Combining Mineral and Polymer Binder Material Science for Sustainability in Construction and Restoration

Restoration of Buildings and Monuments Pub Date : 2015-12-01 DOI:10.1515/rbm-2015-2001

D. Van Gemert, Ö. Cizer

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引用次数: 1

Abstract

Abstract The study of microstructure formation in polymer-cement concrete provides opportunities to exploit synergetic actions between cement and polymer, leading to performance improvement and to a wide range of new and innovative properties and applications. Polymers can reduce the impact of construction industry on environment, by decreasing the carbon footprint of cement and concrete production. Renovation and restoration, largely figuring in the concept of sustainable construction development, thank their growing share in construction activity to the input of polymers in repair and binder materials and in rehabilitation procedures. The study of ancient binders and mortars reveals aspects of the origins of the observed long lasting durability of those ancient mortars. It also reveals the interaction mechanisms between carbonation of air hardening components and hydration of hydraulic components, which in turn helps to develop chemical activation methods (i.e. alkaline activation) to improve the hydraulic properties of pozzolans and industrial residues to develop inorganic polymers (i.e. geopolymers) for eventually full replacement of cement in binders.

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结合矿物和聚合物粘结材料科学在建筑和修复中的可持续性

聚合物水泥混凝土中微观结构形成的研究为开发水泥和聚合物之间的协同作用提供了机会，从而改善性能并获得广泛的新特性和应用。聚合物可以通过减少水泥和混凝土生产的碳足迹来减少建筑行业对环境的影响。翻修和修复主要是可持续建筑发展概念的一部分，它们在建筑活动中所占的份额越来越大，这要归功于修复和粘结材料以及修复程序中聚合物的投入。对古代粘合剂和迫击炮的研究揭示了这些古代迫击炮持久耐用性的起源。研究还揭示了空气硬化组分的碳酸化与水力组分的水化之间的相互作用机制，从而有助于开发化学活化方法(即碱性活化)来改善火山灰和工业残留物的水力性能，从而开发无机聚合物(即地聚合物)，最终完全取代粘合剂中的水泥。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Restoration of Buildings and Monuments

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