability,CO2 emissions,and cost.Decision schemes based on carbon efficiency indices further confirm that CO2 emissions can be effectively reduced,while ensuring concrete performance via scientifically proportioning supplementary cementitious materials,and optimizing water-binder ratio and superplasticizer content. Conclusions This study highlighted a significant potential of an AI-driven approach for designing low-carbon concrete,effectively balancing engineering performance with environmental impact.This study could provide valuable insights into achieving tailored concrete properties via utilizing predictive modeling,parameter influence analysis with SHAP,and NSGA-Ⅲ for multi-objective optimization.The proposed intelligent design method incorporating carbon efficiency indices could offer a practical strategy for developing low-carbon concrete,promoting sustainable practices in the construction industry.
元强;夏瑞;刘易;马嘉璐
中南大学土木工程学院,高速铁路建造技术国家工程研究中心,长沙 410075中南大学土木工程学院,高速铁路建造技术国家工程研究中心,长沙 410075中南大学土木工程学院,高速铁路建造技术国家工程研究中心,长沙 410075中南大学土木工程学院,高速铁路建造技术国家工程研究中心,长沙 410075
信息技术与安全科学
低碳混凝土机器学习多目标优化力学性能抗氯离子渗透性
low-carbon concretemachine learningmulti-objective optimizationmechanical propertieschloride ion penetration resistance
《硅酸盐学报》 2026 (3)
878-893,16
国家重点研发计划(2022YFB2602604)中国中铁股份有限公司科技研究开发计划(2023-重大-08).
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