本書(shū)系統(tǒng)介紹了各種水處理單元技術(shù)方法的基本原理、工藝流程、設(shè)計(jì)計(jì)算、管理及應(yīng)用等。內(nèi)容包括總論、篩濾與調(diào)節(jié)、混凝、沉淀與上浮、深層過(guò)濾、化學(xué)處理、吸附、離子交換、膜分離、其他相轉(zhuǎn)移分離法、循環(huán)冷卻水處理、廢水生物處理理論基礎(chǔ)、好氧活性污泥法、好氧生物膜法、厭氧生物處理、生物脫氮除磷、人工生態(tài)處理、污泥處理與處置、廢水處理廠設(shè)計(jì)等。
本書(shū)系統(tǒng)介紹了各種水處理單元技術(shù)方法的基本原理、工藝流程、設(shè)計(jì)計(jì)算、管理及應(yīng)用等。內(nèi)容包括總論、篩濾與調(diào)節(jié)、混凝、沉淀與上浮、深層過(guò)濾、化學(xué)處理、吸附、離子交換、膜分離、其他相轉(zhuǎn)移分離法、循環(huán)冷卻水處理、廢水生物處理理論基礎(chǔ)、好氧活性污泥法、好氧生物膜法、厭氧生物處理、生物脫氮除磷、人工生態(tài)處理、污泥處理與處置、廢水處理廠設(shè)計(jì)等。
李大鵬,男,46歲,蘇州科技大學(xué)/省協(xié)同創(chuàng)新中心管委會(huì)辦公室主任/教授,高等教育給排水科學(xué)與工程專(zhuān)業(yè)評(píng)估委員會(huì)委員,專(zhuān)業(yè)方向:農(nóng)村生活污水處理,地表水修復(fù)/訪問(wèn)學(xué)者1年,為國(guó)際留學(xué)生全英文授課4年。主持完成國(guó)家自然科學(xué)基金3項(xiàng),主持完成省部級(jí)項(xiàng)目3項(xiàng),參與完成國(guó)家自然科學(xué)基金重點(diǎn)項(xiàng)目1項(xiàng)和十一五水重大專(zhuān)項(xiàng)1項(xiàng);目前主持國(guó)家自然科學(xué)基金1項(xiàng)、十三五水重大專(zhuān)項(xiàng)子課題2項(xiàng)、省高校重大項(xiàng)目1項(xiàng)。參編《湖泊沉積物界面過(guò)程與效應(yīng)》,2013年,科學(xué)出版社,獨(dú)立撰寫(xiě)第10章,4萬(wàn)字。迄今,公開(kāi)發(fā)表文章102篇,其中SCI6篇(1區(qū)1篇,2區(qū)3篇),EI15篇,CSCD收錄31篇。
Chapter 1 Overview of waste water ( 1 ) 1.1 What is waste water ( 1 ) 1.2 The types of the waste water ( 2 ) 1.2.1 Domestic waste water ( 2 ) 1.2.2 Industrial waste water ( 16 ) 1.2.3 Rural waste water ( 27 ) 1.3 The effects of the waste water ( 40 ) 1.3.1 Chemistry of water impurities ( 40 ) 1.3.2 Metallic corrosion ( 43 ) 1.3.3 Scale formation ( 47 ) 1.3.4 Fouling ( 48 ) 1.4 Waste water treatment processes ( 50 ) 1.4.1 Preliminary and primary treatment ( 50 ) 1.4.2 Secondary (biological) treatment ( 55 ) 1.4.3 Tertiary (advanced) treatment ( 65 )Chapter 2 Treatment theory of the activated sludge ( 75 ) 2.1 The traditional activated sludge ( 75 ) 2.1.1 The basic conception and the process ( 75 ) 2.1.2 The forms and component of the activated sludge ( 76 ) 2.1.3 The microorganism in the activated sludge and its function ( 77 ) 2.1.4 The clarification process by the activated sludge ( 78 ) 2.1.5 The effect of the environmental factors on the activated sludge ( 80 ) 2.2 Some performance indexes of the activated sludge ( 85 ) 2.2.1 Some performance indexes of the activated sludge ( 85 ) 2.2.2 Some indexes of the activated sludge for designment and running ( 89 ) 2.2.3 Aeration ( 92 ) 2.3 The development and application of the activated sludge ( 95 ) 2.3.1 Complete-mix activated sludge process ( 95 )2.3.2 Tapered aeration process ( 96 )2.3.3 Contact-stabilization activated sludge ( 97 ) 2.3.4 High-purity oxygen activated sludge ( 98 ) 2.3.5 Step-feed activated sludge ( 99 ) 2.3.6 Extended aeration activated sludge (100) 2.3.7 High-rate activated sludge (100) 2.3.8 Selector activated sludge (101) 2.3.9 The running parameters for the traditional activated sludge andmodified processes (102) 2.4 The cultivation and running management of the activated sludge (103) 2.4.1 The cultivation of the activated sludge (103) 2.4.2 The running of the activated sludge (103) 2.5 The abnormal phenomenon during the running of the activated sludge (105) 2.5.1 Sludge bulking (105) 2.5.2 Sludge disintegration (107) 2.5.3 Sludge corruption (108) 2.5.4 Sludge floating (108) 2.5.5 Bubbles (108) 2.5.6 Abnormal biofacies (109) 2.5.7 Insufficient nitrification (109) 2.5.8 Insufficient denitrification (110) 2.6 The designment of the activated sludge (110) 2.6.1 Aeration tank (110) 2.6.2 The secondary settling tank (111) 2.6.3 The design on the backflow of the sludge (112)Chapter 3 The biofilm (115) 3.1 The basic concepts (116) 3.1.1 The formation of the biofilm and the clarification (116) 3.1.2 The carrier of the biofilm (118) 3.1.3 The characteristics of the biofilm (119) 3.1.4 The biofilm reactor (121) 3.2 Some important parameters (121) 3.2.1 Specific increase rate of biomass (122) 3.2.2 Specific removal rate of the substrate (122) 3.3 Bio-filters (123)3.3.1 The definition of the bio-filter (123 ) 3.3.2 Trickling filter (125) 3.3.3 High-rate filter (127) 3.3.4 Tower biofilter (131) 3.3.5 Biological aerated filter (133) 3.4 Rotating biological contactor (136) 3.4.1 The overview (136) 3.4.2 The principle and the application (136) 3.4.3 The designment of the rotating biological contactor (139) 3.5 Submerged biofilm reactor (140) 3.5.1 The structure (141) 3.5.2 The form of the aeration tank (142) 3.5.3 The characteristics of the submerged biofilm reactor (144) 3.5.4 The processes of the submerged biofilm reactor (144) 3.5.5 The designment of the submerged biofilm reactor (146) 3.6 Biological fluidized bed (147) 3.6.1 The structure (147) 3.6.2 The characteristics u56256 ._xddba_ (148) 3.6.3 The process type of the biological fluidized bed (149) 3.6.4 The designment of the biological fluidized bed (151) 3.7 The new biofilm reactor and combination process (152) 3.7.1 Combined biofilm reactor (152) 3.7.2 Union process of biofilm and activated sludge (153)Chapter 4 Typical treatment processes on domestic and industrywaste water (156) 4.1 For domestic waste water (156) 4.1.1 Oxidation ditch (156) 4.1.2 Sequencing batch reactor (171) 4.1.3 Membrane bioreactor (183) 4.1.4 Adsorption biodegradation (AB) (186) 4.1.5 Moving bed biofilm reactor (188) 4.1.6 A/ O process (190) 4.2 For Industrial waste water (206) 4.2.1 Anaerobic biological treatment (207)4.2.2 Upflow anaerobic sludge blanket reactor (216 ) 4.2.3 The other typical technologies (218)Chapter 5 Typical technology on rural waste water (227) 5.1 Production and collection of rural domestic waste water (227) 5.1.1 Production of rural domestic waste water (227) 5.1.2 Collection of rural domestic waste water (228) 5.1.3 Water quality characteristics of rural domestic waste water (230) 5.2 Typical technologies (231) 5.2.1 Oxidation lagoon (231) 5.2.2 The wetlands (241) 5.3 Commonly used integrated treatment device for rural domesticsewage treatment (246) 5.3.1 Vertical flow type AAO integrated device (246) 5.3.2 Integrated air lift SBR device (247) 5.3.3 Integrated biological filter (249) 5.3.4 Integrated MBR device (250) 5.4 Long-term operation and management mechanism of rural waste watertreatment technology (251)5.4.1 Territory (village and town) self-operation and maintenancemanagement mechanism (251) 5.4.2 Third-party operation management mechanism (251) 5.4.3 Construction and operation integrated operation managementmechanism (252)Chapter 6 Control and use on sludge (254) 6.1 Overview (254) 6.1.1 The principle for the sludge treatment (254) 6.1.2 The basic method for the sludge treatment (255) 6.1.3 The basic process for the sludge treatment (256) 6.2 Sludge characteristics and calculation (256) 6.2.1 The component and the types of the sludge (256) 6.2.2 The indexes of the sludge (257) 6.2.3 The calculation on the sludge amount (260) 6.3 Sludge thickening (261) 6.3.1 The gravity thickening (262)6.3.2 The flotation thickening (263 ) 6.4 Sludge digestion (264) 6.4.1 Anaerobic digestion (264) 6.4.2 Aerobic digestion (265) 6.5 Sludge conditioning (265) 6.5.1 Chemical conditioning (266) 6.5.2 Heat conditioning (266) 6.5.3 Elutriation conditioning (266) 6.5.4 Freezing solution conditioning (267) 6.6 Sludge dewatering (267) 6.6.1 The natural drying of sludge (267) 6.6.2 The mechanical dewatering of sludge (267) 6.7 Sludge drying and incineration (270) 6.8 Comprehensive utilization and ultimate disposal of the sludge (270) 6.8.1 Agricultural fertilizer (270) 6.8.2 Building materials (271) 6.8.3 Landfill (271) 6.8.4 Land use (271) 6.8.5 Compost (272) 6.8.6 Thermolysis (273)Chapter 7 Waste water treatment cases (275) 7.1 Traditional activated sludge (276) 7.2 Anaerobic-aerobic activated sludge process (277) 7.2.1 Anaerobic-aerobic activated sludge process for removal P (277) 7.2.2 Anaerobic/ anoxic/ aerobic process (278) 7.3 Adsorption/ biodegradation process (278) 7.4 Oxidation ditch process (280) 7.4.1 A-E oxidation ditch (280) 7.4.2 T oxidation ditch (282) 7.5 Biological aerated filter (284) 7.6 A domestic example of reconstruction and extension of sewage plant (285) 7.6.1 Introduction (285) 7.6.2 Renovation and extension scheme of sewage plant (289) 7.6.3 Operation effect (319)Chapter 8 Water reclamation and reuse (320 ) 8.1 Water reclamation (321) 8.2 Current and potential future global water shortages (324) 8.2.1 Irrigation water use (324) 8.2.2 Domestic and industrial water uses (325) 8.3 The important role of the water reclamation and reuse (325) 8.4 Technology development (330) 8.4.1 Typical water reclamation processes (332) 8.4.2 Complete flow scheme optimizing for water reuse (334) 8.5 Framework for water reuse implementation (338) 8.6 Cases (339) 8.6.1 Water reuse in China (339) 8.6.2 The others (350)Chapter 9 Waste water recovery (358) 9.1 What is waste water recovery (358) 9.1.1 Pollutant recovery (358) 9.1.2 Water reuse (359) 9.2 Recovery and energy in municipal waste water (360) 9.2.1 Recovery types and feasibility (360) 9.2.2 Energy reserves and energy feasibility (361) 9.3 Phosphorus recovery (362) 9.3.1 Significance of phosphorus recovery (362) 9.3.2 Basic methods for phosphorus resource (363) 9.3.3 Evaluation on phosphorus resource (366)