昌吉州燃煤电厂粉煤灰物化性质及其综合利用分析

新疆昌吉州粉煤灰量逐年递增给当地造成了严重的环境污染,同时企业无法对其回收利用造成了较大的资源浪费。通过对新疆昌吉州十二家燃煤电厂粉煤灰进行物理化学分析,发现主要组成为二氧化硅,其含量平均为47.43%;三氧化铝、三氧化铁含量平均为17.98%、7.16%。为了提高粉煤灰的综合利用率,结合此次分析结果及粉煤灰资源化利用现状,对昌吉州粉煤灰在建筑行业、农业、化学工业、冶金工业、环境保护业的高附加值利用方面提出了利用对策。     

粉煤灰综合利用的研究进展

从粉煤灰的来源入手,介绍了粉煤灰的化学组成和物质组成,对粉煤灰在污水处理、建材领域和材料学领域等方面的应用机理及国内的应用现状进行了概述,并对粉煤灰的应用进行了展望,用粉煤灰制作的绿色建材和建筑工程,粉煤灰填充材料发展的聚合物复合材料等方面必会有光明的前景.     

大庆石油管理局粉煤灰综合利用现状及前景

简要介绍了目前国内外粉煤灰利用的情况,分析了大庆石油管理局粉煤灰利用范围,主要包括筑路、生产水泥、加工切块、陶粒和步踏砖等,粉煤灰的综合利用率在70%以上。通过调查粉煤灰综合利用情况,对制作水泥和制作步踏砖存在的问题提出了解决办法。针对大庆油田的实际情况,在借鉴国内外其他方法和技术的基础上,提出了综合利用粉煤灰的其他建议,例如用于固井作业的水泥浆体系,生产铝盐,用于填埋固体废物等。     

闭环气力输送粉煤灰中袋式除尘器所遇问题浅谈

对闭环气力输送粉煤灰系统中袋式除尘器滤袋压差值过高的现象进行了分析,得出了该系统处理的粉煤灰浓度大、粒径小、湿度大、黏性大的特点,并根据粉煤灰的这些特性采取了针对性措施,降低了袋式除尘器滤袋压差,使系统恢复正常工作。     

粉煤灰在重金属废水处理中的应用

粉煤灰是一种可再资源化的工业固体废弃物。利用粉煤灰对重金属废水进行处理可谓是一种以废治废、变废为宝、实现废物综合利用的有效途径。综述了粉煤灰吸附法在重金属废水处理中的国内外研究现状,展望了该方法的应用前景。     

利用粉煤灰生产超300^#砼的研究

本文以粉煤灰为主要原料，非蒸养法生产必能优良，超３００＾＃粉煤灰砼，研究了影响粉煤灰胶结料及砼强度的主要因素，找出了获得高度粉煤灰胶结料砼的最佳参数，进行了粉煤灰的性能试验；初步探讨了粉煤灰的砼性能优良的原因，该技术的粉煤灰开辟了一条高价值，大宗利用的有效途径。     

利用粉煤灰制作新型建筑材料

粉煤灰不仅占用大量耕地,而且严重污染环境。针对东营地区粉煤灰的产生现状,积极开发粉煤灰的废物利用。通过对粉煤灰生产空心砌块的原料配比和生产工艺实施的调查,结果表明,利用粉煤灰生产新型建筑材料是减少占地和建材工业征地的有效途径,能变废为宝、化害为利,达到保护环境的目的。     

粉煤灰吸附处理麻黄素废水的试验研究

根据粉煤灰的吸附机制，通过试验研究，为粉煤灰吸附工程提供了设计参数，同时也为探明ＣＯＤ、ＢＯＤ５及色度在粉煤灰中的降解转化规律提供了借鉴依据。     

粉煤灰改性吸附材料的研究

本文阐述了粉煤灰的主要化学成份、结构、物理性质，指出粉煤灰改性的物质基础，并结合笔者的研究情况，分析了改性粉煤灰处理废水和废气的机理，介绍了其在处理废水和废气的研究与应用情况，提出了应用改性粉煤灰处理废水和废气中存在的问题及今后研究的重点。     

粉煤灰及其利用

介绍了火力发电厂排放粉煤灰的主要物理化学性能，指出了综合利用粉煤灰的一些途径，介绍了从粉灰中提取聚合铝和用粉煤灰制分子筛工艺流程，对利用粉煤灰制做陶瓷进行了探讨。     

Application of coal ash to environmental improvement: Transformation into zeolite, potassium fertilizer, and FGD absorbent

The rapid increase in population and economic growth have led to an increase in energy demand. Coal reserves are distributed worldwide, and coal is now known to be the most stable and available energy source. However, utilization of coal as an energy source involves the generation of a great amount of coal ash, and the recycling rate of the ash is rather low. Coal ash is mainly used in civil construction materials, and there is a limit to the demand for coal ash by construction industries: therefore, the increasing amount of coal ash will be a serious problem in the near future. Different applications should be considered. In this paper, three environmentally-friendly methods for coal ash recycling are described. Firstly, alkali treatment can transform coal ash to zeolite, which is used in deodorant and for wastewater treatment and soil improvement. Secondly, potassium silicate fertilizer is produced from coal ash and has a higher retentivity in the soil than that of conventional fertilizers. Thirdly, emission of sulfur dioxide is controlled by flue gas desulfurization using coal ash. It is considered that environmentally-friendly use of coal ash is important from the viewpoints of energy, economy, and environmental strategy in order to realize the concept of sustainable development.     

Evaluation of leachates from coal refuse blended with fly ash at different rates

There is great interest in returning coal combustion products to mining sites for beneficial reuse as liming agents. A column study examined the effects of blending two coal fly ashes with an acid-forming coal refuse (4% pyritic S). Both fly ashes were net alkaline, but had relatively low neutralizing capacities. One ash with moderate alkalinity (CRF) was bulk blended with coal refuse at 0, 20, and 33% (w/w), while another lower alkalinity ash (WVF) was blended at 0, 5, 10, 20, and 33% (w/w). The columns were leached (unsaturated) weekly with 2.5 cm of simulated precipitation for >150 wk. Where high amounts of ash alkalinity (>20% w/w) were mixed with the coal refuse, pyrite oxidation was controlled and leachate pH was >7.0 with low metal levels throughout the study. At lower rates of alkalinity loading, trace metals were sequentially released from the WVF ash as the 5, 10, and 20% treatments acidified due to pyrite oxidation. Lechate metals increased in proportion to the total amounts applied in the ash. In this strongly acidic environment, metals such as Mn, Fe, and Cu were dissolved and leached from the ash matrix in large quantities. If ash is to be beneficially reused in the reclamation of acid-producing coal refuse, the alkalinity and potential acidity of the materials must be balanced through the appropriate addition of lime or other alkaline materials to the blend. Highly potentially acidic refuse material, such as that used here, may not be suitable for ash/refuse codisposal scenarios.     

煤灰渣利用中对人群所产生辐射影响的评价

煤的开发与利用产生了大量的灰，渣等固体废物，占用大量土地，污染土壤和水源，成为四大公害之一，因而对煤灰，渣的治理和综合利用一直受到人们的关注。然而，由于煤灰渣中的天然放射性水平较高，因此，在煤灰渣的综合利用，尤其在用作建筑材料时，不可避免地要受到其放射性核素的危害。本文在对四川省各燃煤电厂排放灰渣中的^238U,^232Th,^220R,^40X并无然放射性核素进行分析和研究的基础上，用UNSCEAR1982年报告所推荐的计算模式估算了各电厂煤灰渣制度建材对公众所产生的附加辐射剂量，评价了煤灰制度建材对环境和人群所产生的辐射影响，并提出了控制煤灰渣在建材中的最大掺合量，为其它作用的使用煤灰渣提出了科学的理论依据。     

The leaching characteristics of selenium from coal fly ashes

The leaching characteristics of selenium from several bituminous and subbituminous coal fly ashes under different pH conditions were investigated using batch methods. Results indicated that pH had a significant effect on selenium leaching from bituminous coal ash. The minimum selenium leaching occurred in the pH range between 3 and 4, while the maximum selenium leaching occurred at pH 12. The release of selenium from subbituminous coal ashes was very low for the entire experimental pH range, possibly due to the high content of calcium which can form hydration or precipitation products as a sink for selenium. The adsorption results for different selenium species indicated that Se(VI) was hardly adsorbable on either bituminous coal ashes or subbituminous coal ashes at any pH. However, Se(IV) was highly adsorbed by bituminous coal ashes under acidic pH conditions and was mostly removed by subbituminous coal ashes across the entire pH range. This result suggests that the majority of selenium released from the tested fly ashes was Se(IV). A speciation-based model was developed to simulate the adsorption of Se(IV) on bituminous coal fly ash, and the pH-independent adsorption constants of HSeO3* and SeO3 2* were determined. The modeling approach is useful for understanding and predicting the release process of selenium from fly ash.     

Coal Combustion Product: Nonhazardous Material for Mine Fill

As is the case in many other countries around the world, India's main source of electricity is coal‐fired power plants. In addition to providing energy, the burning of coal also results in large amounts of coal combustion products (CCP), the incombustible material, such as fly ash, left after the coal is burned. These materials are produced in large volume, and if they are not managed or utilized properly, they can pose a danger to the environment. This article discusses the uses of CCP, with a special emphasis on fly ash, and the role that it is currently playing and can continue to play as a mine filler for India's depleted opencast and underground coal mines.     

利用粉煤灰处理采油废水的研究

利用电厂粉煤灰及灰场氧化塘对现河首站采油废水中的污染物进行吸附和生化处理试验。试验结果表明:粉煤灰具有类似活性炭的结构和比表面积,对废水中的石油类、COD、氨氮、挥发酚等污染物具有较强的吸附、沉降和过滤作用。     

Ash and deposit formation from oxy-coal combustion in a 100 kW test furnace

Ash deposition is still an unresolved problem when retrofitting existing air-fired coal power plants to oxy-fuel combustion. Experimental data are quite necessary for mechanism validation and model development. This work was designed to obtain laboratory combustor data on ash and deposits from oxy-coal combustion, and to explore the effects of oxy-firing on their formation. Two bituminous coals (Utah coal and Illinois coal) and one sub-bituminous coal (PRB coal) were burned on a down-fired combustor under both oxy- and air-firing. Two oxy-fired cases, i.e., 27 vol% O₂/73 vol% CO₂ and 32 vol% O₂/68 vol% CO₂, were selected to match the radiation flux and the adiabatic flame temperature of air combustion, respectively. Once-through CO₂ was used to simulate fully cleaned recycled flue gas. The flue gas excess oxygen was fixed at 3 vol%. For each case, both size-segregated fly ash and bulk fly ash samples were obtained. Simultaneously, ash deposits were collected on an especially designed un-cooled deposition probe. Ash particle size distributions and chemical composition of all samples were characterized. Data showed that oxy-firing had insignificant impacts on the tri-modal ash particle size distributions and composition size distributions in the size range studied. Bulk ash compositions also showed no significant differences between oxy- and air-firing, except for slightly higher sulfur contents in some oxy-fired ashes. The oxy-fired deposits were thicker than those from air-firing, suggesting enhanced ash deposition rates in oxy-firing. Oxy-firing also had apparent impacts on the deposit composition, especially for those components (e.g., CaO, Fe₂O₃, SO₃, etc.) that could contribute significantly to ash deposition. Based on these results, aerodynamic changes in gas flow and changes in combustion temperature seemed more important than chemical changes of ash particles in determining deposit behavior during oxy-coal combustion.     

Leaching characteristics of solid wastes from thermal power plants of western Turkey and comparison of toxicity methodologies

Use of lignite in power generation has led to increasing environmental problems associated not only with gaseous emissions, but also with the disposal of ash residues. In particular, use of low quality coals with high ash content results in huge quantities of both fly and bottom ashes to be disposed of. A main problem related to coal ash disposal is the heavy metal content of the residue. In this regard, experimental results of numerous studies indicate that toxic trace metals may leach when fly and bottom ashes are in contact with water. In this study, fly and bottom ash samples obtained from thermal power plants, namely Yenikoy, Kemerkoy and Yatagan, located at the southwestern coast of Turkey, were subjected to toxicity tests such as the extraction (EP) and toxicity characteristic leaching (TCLP) procedures of the US Environmental Protection Agency (USEPA) and the so-called 'Method A' extraction procedure of the American Society of Testing and Material (ASTM). The geochemical composition of ash samples showed variations depending on the coal burned in the plants. Furthermore, the EP, TCLP and ASTM toxicity tests showed variations such that the ash samples were classified as 'toxic waste' based on EP and TCLP results whereas they were classified as 'non-toxic' based on ASTM results, indicating test results are pH dependent. When the extraction results were compared with the chemical composition of water samples obtained in the vicinity of the thermal power plants, it was found that the results obtained using the ASTM procedure cannot be used to predict subsurface contamination whereas the EP and TCLP procedures can be used.