Boskey V. Bahoria , Prashant B. Pande , Sagar W. Dhengare , Jayant M. Raut , Rajesh M. Bhagat , Nilesh M. Shelke , Satyajit S. Uparkar , Vikrant S. Vairagade
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To enhance the prediction accuracy, PCA was performed on feature dimensionality reduction and GA optimized hyperparameters both for the model as well as the concrete mix design for improved strength with cost effectiveness. With an R² value of 0.92–0.95, the performance results of the presented model came out better than the baseline models, as well as reducing the MAE by 20 %. Besides, there existed a 5–8 % better compressive strength in GA-optimized mix designs. Robustness comes into play with the model that shows steady strength predictions, regardless of conditions of curing under multiple conditions and at different material composition levels. Furthermore, the reutilization of recycled aggregates and nano-silica gives a real environmental benefit as less waste is produced but the material performance is maximized. 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引用次数: 0
摘要
这项工作的主要目的是提高混凝土的抗压强度,特别是在可持续建筑中,开发更精确的预测建模技术。使用混合深度学习模型可以对填充了纳米二氧化硅和再生骨料的玄武岩纤维增强混凝土进行抗压强度预测,该模型建议结合使用卷积神经网络和长短期记忆网络。CNN 从 SEM 图像中捕捉微观结构特征,而 LSTM 则对连续固化数据样本的时间依赖性进行建模。为提高预测精度,对特征维度进行了 PCA 缩减,并通过 GA 优化了模型和混凝土混合设计的超参数,以提高强度和成本效益。该模型的 R² 值为 0.92-0.95,其性能结果优于基线模型,并将 MAE 降低了 20%。此外,GA 优化的混合设计抗压强度提高了 5-8%。该模型的稳健性发挥了作用,无论在多种条件下的固化条件如何,以及在不同的材料成分水平下,该模型都能显示稳定的强度预测。此外,对再生骨料和纳米二氧化硅的再利用也带来了真正的环境效益,因为产生的废料更少,但材料的性能却得到了最大程度的发挥。这种结果表明,所提出的模型可以实际应用于混凝土强度和可持续发展特性的优化设计,从而为建筑领域的决策提供了一个便捷的工具。它是一种有效的工具,可在提高混凝土性能的同时最大限度地减少环境和材料浪费。
Predictive models for properties of hybrid blended modified sustainable concrete incorporating nano-silica, basalt fibers, and recycled aggregates: Application of advanced artificial intelligence techniques
The main objective of this work is to improve the compressive strength of concrete, specially in sustainable construction is to develop more precise predictive modeling techniques. The compressive strength prediction of basalt fiber reinforced concrete filled with nano-silica and recycled aggregates can be done using a hybrid deep learning model suggesting the use of the combination of Convolutional Neural Networks and Long Short-Term Memory networks. The CNN captures microstructural features from SEM images, while the LSTM models temporal dependencies from sequential curing data samples. To enhance the prediction accuracy, PCA was performed on feature dimensionality reduction and GA optimized hyperparameters both for the model as well as the concrete mix design for improved strength with cost effectiveness. With an R² value of 0.92–0.95, the performance results of the presented model came out better than the baseline models, as well as reducing the MAE by 20 %. Besides, there existed a 5–8 % better compressive strength in GA-optimized mix designs. Robustness comes into play with the model that shows steady strength predictions, regardless of conditions of curing under multiple conditions and at different material composition levels. Furthermore, the reutilization of recycled aggregates and nano-silica gives a real environmental benefit as less waste is produced but the material performance is maximized. This kind of outcome indicates how the proposed model can be practically applied in optimizing concrete design in terms of strength and sustainability features, thus providing an accessible instrument for decision-making in the construction field. It is an effective tool to improve the performance of concrete while minimizing environmental and material wastes.
期刊介绍:
Nano-Structures & Nano-Objects is a new journal devoted to all aspects of the synthesis and the properties of this new flourishing domain. The journal is devoted to novel architectures at the nano-level with an emphasis on new synthesis and characterization methods. The journal is focused on the objects rather than on their applications. However, the research for new applications of original nano-structures & nano-objects in various fields such as nano-electronics, energy conversion, catalysis, drug delivery and nano-medicine is also welcome. The scope of Nano-Structures & Nano-Objects involves: -Metal and alloy nanoparticles with complex nanostructures such as shape control, core-shell and dumbells -Oxide nanoparticles and nanostructures, with complex oxide/metal, oxide/surface and oxide /organic interfaces -Inorganic semi-conducting nanoparticles (quantum dots) with an emphasis on new phases, structures, shapes and complexity -Nanostructures involving molecular inorganic species such as nanoparticles of coordination compounds, molecular magnets, spin transition nanoparticles etc. or organic nano-objects, in particular for molecular electronics -Nanostructured materials such as nano-MOFs and nano-zeolites -Hetero-junctions between molecules and nano-objects, between different nano-objects & nanostructures or between nano-objects & nanostructures and surfaces -Methods of characterization specific of the nano size or adapted for the nano size such as X-ray and neutron scattering, light scattering, NMR, Raman, Plasmonics, near field microscopies, various TEM and SEM techniques, magnetic studies, etc .