煤炭在我國的一次能源消費中占到75%左右，燃煤火力發電廠產生的煙氣是大氣汙染的重要來源。在目前的燃煤煙氣脫硫技術中，石灰石－石膏濕法是我國大力推廣的技術，此技術適用於常見煤種，具有90%以上的效脫硫率，95%以上的係統回用率和90%以上的吸收劑利用率，此套工藝運行穩定，而且石灰石來源廣泛，價格便宜。

　　Coal accounts for about 75% of China's primary energy consumption, and the flue gas generated by coal-fired power plants is an important source of air pollution. In the current coal-fired flue gas desulfurization technology, the limestone gypsum wet process is a widely promoted technology in China. This technology is suitable for common coal types and has an effective desulfurization rate of over 90%, a system reuse rate of over 95%, and an absorbent utilization rate of over 90%. This process runs stably and has a wide range of limestone sources and is inexpensive.

　　因此，我國的脫硫廢水主要是石灰石－石膏濕脫硫技術所產生的，也就是精品乱码一区内射人妻无码通常所說的脫硫廢水。下麵概括幾種脫硫廢水的深度處理工藝。

　　Therefore, the desulfurization wastewater in China is mainly generated by limestone gypsum wet desulfurization technology, which is commonly referred to as desulfurization wastewater. Below are several advanced treatment processes for desulfurization wastewater.

　　?1?脫硫廢水蒸發濃縮

　　1. Evaporation and concentration of desulfurization wastewater

　　通過蒸發和幹燥設備能夠讓脫硫廢水分離成為高質量的水或水蒸氣以及固體廢棄物，可以實現水的循環使用，可以完成火力發電廠廢水零排放，此方法的缺點是需要高額的投資，目前在國內還沒有實際運行的實例。脫硫廢水蒸發係統由四個部分構成，分別是熱輸入、熱回收、排熱以及附屬係統部分；低壓蒸汽和熱交換管內流動的循環脫硫廢水在水加熱器內水進行熱交換，加熱沸騰了的循環脫硫廢水分別流到每個閃蒸室內進行閃蒸，蒸發出的水蒸汽通過除霧器和蒸發器上部的熱交換管再進行熱交換冷凝，每一級所得到的蒸汽凝結水被熱交換管下端的蒸餾水托盤收集，從而實現固液分離，此工藝技術流程操作簡單，蒸發回收水水質良好，此工藝的投資成本太高限製了它在實際脫硫廢水工程中的應用。

　　Through evaporation and drying equipment, desulfurization wastewater can be separated into high-quality water or steam, as well as solid waste, which can achieve water recycling and achieve zero discharge of wastewater from thermal power plants. The disadvantage of this method is that it requires high investment, and there are currently no actual operating examples in China. The desulfurization wastewater evaporation system consists of four parts, namely heat input, heat recovery, heat dissipation, and ancillary system parts; The circulating desulfurization wastewater flowing in the low-pressure steam and heat exchange tubes undergoes heat exchange in the water heater. The heated and boiled circulating desulfurization wastewater flows into each flash evaporation chamber for flash evaporation. The evaporated water vapor is then condensed by heat exchange through the demister and heat exchange tubes on the upper part of the evaporator. The condensed water obtained from each stage is collected by the distilled water tray at the lower end of the heat exchange tube, thereby achieving solid-liquid separation. This process technology has a simple operation and good water quality for evaporation recovery. The high investment cost of this process limits its application in actual desulfurization wastewater engineering.

　　2?脫硫廢水的生物處理

　　Biological treatment of desulfurization wastewater

　　脫硫廢水中COD固然不高，但有別於一般的廢水，脫硫廢水形成的化學需氧量的主要因素是還原態的無機物，並不是有機物，脫硫廢水還有高鹽度，高氨氮和高總氮的特點，這說明脫硫廢水的可生化性很差。目前，國內外學者提出了一些突破傳統理論的新認識和新發現，特別是在生物脫氮工藝上有了新的突破，像短程硝化反硝化、厭氧氨氧化、同步硝化反硝化、好氧反硝化等為脫硫廢水的處理提供了新的思路。厭氧氨氧化作為脫硫廢水生物脫氨工藝具有巨大的應用潛力，但是脫硫廢水的高鹽度會抑製厭氧氨氧化細菌的活性，厭氧氨氧化細菌如何才能適應脫硫廢水這樣的成分複雜的廢水還需要深入的研究；脫硫廢水複雜性對微生物的活性具有很強的抑製作用，微生物可以通過適當的馴化去抵製脫硫廢水的毒性，對於脫硫廢水對活性汙泥的毒性的影響也是需要進一步的研究。以活性汙泥法為代表的生化處理工藝已是相當成熟，活性汙泥法具有操作簡單，廉價高效等特點，如果可以將活性汙泥法應用到脫硫廢水處理中將會給脫硫廢水的處理帶來新的視野。

　　Although the COD in desulfurization wastewater is not high, it is different from ordinary wastewater. The main factor causing the chemical oxygen demand in desulfurization wastewater is the reduced inorganic matter, not the organic matter. The desulfurization wastewater also has the characteristics of high salinity, high ammonia nitrogen, and high total nitrogen, which indicates that the biodegradability of desulfurization wastewater is poor. At present, scholars at home and abroad have proposed some new understandings and discoveries that break through traditional theories, especially in the field of biological nitrogen removal processes, such as short-range nitrification denitrification, anaerobic ammonia oxidation, synchronous nitrification denitrification, aerobic denitrification, etc., which provide new ideas for the treatment of desulfurization wastewater. Anaerobic ammonia oxidation, as a biological ammonia removal process for desulfurization wastewater, has great potential for application. However, the high salinity of desulfurization wastewater can inhibit the activity of anaerobic ammonia oxidation bacteria. Further research is needed on how anaerobic ammonia oxidation bacteria can adapt to the complex composition of desulfurization wastewater; The complexity of desulfurization wastewater has a strong inhibitory effect on the activity of microorganisms. Microorganisms can resist the toxicity of desulfurization wastewater through appropriate domestication. Further research is needed to investigate the impact of desulfurization wastewater on the toxicity of activated sludge. The biochemical treatment process represented by the activated sludge method is quite mature. The activated sludge method has the characteristics of simple operation, low cost and high efficiency. If the activated sludge method can be applied to the treatment of desulfurization wastewater, it will bring new perspectives to the treatment of desulfurization wastewater.

　　3?微生物燃料電池對脫硫廢水的處理

　　Treatment of desulfurization wastewater by 3 microbial fuel cells

　　微生物燃料電池(microbialfuelcell，MFC)是將廢水中有機物的化學能轉化為電能，在去除汙染物的同時將產生的電能回收，實現了能量轉化。近年來隨著微生物燃料電池的迅速發展，作為一種新的反應裝置有著高效的去除汙染物的效果和產電回收能源的雙重效果，微生物燃料電池的發展不可限量，將微生物燃料電池與脫硫廢水的處理結合起來會是一個很好的出路。圖1 ?MFC係統組成微生物燃料電池的示意圖如圖1所示，MFC一般由陽極、膜和陰極組成，在常見的MFC陽極室內，厭氧產電微生物通過呼吸作用將供體的有機汙染物氧化來，釋放出電子和質子，產生的電子將通過位於細胞外膜的電子載體(例如細胞色素c或被稱為納米導線的菌毛)傳遞到陽極，然後再經過外部電路轉移到陰極，釋放出產生的能量，從而產生電流；質子通過離子交換膜轉移到陰極，在陰極室內，質子、電子受體和電子發生還原反應，微生物燃料電池是能夠在常溫常壓下進行難降解物質的降解和能量的轉換。對於脫硫廢水這樣的難降解的汙染物，需要添加容易降解的有機物作為共生基質，也就是在共代謝的條件下才能被有效降解，對使用MFC和UASB對硫化廢水的處理進行比較，得出MFC對處理硫化廢水有著較好的效果和較高的經濟性。

　　Microbial fuel cell (MFC) converts the chemical energy of organic matter in wastewater into electrical energy, and recovers the generated electrical energy while removing pollutants, achieving energy conversion. In recent years, with the rapid development of microbial fuel cells, as a new reaction device, it has a dual effect of efficient removal of pollutants and energy recovery from electricity production. The development of microbial fuel cells is unlimited, and combining microbial fuel cells with desulfurization wastewater treatment will be a good way out. Figure 1 shows a schematic diagram of the composition of a microbial fuel cell in an MFC system. MFC generally consists of an anode, a membrane, and a cathode. In a common MFC anode chamber, anaerobic electricity producing microorganisms oxidize organic pollutants from donors through respiration, releasing electrons and protons. The generated electrons are transferred to the anode through an electron carrier located on the outer membrane of the cell (such as cytochrome c or pili called nanowires), and then transferred to the cathode through an external circuit, releasing the generated energy and generating an electric current; Protons are transferred to the cathode through an ion exchange membrane. In the cathode chamber, protons, electron acceptors, and electrons undergo reduction reactions. Microbial fuel cells are capable of degrading difficult to degrade substances and converting energy at room temperature and pressure. For pollutants such as desulfurization wastewater that are difficult to degrade, it is necessary to add easily degradable organic matter as a symbiotic matrix, which can only be effectively degraded under co metabolism conditions. Comparing the treatment of sulfide wastewater using MFC and UASB, it is concluded that MFC has a better effect and higher economy in treating sulfide wastewater.

　　本文由 生物脫硫   友情奉獻.更多有關的知識請點擊  http://www.desencn.com/   真誠的態度.為您提供為全麵的服務.更多有關的知識精品乱码一区内射人妻无码將會陸續向大家奉獻.敬請期待.

　　This article is contributed by the friendship of biological desulfurization For more related knowledge, please click http://www.desencn.com/ Sincere attitude To provide you with comprehensive services We will gradually contribute more relevant knowledge to everyone Coming soon.