隨著我國經(jīng)濟的快速發(fā)展,人口的增長和城市化進程的加快��,城市生活垃圾產(chǎn)量也在急劇增加����;同時,生活垃圾的無害化處理也得到了相應的發(fā)展��,形成了以焚燒發(fā)電為主的處理方式���。隨著技術的不斷發(fā)展和行業(yè)變化�,我國生活垃圾焚燒處理裝備向著大型化���、高參數(shù)的方向邁進�,同時,對焚燒系統(tǒng)的高效�����、低碳��、穩(wěn)定運行提出了更高的要求��。
我國自1987年開始從國外引進垃圾發(fā)電技術���,深圳市首s次新建的垃圾發(fā)電廠開始營業(yè)�����,自此���,國內(nèi)的垃圾焚燒發(fā)電技術后來居上,邁上了快車道��。特別是近年來��,隨著我國“碳達峰-碳中和”戰(zhàn)略目標的提出�,垃圾焚燒發(fā)電技術發(fā)展迅猛。垃圾焚燒發(fā)電裝機容量由2016年的549萬千瓦增至2021年的1729萬千瓦���,目前垃圾電站的裝機容量和垃圾年處理量均列世界第d一�。包括水冷壁�����、過熱器���、再熱器����、省煤器在內(nèi)的鍋爐四管是鍋爐組件中重要的熱量交換部件�。由于城市生活垃圾中的氯、硫��、堿金屬等是不可能消除的成分�,因此在垃圾焚燒過程中,鍋爐四管金屬受熱面受到嚴重的高溫腐蝕難以避免���。隨著垃圾焚燒爐中蒸汽參數(shù)逐漸提高��,對于鍋爐受熱面防腐的要求也愈加嚴格�。
當管壁金屬或涂層由于腐蝕脫落或使管壁減薄到一定程度時,管內(nèi)的高壓水汽會沖出即出現(xiàn)高壓泄漏甚至爆管�����,迫使鍋爐非計劃停機維護�,不僅會造成嚴重的安全隱患,也會對發(fā)電效率以及垃圾發(fā)電經(jīng)濟性都會造成極大影響�。因此,一直以來垃圾鍋爐的高溫腐蝕防護問題����,成為阻礙垃圾發(fā)電行業(yè)發(fā)展的瓶頸,嚴重制約了我國垃圾處理環(huán)保產(chǎn)業(yè)的快速發(fā)展�����,也是擺在我國垃圾焚燒發(fā)電領域科技人員面前亟待解決的問題�����。多年來���,我國該領域的科技人員為此做出了艱苦的努力���,取得了不少研究成果�。本書是在吸收了近年來國內(nèi)外垃圾發(fā)電高溫防腐領域研究的基礎上���,重點對作者多年來的研究成果進行了闡述,旨在為相關科技人員開發(fā)鍋爐高溫防腐新技術提供基礎����。
本書共分七章,內(nèi)容主要包括垃圾電站鍋爐高溫腐蝕現(xiàn)狀與理論���、垃圾電站鍋爐防腐技術與發(fā)展����、垃圾電站鍋爐合金涂層的材料體系及特性��、垃圾電站鍋爐合金涂層的高溫腐蝕特性�、垃圾電站鍋爐重熔涂層技術、垃圾焚燒鍋爐的防腐優(yōu)化設計及應用等�。
龍吉生,男�����,1966年生于江西省吉安市吉水縣,1988年政府公派日本留學并于1994年獲工學博士學位�。在日本技術開發(fā)株式會社工作15年后,于2008年底回國創(chuàng)業(yè)�����,創(chuàng)立了上�?岛悱h(huán)境股份有限公司。現(xiàn)任上����?岛悱h(huán)境股份有限公司董事長兼首席科學家,日本福岡大學客座教授��,國務院政府特殊津貼獲得者����,國家重點研發(fā)計劃首席科學家。是上海市領軍人才����,住建部科技委城市環(huán)境衛(wèi)生專委會委員,國家發(fā)展改革委PPP專家����,住建部可持續(xù)發(fā)展與資環(huán)專委會委員,住建部可持續(xù)發(fā)展與資源環(huán)境專家委員會委員。從事固廢處理技術研發(fā)和應用近30年���,在日期間主持了日本巖手�、新瀉���、宮崎等多個垃圾焚燒項目��,回國后主持開發(fā)了新一代爐排爐焚燒技術,該技術與裝備在國內(nèi)占據(jù)超過1/3的市場份額�����。帶領康恒環(huán)境在全國已投資建設約70余座垃圾焚燒發(fā)電項目��,處理垃圾規(guī)模約10萬噸/日���。曾獲國家科學技術進步二等獎(公司)1項(2013)���、教j育y部科學技術進步獎一等獎1項(2012)、華夏建設科學技術獎一�、二等獎各1項(2011、2020)�,曾獲日中科學技術交流協(xié)會“天田科學技術研究獎”(1991)和日本廢棄物技術咨詢顧問協(xié)會“有功獎”(2001)等。已發(fā)表學術論文40余篇,參編著作4部�����,授權專利96項�����,其中發(fā)明專利15項����。參編《生活垃圾焚燒污染控制標準》(GB18485-2014)等標準規(guī)范6項。
序
前言
1 概述 ······························································································· 1
1.1 我國生活垃圾產(chǎn)生及處理現(xiàn)狀 ································································· 1
1.1.1 生活垃圾的產(chǎn)生及性質(zhì) ··································································· 1
1.1.2 生活垃圾的處理現(xiàn)狀 ······································································ 5
1.2 生活垃圾焚燒技術發(fā)展及難點 ································································· 9
1.2.1 垃圾焚燒大型化及蒸汽高參數(shù)化發(fā)展 ················································· 9
1.2.2 鍋爐長周期安全穩(wěn)定運行的需求凸顯 ················································ 15
參考文獻 ································································································· 19
2 垃圾焚燒鍋爐高溫腐蝕現(xiàn)狀與理論 ······················································· 21
2.1 背景及意義 ························································································ 21
2.1.1 垃圾焚燒鍋爐受熱面爆管現(xiàn)狀 ························································· 21
2.1.2 垃圾焚燒鍋爐的高溫腐蝕問題 ························································· 24
2.1.3 垃圾焚燒鍋爐高溫防腐的迫切性 ······················································ 25
2.2 垃圾焚燒鍋爐高溫腐蝕類型 ·································································· 26
2.2.1 含氯氣體引起的腐蝕 ····································································· 26
2.2.2 固態(tài)堿金屬氯化物引起的腐蝕 ························································· 26
2.2.3 熔融態(tài)堿金屬氯化物引起的腐蝕 ······················································ 27
2.3 垃圾焚燒鍋爐高溫腐蝕產(chǎn)物 ·································································· 28
2.3.1 垃圾焚燒鍋爐管壁的腐蝕產(chǎn)物 ························································· 28
2.3.2 氯化腐蝕的基本過程 ····································································· 30
2.4 垃圾焚燒鍋爐高溫腐蝕機理 ·································································· 31 2.4.1 高溫腐蝕的規(guī)律 ···········································································31
2.4.2 高溫氯腐蝕微觀過程 ·····································································32
2.4.3 高溫腐蝕的影響因素 ·····································································33
2.5 高溫腐蝕速度規(guī)律 ··············································································· 36
2.5.1 腐蝕速度與管壁溫度間的關系 ·························································36
2.5.2 腐蝕速度的主要影響因素 ·······························································40
2.5.3 高溫腐蝕速率小結 ········································································46
參考文獻 ·································································································· 48
3 垃圾焚燒鍋爐防腐涂層技術與發(fā)展 ······················································ 50
3.1 垃圾焚燒鍋爐管基材 ············································································ 51
3.2 基于制備工藝的防腐涂層體系 ································································ 54
3.2.1 熱噴涂技術 ·················································································55
3.2.2 堆焊技術 ····················································································64
3.2.3 感應熔焊技術 ··············································································67
3.2.4 滲鋁涂層技術 ··············································································70
3.2.5 納米陶瓷涂層技術 ········································································72
3.2.6 激光熔覆涂層技術 ········································································74
3.3 涂層材料體系設計及其協(xié)同發(fā)展 ····························································· 76
3.3.1 合金材料體系 ··············································································77
3.3.2 金屬陶瓷材料體系 ········································································77
3.3.3 涂層工藝與材料的協(xié)同發(fā)展 ····························································77
參考文獻 ·································································································· 79
4 垃圾焚燒鍋爐防腐涂層的材料體系及特性 ············································· 85
4.1 高溫防腐合金 ····················································································· 85
4.1.1 鎳基高溫耐蝕合金 ········································································85
4.1.2 Ni
?
Cr 型耐蝕合金 ········································································88
4.1.3 Ni
?
Mo 型耐蝕合金 ······································································88
4.1.4 Ni
?
Cr
?
Mo 系耐蝕合金 ·································································89
4.2 Ni
?
Crx
?
Mo 系高溫耐蝕合金涂層 ·························································· 89
4.2.1 Ni
?
Crx
?
Mo 系高溫耐蝕合金涂層制備 ·············································89
4.2.2 Ni
?
Crx
?
Mo 系耐蝕合金涂層顯微硬度分析 ·······································91
4.2.3 Ni
?
Crx
?
Mo 系耐蝕合金涂層顯微組織分析 ·······································91
4.2.4 Ni
?
Crx
?
Mo 系高溫耐蝕合金涂層電化學測試分析 ······························98 4.3 Ni
?
Cr
?
Mox 系高溫耐蝕合金涂層 ·························································101
4.3.1 Ni
?
Cr
?
Mox 系高溫耐蝕合金涂層制備 ··········································· 101
4.3.2 Ni
?
Cr
?
Mox 系高溫耐蝕合金涂層組織 ··········································· 102
4.3.3 Ni
?
Cr
?
Mox 系高溫耐蝕合金浸泡腐蝕性能 ····································· 104
參考文獻 ································································································ 114
5 垃圾焚燒鍋爐防腐涂層的高溫腐蝕特性 ··············································· 117
5.1 Ni
?
Cr
?
Mo 系合金涂層的高溫氯腐蝕特性 ·············································· 117
5.1.1 Ni
?
Cr
?
Mo 系合金涂層高溫腐蝕試驗設計 ······································· 117
5.1.2 高溫堿金屬氯化物熔鹽腐蝕實驗 ···················································· 118
5.1.3 TP347H 不銹鋼的高溫氯腐蝕 ······················································· 121
5.1.4 Ni
?
Cr
?
Mo 系鎳基合金的高溫氯腐蝕 ············································· 127
5.1.5 Ni
?
Cr
?
Mo 系鎳基合金涂層的高溫氯腐蝕 ······································· 132
5.1.6 Ni
?
Cr
?
Mo 系鎳基合金涂層的高溫腐蝕機理 ···································· 137
5.1.7 Ni
?
Cr
?
Mo 系合金涂層的高溫氯腐蝕特性總結 ································· 140
5.2 高 Mo/W 系 Ni
?
Cr
?
Mo 合金涂層的高溫氯/硫腐蝕特性 ·····························141
5.2.1 高 Mo/W 系 Ni
?
Cr
?
Mo 合金涂層的制備 ········································ 141
5.2.2 高溫氯硫?qū)嶒炦^程 ······································································ 142
5.2.3 TP347H 不銹鋼的高溫氯硫腐蝕 ····················································· 144
5.2.4 NiCr17Mo 合金涂層的高溫氯硫腐蝕特性 ········································· 150
5.2.5 NiCrMo10W 系合金涂層的高溫氯硫腐蝕特性 ··································· 156
5.2.6 高 Mo/W 系 Ni
?
Cr
?
Mo 合金涂層的高溫氯硫腐蝕機理 ······················· 162
5.2.7 高 Mo/W 系 Ni
?
Cr
?
Mo 合金涂層的高溫氯硫腐蝕特性總結 ················· 166
參考文獻 ································································································167
6 垃圾焚燒余熱鍋爐受熱面重熔涂層技術研究 ········································· 172
6.1 二次重熔技術 ····················································································172
6.1.1 應用背景 ···················································································· 172
6.1.2 國內(nèi)外研究現(xiàn)狀 ··········································································· 173
6.2 耐垃圾焚燒煙氣重熔涂層的制備工藝 ·····················································175
6.2.1 實驗材料 ···················································································· 176
6.2.2 熱噴涂層的制備 ··········································································· 176
6.2.3 涂層的二次重熔 ··········································································· 177
6.3 重熔涂層的實驗方法 ···········································································180
6.3.1 測試方法 ···················································································· 180 6.3.2 物相分析 ··················································································· 182
6.4 重熔涂層的顯微組織與元素分布 ··························································· 185
6.4.1 火焰噴涂 ··················································································· 185
6.4.2 火焰重熔 ··················································································· 187
6.4.3 激光重熔 ··················································································· 194
6.4.4 感應重熔 ··················································································· 197
6.4.5 小結 ························································································· 201
6.5 重熔涂層的顯微硬度 ·········································································· 202
6.5.1 火焰重熔層的顯微硬度 ································································· 202
6.5.2 激光重熔層的顯微硬度 ································································· 203
6.5.3 感應重熔層的顯微硬度 ································································· 203
6.6 重熔涂層的高溫腐蝕特性 ···································································· 204
6.7 二次重熔工藝對比 ············································································· 210
6.8 感應重熔涂層的工程應用 ···································································· 212
參考文獻 ································································································ 216
7 垃圾焚燒鍋爐的防腐優(yōu)化設計及應用 ·················································· 219
7.1 高參數(shù)余熱鍋爐防腐設計現(xiàn)狀及趨勢 ····················································· 219
7.1.1 主蒸汽參數(shù)對防腐設計的影響 ························································ 219
7.1.2 綜合經(jīng)濟效益分析 ······································································· 226
7.2 典型垃圾焚燒鍋爐防腐工程應用案例及分析 ············································ 228
7.2.1 我國南部某垃圾焚燒發(fā)電項目 ························································ 228
7.2.2 我國北部某垃圾焚燒發(fā)電項目 ························································ 257
參考文獻 ································································································ 273
后記 ································································································· 276
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