Fabrication of Silane and Desulfurization Ash Composite Modified Polyurethane and Its Interfacial Binding Mechanism

Polyurethane/desulfurization ash(PU/DA)composites were synthesized using"one-pot method",with the incorporation of a silane coupling agent(KH550)as a"molecular bridge"to facilitate the integration of DA as hard segments into the PU molecular chain.The effects of DA content(φ)on the mechanical properties,thermal stability,and hydrophobicity of PU,both before and after the addition of KH550,were thoroughly examined.The results of microscopic mechanism analysis confirmed that KH550 chemically modified the surface of DA,facilitating its incorporation into the polyurethane molecular chain,thereby significantly enhancing the compatibility and dispersion of DA within the PU matrix.When the mass fraction of modified DA(MDA)reached 12%,the mechanical properties,thermal stability,and hydrophobicity of the composites were substantially improved,with the tensile strength reaching 14.9 MPa,and the contact angle measuring 100.6°.

Liming Characteristics of a High-Calcium Dry Flue Gas Desulfurization By-Product and a Class-C Fly Ash

Due to coal’s availability and low cost, coal combustion continues to be the United States’ primary energy source. However, coal combustion produces large quantities of waste material. Some coal combustion by-products (CCBs) have chemical and physical characteristics that make them potentially useful as soil amendments. The objectives of this study were to characterize a relatively new, high-calcium dry flue gas desulfurization (DFGD) by-product and compare its agronomic liming potential to a Class-C fly ash (FA) and reagent-grade calcium carbonate (CaCO3). Calcium car-bonate equivalence (CCE), degree of fineness (DOF), and effective neutralizing value (ENV) for each CCB were determined using standard methods. The CCBs and CaCO3 were also incubated with an acidic (~4.5) clay sub-soil at application rates equiva-lent to 0, 0.5, 1, and 2 times the soil’s lime requirement and compared to an una-mended control. Soil pH was then measured periodically during a 40-day incubation. The ENV of 79.4% for the DFGD by-product and 57.3% for the FA were comparable to those of commercially available liming materials, but were significantly lower (P < 0.05) than that of reagent-grade CaCO3. After 40 days of incubation at the 0.5× ap-plication rate, both CCBs raised the pH of the clay soil to only 5.0, while the CaCO3 raised the pH to 6.5. After 40 days at the 1× rate, all three materials had raised the soil pH to between 6.5 and 7.0, although the FA increased the soil pH more slowly than did the other two materials. At the 2× rate, both CCBs increased the soil pH to between 7.5 and 8.0, while the CaCO3 increased the soil pH to only 7.0. Both CCBs appear to be useful as soil liming materials, although care should be taken to avoid over-application, as this may make the soil too alkaline for optimum plant growth.

Research on physical and chemical properties and soundness of dry desulphurized fly ash used as a construction material

The physical and chemical properties and soundness of Baosteel Power Plant＇ s dry desulphurized fly ash were systematically investigated and compared with those of the similar byproducts produced by some other domestic power plants. The feasibility of these byproducts used as a construction material was also analyzed. The results show that Baosteel＇s dry desulphurized fly ash is a kind of ash with high calcium and high sulfur contents, which has the characteristics of volcanic ash activity. It contains sulfate and sulfite, and is easy to cause sulfate activation. It has higher activity compared with common fly ash. But higher calcium sulfite and free-CaO contents in ash will bring about soundness concerns to users. Therefore, quality tests and volume control will be necessary when fly ash is used as a construction material.

Geldart C类脱硫灰颗粒在环流耦合提升管内稳定流动特性

我国CO_(2)的排放中70%来自工业领域,故工业过程的碳捕集对实现“双碳目标”十分关键。工业烟气中往往含有的硫氧化物会腐蚀设备并使后续脱碳等过程使用的催化剂中毒。因此,工业烟气的深度脱硫技术对后续的CO_(2)捕集或提纯过程至关重要。循环流化床半干法烟气脱硫因具有脱硫效率高、无污染、停留时间可控等优点受到广泛关注。循环流化床脱硫工艺中作为脱硫剂的脱硫灰颗粒为典型Geldart C类颗粒。由于C类颗粒的强黏附性,其在循环流化床操作中容易结块,从而影响装置稳定运行。为了强化脱硫灰颗粒在循环流化床内的流动稳定性,提出了环流强化的耦合提升管反应器的概念,并自行设计搭建了一套导流筒内径100 mm、高度300 mm,外筒内径160 mm、高度760 mm,输送段内径75 mm、总高度12.6 m的环流耦合提升管。在U_(g)=4 m/s、G_(s)=45 kg/(m^(2)·s),U_(g)=7 m/s、G_(s)=25 kg/(m^(2)·s)的操作条件下,考察了环流段的压力分布、标准差以及功率谱密度。当环隙区气速为0.4 m/s时,环流流动能够实现稳定、连续的密相环流流动。在C类颗粒形成稳定流动基础上,讨论了环流耦合提升管内的流动特性分布规律,包括固含率和颗粒速度。实验发现,环流流动的设计可以强化C类颗粒的流动特性,大幅提高耦合反应器内C类颗粒脱硫灰固含率,并实现了C类颗粒循环流态化装置的稳定运行。同时,这些研究结果可以为C类颗粒新型循环流态化反应器设计提供参考。

铁尾矿基多固废混凝土抗压性能及微观结构分析

针对铁尾矿堆存困难、综合利用率低和活性低的问题,以铁尾矿钢渣脱硫灰为复合掺合料制备多固废混凝土。通过抗压性能测试,研究复合掺合料掺量、铁尾矿细度对混凝土抗压强度的影响,并利用压汞法(MIP)和背散射电子成像技术(BSE)探究混凝土的微观结构。结果表明:复合掺合料的掺入对混凝土早期抗压强度影响较大,掺量小于20%的混凝土28 d抗压强度与无掺合料组抗压强度基本持平,30%掺量的混凝土抗压强度随铁尾矿比表面积的增大而先增大后减小;掺入复合掺合料和减小铁尾矿细度能够改善混凝土孔结构和提高界面过渡区的密实度。

粉煤灰基地聚合物的制备及其性能研究

以低钙粉煤灰为硅铝原料制备了地聚合物胶凝材料,研究了激发剂种类和掺量对地聚合物抗压强度的影响,以及产物对Cr^(3+)和Pb^(2+)固化效果。结果表明:当水玻璃掺量为15%,脱硫石膏掺量为7%时,所制得地聚合物抗压强度最高,3 d、 7 d、28 d龄期抗压强度分别为19.8 MPa、32.5 MPa和53.5 MPa;地聚合物对重金属离子Cr^(3+)和Pb^(2+)的固化效果均较好,其在去离子水和硫酸硝酸混合酸液中的浸出量均远低于国标限值。

无机胶凝材料改性脱硫建筑石膏性能研究

循环流化床(CFB)灰渣具有良好的火山灰性,以脱硫建筑石膏为主要胶凝材料,电石渣为碱激发剂,CFB灰渣和粉煤灰为矿物掺和料,研究CFB灰渣对脱硫建筑石膏流动度、凝结时间、抗压强度、膨胀率等性能的影响规律,并借助X射线衍射(XRD)、扫描电子显微镜(SEM)等手段分析其水化产物和微观形貌。结果表明,掺入CFB灰渣可以有效提高脱硫建筑石膏的力学性能和耐水性能,但对工作性能和膨胀性能有负面影响。经20%(质量分数)CFB飞灰、5%(质量分数)电石渣复合改性后,脱硫建筑石膏的1、28 d绝干抗压强度分别为20.53、22.37 MPa,较脱硫建筑石膏基样分别增加了28.6%、35.9%。CFB灰渣水化生成的水化硅酸钙(C-S-H)凝胶和钙矾石(AFt)包裹并填充于二水石膏晶体表面及空隙中,使硬化体内部结构更加密实,从而提高了脱硫建筑石膏的力学性能和耐水性能。

脱硫石膏与粉煤灰配施对碱化土壤改良及苜蓿生长的影响

【目的】筛选适宜新垦龟裂碱化土壤改良和苜蓿生长的脱硫石膏和粉煤灰配比。【方法】采用小区试验,试验设置CK(脱硫石膏0、粉煤灰0)、T1(脱硫石膏30 t/hm^(2)、粉煤灰15 t/hm^(2))、T2(脱硫石膏30 t/hm^(2)、粉煤灰30 t/hm^(2))、T3(脱硫石膏30 t/hm^(2)、粉煤灰45 t/hm^(2))、T4(脱硫石膏45 t/hm^(2)、粉煤灰15 t/hm^(2))、T5(脱硫石膏45 t/hm^(2)、粉煤灰30 t/hm^(2))、T6(脱硫石膏45 t/hm^(2)、粉煤灰45 t/hm^(2))共7个处理,研究脱硫石膏和粉煤灰配施对土壤pH值、碱化度和可溶性盐量及苜蓿生长影响。【结果】脱硫石膏和粉煤灰配施显著改善龟裂碱化土壤物理性质,与CK相比,T3处理土壤体积质量降低7.69%,土壤孔隙度和田间持水率分别提高9.69%和18.70%;脱硫石膏和粉煤灰配施对0~40 cm土层土壤化学性质改良效果较好,T4处理0~10、10~20 cm土层土壤pH值分别降低10.51%、11.66%,碱化度分别降低56.76%和50.27%;T4处理0~10、10~20、20~40 cm土层土壤可溶性盐量分别下降32.33%、52.55%、3.04%;T4、T1处理苜蓿增产效果较好,与CK相比,苜蓿鲜质量分别提高61.76%、43.21%,干物质量分别提高48.80%、30.72%;但脱硫石膏和粉煤灰配施量过大则会造成减产,T6处理苜蓿鲜质量和干物质量分别较CK降低19.69%、10.24%。【结论】脱硫石膏和粉煤灰配合施用能有效降低龟裂碱化土壤的体积质量、pH值、碱化度和可溶性盐量,提高土壤孔隙度、田间持水率,从而有利于苜蓿的生长和发育,其中45 t/hm^(2)脱硫石膏与15 t/hm^(2)粉煤灰为最优配比组合。

低氧燃烧对炉内石灰脱硫过程影响的实验研究

为了探究流化床锅炉低氧燃烧对炉内石灰脱硫过程的影响,在小型鼓泡流化床实验装置上开展了不同过量空气系数(0.6~1.2)下炉内石灰脱硫实验研究。通过炉内烟气组分变化特性、脱硫灰渣含硫量变化特性和脱硫石灰产物特性的研究,揭示了不同过量空气系数下炉内石灰脱硫特性。实验结果表明:当空气过量系数大于1.0时,含硫烟气主要是SO_(2),灰渣中的硫主要以硫酸盐形式存在,过量空气系数的降低对石灰固硫影响较小。当工况转变为缺氧燃烧时,烟气中的硫主要以H_2S形式存在,灰渣中的硫化物硫的含量最高,有机硫和硫酸盐硫次之,石灰中含硫产物大幅下降。从脱硫剂的利用率上考虑,建议低氧燃烧时空气过量系数宜控制1.0以上但尽可能低。

基于沸腾炉焙烧脱硫灰的复合催化热分解效应

为解决烧结烟气脱硫灰中主要成分亚硫酸钙不稳定等问题,本文利用沸腾炉对脱硫灰的催化分解效应进行了研究,其中,催化剂为硫化亚铁和硫酸亚铁配成的复合催化剂。通过对脱硫灰的催化分解过程进行热重分析,同时探讨复合催化剂配比、保温时间、反应温度、气体流量等因素对沸腾炉中脱硫灰的脱硫率及焙烧产物的影响。热重结果表明,添加复合催化剂后脱硫灰分解温度降低了100℃左右。沸腾炉试验表明,当反应温度为900℃,气体流量为3000 mL/min,复合催化剂配比为2.5∶1,保温时间为30 min时,脱硫率可达91.41%。脱硫灰催化分解生成的SO_(2)可为后续制造硫酸提供原料,焙烧产物可以作为烧结厂的原料,有效地解决了脱硫灰对环境的污染。

电厂燃煤飞灰固化脱硫污泥重金属铅特性研究

【目的】燃煤电厂脱硫污泥中重金属富集显著,降低脱硫污泥中重金属含量十分必要。【方法】提出利用电厂飞灰固化脱硫污泥重金属的思路,并和常见固化剂开展对比。【结果】以铅为对象,在水泥、飞灰、螯合剂二硫代氨基甲酸酯(dithiocarbamate,DTC)和螯合剂三聚硫氰酸三钠盐(TMT-15)中,飞灰对脱硫污泥中铅固化效果最好;不同飞灰及脱硫污泥固化效率在40%~100%。机理分析表明,类似于水泥,飞灰化学成分主要含有SiO2、Al2O3、CaO、Fe2O3等,可与脱硫污泥发生水化反应等,生成对重金属固化稳定有利的水化硅酸钙C-S-H等水化产物及钙矾石等物质,同时生成物对重金属铅等具有吸附作用。【结论】在燃煤电厂脱硫污泥中掺入一定比例的飞灰可以实现铅的固化稳定,为脱硫污泥从危险固废降低为一般固废提供了方法。

含钙镁煤基固废CO_(2)矿化封存及其产物性能研究进展

随着化石碳资源的过度消耗,导致CO_(2)等温室气体的大量排放,全球气候变化已经成为全人类面对的重大挑战之一,同时,煤炭资源开发利用过程中会产生大量的粉煤灰、脱硫石膏等含钙镁煤基固废。如何实现CO_(2)高效捕集与封存是当下面临的极具挑战性课题,粉煤灰、煤气化灰渣等大宗重污染工业固废的大规模综合利用仍亟待突破。在“双碳”目标下,利用煤基固废矿化封存CO_(2)是一项具有巨大潜力的高效应对全球变暖的策略,利用含钙镁煤基固废进行矿物碳酸化对于二氧化碳捕集与封存(CCS)以及固废的资源化处置都具有很大前景。然而,它的工业应用瓶颈依旧无法突破。综述了以典型煤基固废粉煤灰(FA)、脱硫石膏(FGDG)以及煤气化灰渣(CGS)为原料的CO_(2)矿化技术的发展现状,旨在探讨其技术局限性的原因。首先,简要阐述了煤基固废CO_(2)矿化的途径,揭示了煤基固废CO_(2)矿化反应过程和原理。其次,重点讨论了典型煤基固废的矿化潜力和工艺,明晰CO_(2)矿化过程中工艺参数对产物性能的调控机理。最后,总结了煤基固废CO_(2)矿化产物的性能并且利用全生命周期评估(Life Cycle Assessment,LCA)阐明矿化工艺的可行性及其对环境的影响。研究将对煤基固废CO_(2)矿化的工艺技术提供优化建议,以期推动煤炭工业的低碳转型战略目标。

脱硫粉煤灰掺量对蒸压加气混凝土稳定性影响及其机理

随着环保要求的提高和资源循环利用的推广,脱硫粉煤灰作为一种煤电化副产品,在改善蒸压加气混凝土(AAC)的性能方面具有潜在的应用价值。为了深入研究脱硫粉煤灰掺量对AAC稳定性的影响及其机理,开展了以不同比例的脱硫粉煤灰替代普通粉煤灰的稳定性实验,通过对六组不同掺量试件的稠度、干密度进行测试,并分析了其对AAC试件抗压强度的影响趋势,结合ACC水化过程,探讨了脱硫粉煤灰从微观到宏观对AAC的结构和性能的影响,阐明了脱硫粉煤灰对蒸压加气混凝土稳定性影响机理。研究结果表明,在脱硫粉煤灰的初始掺入阶段,由于其作为微细填料的功能,以及促进水化反应的作用,显著提高了AAC的干密度和初期抗压强度,在脱硫粉煤灰掺量为30%时,AAC试件强度达到阈值。然而脱硫粉煤灰掺量对AAC具有双向作用,过多的脱硫粉煤灰导致气孔增多及活性降低,进而影响试件的长期稳定性。本文研究成果对于ACC工艺的优化具有较大参考价值,为脱硫粉煤灰在蒸压加气混凝土领域的运用提供了理论依据和数据支撑。

基于RSM的工业副产品改性硫铝酸钙水泥性能分析

为研究工业副产品烟气脱硫石膏(FGDG)、粉煤灰(FA)和石灰石(LS)对硫铝酸盐水泥(SAC)熟料无侧限抗压强度(UCS)和pH的影响规律,采用FGDG,FA和LS改性SAC熟料,并在7 d和28 d龄期进行UCS和pH测试.采用响应面方法(RSM),建立UCS和pH的回归模型,分析各因素交互对其影响.研究结果表明:UCS和pH均受到FGDG,FA和LS单因素和各因素交互作用影响.FGDG和LS,LS和FA的交互作用对浆体7 d和28 d的UCS影响显著,LS和FA,FGDG和FA的交互作用对浆体pH 7 d影响显著,但对浆体pH 28 d影响并不显著.利用RSM-BBD多目标优化法进行优化各工业副产品,建立的回归模型具有较高的可信度和精确度,得到改性硫铝酸钙水泥满足高UCS低pH时各工业副产品的合适添加比,其试验值和预测值误差较小.

钙基脱硫灰在石灰石-石膏湿法脱硫系统中的应用

钙基脱硫灰的资源化利用一直是行业应用难题。本文为验证钙基脱硫灰替代石灰石-石膏湿法脱硫系统原用脱硫剂(石灰石粉)的脱硫效果,进行在混合脱硫剂中添加不同比例钙基脱硫灰的实验室和工业应用试验,分析脱硫效率、SO_(2)排放质量浓度、吸收塔浆液和石膏的化学成分、脱硫污泥量等主要工艺参数的变化情况,并对钙基脱硫灰添加前、后湿法脱硫系统的生产运行方式变化进行对比分析。结果表明:当钙基脱硫灰替代占比在50%以下时,吸收塔浆液的化学成分基本没有发生变化,系统脱硫效率均在95%以上;SO_(2)排放质量浓度均在10 mg/Nm 3以下,小于35 mg/Nm^(3)的国家排放标准,满足行业超低排放要求;石膏的化学成分基本没有发生变化,满足石膏的社会化应用标准;污泥产生量没有增加,吸收塔内的Cl-浓度有所上升但可通过增大废水排放量来解决;湿法脱硫系统的操作调整变化不大,运行成本没有明显增加。采用钙基脱硫灰替代石灰石粉可为干法、半干法脱硫灰的综合利用提供一种经济、环保的有效途径。

半干法脱硫灰膏体制备流态填筑材料及其机制

针对填埋到湖底的脱硫灰含水量较高,脱水干燥后再利用可行性差的问题,本文直接利用填埋半干法脱硫灰膏体制备全固废流态填筑料。研究“半干法脱硫灰-钢渣微粉-粉煤灰”全固废胶凝材料,考察原料配比对抗压强度的影响,通过XRD、FT-IR、SEM等分析手段研究胶凝机制,考察流态填筑料强度的影响因素。结果表明:原料最佳配比为脱硫灰∶粉煤灰∶钢渣微粉=40∶20∶40,28 d抗压强度可以达到13.37 MPa;复合胶凝材料水化产物除常规的水化硅酸钙(C-S-H)凝胶和钙矾石外,还存在少量的C_(3)A-CaSO_(3)-11H_(2)O,其由脱硫灰中的CaSO_(3)·0.5H_(2)O和体系中的水化铝酸钙(C-A-H)反应生成;当固化剂掺量为8%~20%时,所制备的流态填筑料28 d抗压强度为1.18~2.47 MPa;三乙醇胺可以增加流态填筑料各龄期的抗压强度,最佳用量为固化剂质量的0.04%。

钢铁含铊高盐固废/废水协同水洗技术研究

钢铁烧结工序会产生大量烧结机头灰和脱硫废水,盐含量高,且含有剧毒重金属铊,其消纳问题成为制约钢铁行业可持续发展的关键问题之一。提出含铊高盐固废与高盐废水协同处置的思路。结果表明,当利用1/4浓度活性炭法脱硫废水用于洗灰时,洗灰水中铊含量低于5 mg/L,且钙、镁的溶出量也有所降低。重点研究了活性炭法脱硫废水中各组分对烧结机头灰水洗过程铊溶出行为的影响,发现水洗过程SO_(3)^(2-)的存在及适宜的pH对铊的溶出有明显抑制作用。

对改性飞灰烟道循环喷射脱硫脱NH_(3)的研究

本文设计了飞灰循环改性系统及烟道喷射系统,由喷射装置将其均匀喷入烟道中,使改性飞灰与烟气中的酸性气体或碱性气体发生反应,避免对后续除尘器等设备的腐蚀。实验表明,改性飞灰对烟气中的NH_(3)、SO_(2)有很好的吸附效果。

Resource utilization of flue gas calcium-based desulfurization ash:a comprehensive review

Calcium-based desulfurization ash(CDA)is mainly produced in dry and semi-dry flue gas desulfurization processes.The property of CDA is extremely unstable because its main component,calcium sulfite,makes it difficult to be directly applied to the field of building materials.The modification of desulfurization ash can be realized by high-temperature oxidation and wet oxidation.After modification,CDA can be widely used in building materials.Hydrothermal oxidation has broad development prospects because it can complete the oxidation of CDA and the removal of impurity elements at the same time.CDA can be used to prepare high value-added products of calcium sulfate whiskers and ecological rubber fillers.

Low-temperature oxidation behavior and mechanism of semi-dry desulfurization ash from iron ore sintering flue gas

The low-temperature wet oxidation behavior of semi-dry desulfurization ash from iron ore sintering flue gas in ammonium citrate solution was investigated for efficiently utilizing the low-quality desulfurization ash. The effects of the ammonium citrate concentration, oxidation temperature, solid/liquid ratio, and oxidation time on the wet oxidation behavior of desulfurization ash were studied. Simultaneously, the oxidation mechanism of desulfurization ash was revealed by means of X-ray diffraction, Zeta electric resistance, and X-ray photoelectron spectroscopy (XPS) analysis. Under the optimal conditions with ammonium citrate, the oxidation ratio of CaSO_(3) was up to the maximum value (98.49%), while that of CaSO_(3) was only 8.92% without ammonium citrate. Zeta electric resistance and XPS results indicate that the dissolution process of CaSO_(3) could be significantly promoted by complexation derived from the ammonium citrate hydrolysis. As a result, the oxidation process of CaSO_(3) was transformed from particle oxidation to SO_(3)^(2−) ion oxidation, realizing the rapid transformation of desulfurization ash from CaSO_(3) to CaSO_(4) at low temperature. It provides a reference for the application of semi-dry desulfurization ash and contributes to sustainable management for semi-dry desulfurization ash.