钢渣和高炉渣微粉做水泥和混凝土掺和料的研究

研究了马钢高炉渣、转炉磁选后尾渣 (以下简称尾渣 )、转炉风碎渣易磨性以及这些渣制成的微粉活性、安定性、流动性等 ,并探讨了复合微粉掺量对混凝土强度的影响 ,为钢渣和高炉渣在水泥。

炉渣微粉掺合料对胶凝材料性能的影响研究

工业固体废弃物在一定程度上属于可以重新利用的资源,混凝土矿物掺合料大部分是用工业固体废弃物进行加工磨细制成的,可以改善混凝土性能,替代部分水泥,降低成本。用燃煤电厂的炉渣加工成炉渣微粉掺合料,通过试验研究它对胶凝材料性能的影响规律;结果表明,炉渣微粉虽然具有一定的活性,但需水性和吸附性都比较大;替代部分水泥单独掺入使用时,使胶凝材料的强度降低、标准稠度需水量比增大、流动性以及与外加剂相容性变差,并且这些性能变化的幅度随着掺量的增加而增大,所以在混凝土生产中,掺合料不宜单选炉渣微粉使用;采用双掺技术,在炉渣微粉掺量不超过10%条件下,可与活性高、与外加剂相容性好的矿渣微粉掺合料同时使用,不仅能改善胶凝材料的性能,而且能够带来一定的经济效益和社会效益。

宝钢高炉渣微粉生产工艺及在砼中应用

介绍了高炉渣微粉在国内外的研究应用及绿色高性能混凝土发展的意义 ,分析了高炉渣粉磨技术、工艺 ,并研究了高炉渣微粉的性能及应用 。

环保型高效胶结材——高炉渣微粉的制造与应用

本文介绍了高炉渣微粉的性质、特点、生产工艺及粉磨设备的选择和应用前景分析。

改性转炉渣微粉替代膨润土的试验研究

转炉微粉具有一定的水硬活性,为充分利用转炉微粉特有的胶凝性,开发转炉微粉替代球团用膨润土的可行性研究,完成了转炉渣微粉替代膨润土的研究。

高炉渣微粉生产工艺技术

高炉渣利用超细粉磨技术处理以后,可以制成高炉渣微粉,是一种可持续发展的环保型高效胶结材。一方面销纳了工业固体废弃物,改善了城市环境,另一方面又对建材工业水泥性能的提高有很大的帮助,产生了良好的经济效益,达到无害化、减量化、资源化的目的,市场前景广阔。

垃圾焚烧炉渣再生微粉稳定碎石强度特性研究

为高效再生利用垃圾焚烧炉渣,采用垃圾焚烧炉渣再生微粉(WISRP)部分替代水泥,进行了不同水泥、再生微粉掺量稳定碎石的无侧限抗压强度试验和劈裂强度试验。结果表明:在同样水泥用量时,掺入少量再生微粉可显著提高稳定碎石的强度;在同样胶凝材料用量时,随WISRP替代水泥比例的增加,强度均先缓慢后大幅度降低;WISRP部分替代水泥对稳定碎石早期强度影响较小,对长期强度影响相对较大,对劈裂强度的影响远大于对抗压强度的影响。研究成果说明:利用WISRP按照合理的比例替代水泥稳定碎石是可行的。

高炉渣和转炉渣粉磨能耗和微粉特性研究

采用相对易磨性的方法比较了水淬高炉渣、滚筒转炉渣和风碎转炉渣的粉磨能耗。采用粒度分布和分形方法研究了炉渣微粉的特性。研究结果表明:水淬高炉渣易磨性最好,而滚筒转炉渣易磨性最差。水淬高炉渣微粉整体粒径分布均匀,不同粒度范围内微粉特性差异较小。而转炉渣中存在明显的难磨相,不同粒度范围内的分形分维数有明显差异。当炉渣微粉磨至很细时,单位质量滚筒转炉渣和风碎转炉渣的能耗分别约是水淬高炉渣的3.19和2.17倍。转炉渣中存在的FeO和金属铁导致其相对水淬高炉渣更难磨。滚筒转炉渣中的大量MgO.2FeO相导致其比风碎转炉渣更难磨。

粒构分布对钢渣基生态活性炭降解甲醛性能的变异系数-灰色关联综合分析

为了利用钢渣、核桃壳制备的具有高效降解甲醛性能的钢渣基生态活性炭,分别对电炉渣微粉的粒径分布、钢渣基生态活性炭的孔结构进行了测试,结果表明:钢渣粒径分布与钢渣基生态活性炭降解甲醛性能的综合关联度排序为(d_(90)-d_(10))/d_(50)>d_(90)/d_(10)>d_(10)>d_(90)>d_(50),说明随着电炉渣微粉粉磨时间的延长,电炉渣微粉的粒径显著减小且粒度分布均匀程度得到改善,有利于增大电炉渣微粉、活性炭与甲醛的降解作用面积;钢渣基生态活性炭孔结构与钢渣基生态活性炭降解甲醛性能的综合关联度排序为平均孔径>孔容积>比表面积,说明孔容积与比表面积即使降低也不会使钢渣基生态活性炭降解甲醛性能下降,适量的电炉渣微粉可以抵消由于孔容积与比表面积降低而导致的钢渣基生态活性炭吸附降解甲醛作用下降的影响。

日本钢铁渣处理和应用新发展

本文介绍了处理液态高炉渣的风淬工艺流程及其关键技术,这是有代表性的日本钢铁渣处理新方法。电炉铁合金渣的风淬处理在日本也已获得成功。钢铁渣应用新发展的趋势是充分利用经过处理的钢铁渣的特性,如日本开发的“微粉高炉渣”等新渣料,为钢铁渣有效利用开辟了新途径。

Sulfuric Acid Resistance of Concrete with Blast Furnace Slag Fine Aggregate

The deterioration of concrete by sulfuric acid attack in sewage environments has become a serious problem for many existing sewage structures. In this study, the properties of concrete using the blast furnace slag have been examined. It was shown that by using the blast furnace slag fine aggregate and blast furnace slag fine powder, it is possible to enhance the resistance of mortar and concrete to sulfuric acid. The resistance to sulfuric acid of mortar and concrete can be improved by using a blast-furnace slag fine aggregate in the total amount of fine aggregate. When mortar or concrete reacts to sulfuric acid, dihydrated gypsum film is formed around the particulate of the fine aggregate. This dihydrated gypsum film could retard the penetration of sulfuric acid, thus, improving the resistance to sulfuric acid. Furthermore, it has been proved that the relationship between the erosion depth by sulfuric acid attack and the product of immersion period and concentration of sulfuric acid can be expressed linearly. However, this relationship is dependent on the type of materials of concrete.

利用高炉熔渣处理不锈钢酸洗污泥

不锈钢酸洗污泥是在不锈钢生产过程中对不锈钢进行酸洗与钝化处理产生的副产物,属于危险废物。提出了利用高温高炉熔渣处理不锈钢酸洗污泥的技术思路,有望实现不锈钢酸洗污泥的资源化利用。采用半球法测定不同配比酸洗污泥加入高炉渣中的熔点,结合FactSage绘制相图分析熔点变化的原因,并将制备的高炉渣微粉与425硅酸盐水泥按照一定比例掺混制备胶砂砌块。结果表明,熔渣熔点随着污泥配比增加而升高。随着不锈钢酸洗污泥配比的增加,熔渣CaO含量减少,导致熔渣熔点升高。不锈钢酸洗污泥中CaSO_4等无机盐对高炉渣微粉制备过程起到了无机助磨作用。当不锈钢酸洗污泥掺加比例由0提高至5%时,高炉渣微粉的比表面积从379.70 m^(2)/kg提高至415.28 m^(2)/kg,胶砂砌块的7 d活性指数从79.45%提高至89.94%,28 d活性指数从94.64%提高至99.96%,均达到了S95矿渣微粉的要求。最后,以容积为1 680 m~3的高炉为例,提出了利用高炉熔渣处理不锈钢酸洗污泥工业应用的初步设计,并进行了热量平衡计算。在考虑热损失和保证高炉渣不发生结壳现象的条件下,高炉熔渣富余的热量可以处理11.28%的不锈钢酸洗污泥,这为不锈钢酸洗污泥的工业应用提供了技术指导。

深部破碎厚矿床盘区机械化小分段充填法开采应用研究

针对锡铁山铅锌矿深部破碎厚矿床上向水平充填法开采中遇到的采场顶板冒落风险大、充填成本高、生产能力小等问题,提出了安全、高效的盘区机械化小分段充填法。采用FLAC3D软件对小分段采场结构参数及其分段平巷支护方案进行模拟对比分析,得出小分段充填法采场高度取10 m、宽度取8~10 m为宜,分段平巷采用树脂锚杆+钢筋网+喷砼支护方案可有效控制巷道变形。利用炉渣微粉+水泥熟料(配比为3∶1)替代水泥作胶凝材料可降低充填成本15%。现场试验表明,小分段充填法采场爆破参数排距为1.4 m、孔底距为1.6~2.0 m时矿石爆破效果最佳,试验盘区生产能力达到了1000 t/d,生产效率提高了100%。

Effects of Al_2O_3 nanoparticles on properties of self compacting concrete with ground granulated blast furnace slag (GGBFS) as binder

In this work, strength assessments and percentage of water absorption of self compacting concrete containing ground granulated blast furnace slag （GGBFS） and A1203 nanoparticles as binder have been investigated. Portland cement was replaced by different amounts of GGBFS and the properties of concrete specimens were investigated. Although it negatively impacts the physical and mechanical properties of concrete at early ages of curing, GGBFS was found to improve the physical and mechanical properties of concrete up to 45 wt% at later ages. A1203 nanoparticles with the average particle size of 15 nm were added partially to concrete with the optimum content of GGBFS and physical and mechanical properties of the specimens were measured. A1203 nanoparticle as a partial replacement of cement up to 3.0 wt% could accelerate C-S-H gel formation as a result of increased crystalline Ca（OH）2 amount at the early ages and hence increase strength and improve the resistance to water permeability of concrete specimens. The increase of the A1203 nanoparticles＇ content by more than 3.0 wt% would cause the reduction of the strength because of the decreased crystalline Ca（OH）2 content required for C-S-H gel formation. Several empirical relationships have been presented to predict flexural and split tensile strength of the specimens by means of the corresponding compressive strength at a certain age of curing. Accelerated peak appearance in conduction calorimetry tests, more weight loss in thermogravimetric analysis and more rapid appearance of the peaks related to hydrated products in X-ray diffraction results, all indicate that A1203 nanoparticles could improve mechanical and physical properties of the concrete specimens.