CO2-activated belite cements synthesized from industry wastes and the carbonation bond mechanism

工业废料合成CO2活化贝利特水泥及其碳化键机理

• 批准号: 194243-2011
• 负责人: Shao, Yixin
• 金额: $ 1.38万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=569755
• 关键词: CO2; activated; belite; cements; synthesized

Production of Portland cement is an energy intensive process. Its high early strength is dependent on high percentage of tricalcium silicate (C3S) which is formed at a temperature of 1500 oC. Dicalcium silicate (C2S) based belite cement can be made with 20% less energy and can have a better long term performance. The main problem with belite cement is that C2S hydrates much more slowly than C3S even with dopants. On the other hand, all C2S polymorphs can be activated by carbon dioxide to produce equivalent high early strength as C3S. The unique characteristic of C2S suggests an innovative way of using belite cement: carbon dioxide activation for early strength and subsequent hydration for long term performance. This proposed research is to develop special belite cements in line with the attempt to reduce energy consumption and produce fast early strength. Since early strength is dependent on carbonation, rather on hydration, calcium-rich and silica-rich industry wastes can be utilized as exclusive raw materials for belite cement. CO2 activation is a carbon uptake process. If CO2 activated hardening can sequester carbon dioxide recovered from synthesis process due to the use of fuel, the production is possible to reach a state of zero-emission. The concrete so produced will have more resistance to atmospheric carbonation, ion penetration, sulphate attack and freeze-thaw cycling. Research will investigate both high temperature and hydrothermal synthetic processes to manufacture belite cement with two industry wastes: ladle slag from steel production and fly ash from thermal power plant. Belite clinkers will be characterized by phase analysis and their cements will be examined for carbonation and hydration reactions. Belite concrete will be tested for its strength, durability and carbon sequestration capacity. To enhance the understanding of the carbonation bond mechanism in CO2 activated belite cement and promote commercial applications, a comprehensive microanalysis of carbonation induced microstructure will be performed. Because of the accelerated curing by CO2 activation, the system is best suited to precast concrete products such as blocks, panels, pipes and slabs. The unique cementing system, first of its kind, offers tremendous benefits.

硅酸盐水泥的生产是一个能源密集型的过程。它的高早期强度依赖于在1500℃下形成的高百分比的硅酸三钙（C3S）。硅酸二钙（C2S）基白石水泥能耗降低20%，且具有较好的长期使用性能。白石水泥的主要问题是，即使有掺杂剂，C2S的水化速度也比C3S慢得多。另一方面，所有C2S多晶型均可被二氧化碳活化，产生与C3S相当的高早强。C2S的独特特性提出了一种使用白石水泥的创新方法：二氧化碳活化获得早期强度，随后水化获得长期性能。本文提出的研究方向是开发特殊的白石胶结物，以达到降低能耗和快速产生早期强度的目的。由于早期强度依赖于碳化作用，而不是水化作用，因此富钙和富硅的工业废料可以作为白石水泥的专用原料。二氧化碳活化是一个碳吸收过程。如果CO2活化硬化能够将合成过程中由于燃料的使用而回收的二氧化碳封存起来，生产就有可能达到零排放的状态。这样生产的混凝土将具有更强的抗大气碳化、离子渗透、硫酸盐侵蚀和冻融循环的能力。研究将研究高温和水热合成工艺，利用两种工业废物：钢铁生产的钢包渣和火力发电厂的飞灰来制造白石水泥。白石熟料将通过物相分析进行表征，其水泥将进行碳酸化和水化反应的检查。Belite混凝土将测试其强度、耐久性和固碳能力。为了加深对CO2活化白石水泥中碳化结合机理的认识，促进其商业应用，本文将对碳化诱导的微观结构进行全面的微观分析。由于二氧化碳活化加速固化，该系统最适合于预制混凝土产品，如砌块、面板、管道和板。独特的固井系统，首创的，提供了巨大的好处。