一.靜電除(chu)塵(chen)器面(mian)臨的形勢
在(zai)(zai)工(gong)(gong)(gong)業(ye)塵(chen)(chen)(chen)(chen)(chen)源治理(li)的多種除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)設(she)備(bei)中,上(shang)世(shi)紀(ji)初發展起來的靜電(dian)(dian)(dian)除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)器(qi),由于其(qi)(qi)除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)效(xiao)率較(jiao)高、運行費用(yong)低、維護(hu)管理(li)簡單(dan)方便等優(you)點,使(shi)其(qi)(qi)在(zai)(zai)除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)領域中廣泛的應用(yong),大(da)(da)規模的除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)幾乎都(dou)采用(yong)了(le)電(dian)(dian)(dian)除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen),據(ju)早期統計水泥(ni)窯用(yong)的除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)設(she)備(bei)80%以上(shang)為電(dian)(dian)(dian)除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)器(qi)。但由于當時的排(pai)放(fang)(fang)標(biao)準要(yao)求較(jiao)低,設(she)計排(pai)放(fang)(fang)標(biao)準為50~100mg/Nm?,已不(bu)(bu)能(neng)滿(man)足環保新要(yao)求,即一般(ban)地(di)區(qu)水泥(ni)窯粉塵(chen)(chen)(chen)(chen)(chen)排(pai)放(fang)(fang)要(yao)求降到(dao)30mg/Nm?以下(xia),地(di)區(qu)要(yao)求降到(dao)20mg/Nm?以下(xia)。據(ju)2010年數(shu)據(ju)統計,水泥(ni)工(gong)(gong)(gong)業(ye)產業(ye)的粉塵(chen)(chen)(chen)(chen)(chen)排(pai)放(fang)(fang)占到(dao)工(gong)(gong)(gong)業(ye)生產總排(pai)放(fang)(fang)量的31.7%,給生態環境帶來巨大(da)(da)壓力。而且,目前電(dian)(dian)(dian)除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)所(suo)用(yong)的高壓電(dian)(dian)(dian)源一般(ban)為工(gong)(gong)(gong)頻(pin)電(dian)(dian)(dian)源、高頻(pin)電(dian)(dian)(dian)源或恒(heng)流電(dian)(dian)(dian)源,其(qi)(qi)不(bu)(bu)僅能(neng)耗(hao)�������大(da)(da),還產生火花放(fang)(fang)電(dian)(dian)(dian)對(dui)除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)器(qi)本體造成電(dian)(dian)(dian)腐蝕,衰(shuai)減除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)效(xiao)率,縮短(duan)使(shi)用(yong)壽命。所(suo)以,水泥(ni)廠窯頭窯尾除(chu)(chu)(chu)(chu)塵(chen)(chen)(chen)(chen)(chen)器(qi)的提效(xiao)改造勢在(zai)(zai)必行。
二.靜電除塵器技(ji)術方案
隨(sui)著環(huan)境意識(shi)和(he)排放(fang)標(biao)準(zhun)的(de)(de)大(da)幅度提高(gao)(gao),原靜電(dian)(dian)除(chu)塵(chen)器性(xing)能難以(yi)滿(man)(man)足(zu)(zu)環(huan)保要(yao)(yao)求,一(yi)時期(�����qi)曾出現(xian)由(you)靜電(dian)(dian)除(chu)塵(chen)轉為布袋(dai)(dai)或電(dian)(dian)袋(dai)(dai)除(chu)塵(chen)方式的(de)(de)傾向。布袋(dai)(dai)及(ji)電(dian)(dian)袋(dai)(dai)除(chu)塵(chen)器雖然能基(ji)本滿(man)(man)足(zu)(zu)目前環(huan)保達標(biao)的(de)(de)基(ji)本需(xu)要(yao)(yao),但(dan)由(you)于其阻力大(da)、電(dian)(dian)耗(hao)高(gao)(gao)、運轉費用高(gao)(gao)、故障率高(gao)(gao)、維護管理不方便、二次污(wu)染等(deng)弱點(dian),只能作(zuo)為范圍內的(de)(de)不得(de)已的(de)(de)選擇。而且,由(you)于其難以(yi)濾掉(diao)微細粉塵(chen)和(he)效果難以(yi)長期(qi)穩定的(de)(de)固有(you)缺陷,已滿(man)(man)足(zu)(zu)不了地區(qu)的(de)(de)≤10mg/Nm?及(ji)“超低排放(fang)”的(de)(de)≤5mg/Nm?的(de)(de)粉塵(chen)排放(fang)新要(yao)(yao)求。
煙溫對設備的影響
煙溫高(gao)于160℃時會顯著降(jiang)低濾(lv)(lv)袋壽(shou)命,如持(chi)續則濾(lv)(lv������)袋將短(duan)時間內燒毀并(bing)破損。當鍋爐出現爆管(guan)時由于前級沒有電除塵器,濾(lv)(lv)袋影響較大。尤(you)其是(shi)不(bu)允許(xu)除塵器采(cai)用旁路������(lu),將對(dui)濾(lv)(lv)袋壽(shou)命帶來較大考驗。
煙(yan)溫高于160℃時會(hui)顯著降(jiang)低濾袋(dai)壽命,如持(chi)續則濾袋(dai)將短(duan)時間(jian)內(nei)燒毀并破損。當(dang)鍋爐出現爆管時由于前級(j������i)有電�������除塵器,濾袋(dai)影(ying)響較小(xiao)。尤其是不允許除塵器采用旁路(lu),將對濾袋(dai)壽命帶來較大考(kao)驗。
高煙溫(wen)對除塵������效率略有影(ying)響,但設備整(zheng)體(ti)對高溫(wen)煙氣承受(shou)能(ne��������ng)力強,同時對除塵器使用壽命沒有影(ying)響。
可(ke)以(yi)看出,在(zai)阻力(li)、電(dian)耗、運轉費(fei)用(yong)、故障率、維(wei)護(hu)管理、二(er)次污染等方面(mian),“靜電(dian)除(chu)(chu)塵”��������遠優(you)于(yu)“布袋(d������ai)除(chu)(chu)塵”。 近(jin)年(nian)興起的(de)“濕式電(dian)除(chu)(chu)塵”、“超凈電(dian)袋(dai)”、“旋轉陽極(ji)板”、“徑流式電(dian)除(chu)(chu)塵器”、“煙(yan)氣調質或微顆粒凝聚”、“本體擴容”等技術,由于(yu)空(kong)間、成本、運行維(wei)護(hu)費(fei)用(yong)、穩定性(xing)、二(er)次污染、適(shi)用(yong)條件(jian)、實際效果等局(ju)限,難以(yi)普(pu)及(ji)(ji),不(bu)適(shi)合水泥(ni)行業使用(yong)。所(suo)以(yi),除(chu)(chu)塵電(dian)源及(ji)(ji)其控制系(xi)統的(de)技術性(xing)能(neng)突破就成為除(chu)(chu)塵領域期待的(de)聚焦點(dian)。
三.除塵電源的選擇
近年(nian),在改進電(dian)(dian)源(yuan)供電(dian)(dian)方式的(de)過程中,設計(ji)思(si)路(lu),電(dian)(dian)源(yuan)性能不(bu)斷提升。市場上除了正(zheng)在淘(tao)汰的(de)“工頻電(dian)(dian)源(yuan)”及其過渡性的(de)“三相(xiang)電(dian)(dian)源(yuan)”外(wai),有“高頻”、“脈(mo)沖&rdqu��o;、“臨界脈(mo)沖”等新型電(dian)(dian)�����源(yuan)。
3.1 工頻(pin)電源技術(shu)特點
單相(xiang)工頻整流電源采用單相(xiang)380V 交流輸入(ru)、工頻變壓(ya)(ya)器升壓(ya)(ya)、高壓(ya)(ya)硅(gui)堆整流成(cheng)100Hz 的脈動(dong)(dong)直(zhi)流電源。由于單相(xiang)電源輸入(ru)功率(lv)因數低、諧波大、輸出脈動(dong)(dong)成(cheng)分大、除塵效果差、電能(neng)消耗高,逐步被淘汰������。
1) 工頻(pin)電源供電形式的優點:
(1) 工頻電源結構簡(jian)單技術成熟;
(2) 造價低。
2) 工(gong)頻(pin)電源(yuan)供(gong)電形式的缺點(dian):
(1) 諧波大、輸出(chu)脈動成分大(理論為57.11%),除塵(chen)效率低;
(2) 功率(lv)因數低(di),電耗(hao)高;
(3) 單相(xiang)整(zheng)流(liu)造成供電不平衡(heng);
(4) 由于火花放電,對本體造成電腐(fu)蝕,除塵效率(lv)衰減快(k��������������uai),使(shi)用壽命短縮。
3.2 三相電源(yuan)技術特點
三(san)相(xiang)(xiang)(xiang)(xiang)整流電(dian)(dian)(dian)(dian)源(yuan)是(shi)采用(yong)(yong)三(san)相(xiang)(xiang)(xiang)(xiang)380V 交流輸入(ru)、工頻變壓器升壓、高(gao)壓硅(gui)堆(dui)整流成300Hz的(de)(de)脈(mo)(mo)(mo)動(dong)直(zhi)流電(dian)(dian)(dian)(dian)源(yuan)。三(san)相(xiang)(xiang)(xiang)(xiang)電(dian)(dian)(dian)(dian)壓經過一(yi)個同(tong)步(bu)檢(jian)測電(dian)(dian)(dian)(dian)路后輸出同(tong)相(xiang)(xiang)(xiang)(xiang)位的(de)(de)三(san)相(xiang)(xiang)(xiang)(xiang)同(tong)步(bu)波形,主電(dian)(dian)(dian)(dian)路可控硅(gui)的(de)(de)六(liu)路觸(chu)發脈(mo)(mo)(mo)沖就(jiu)是(shi)通過該(gai)同(tong)步(bu)波形過零點的(de)(de)判斷(duan)產生的(de)(de)。三(san)相(xiang)(xiang)(xiang)(xiang)電(dian)(dian)(dian)(dian)源(yuan)用(yong)(yong)到(dao)了6個反向并聯可控硅(gui)進行調壓,這(zhe)6����個可控硅(gui)按照1→2→3→4→5→6→1觸(chu)發信(xin)號依次相(xiang)(xiang)(xiang)(xiang)差60°,三(san)相(xiang)(xiang)(xiang)(xiang)電(dian)(dian)(dian)(dian)源(yuan)采用(yong)(yong)寬于(yu)(yu)60°的(de)(de)寬脈(mo)(mo)(mo)沖或雙窄脈(mo)(mo)(mo)沖觸(chu)發,采用(yong)(yong)各相(xiang)(xiang)(xiang)(xiang)同(tong)步(bu)信(xin)號的(de)(de)“過零點”作為控制角計算的(de)(de)基準點。三(san)相(xiang)(xiang)(xiang)(xiang)電(dian)(dian)(dian)(dian)源(yuan)屬(shu)于(yu)(yu)過渡性電(dian)(dian)(dian)(dian)源(yuan),由(you)于(yu)(yu)其除塵(chen)效率(lv)不高(gao)且在減排模式下電(dian)(dian)(dian)(dian)耗過高(gao),以逐步(bu)淘汰。
1) 三相(xiang)工頻電(dian)源供(gong)電(dian)形式的優點:
(1) 三相平(ping)衡,對(dui)電(dian)網污染減少(shao);
(2) 電壓脈動(dong)小(電壓時理論為(wei)4.74%),平均(jun��������������)場強(qiang)有(you)所提高(gao);
(3) 功率因數(shu)接近90%,在同(ton������g)樣二次電(dian)壓(ya)、電(dian)流的輸出情(qing)況下,比工頻電(dian)源節電(dian)������。
2) 三相工頻電源供電形式(shi)的缺點(dian):
������(1) 三(san)相電源閃(shan)絡沖擊(ji)大(da),閃(shan)絡后要關斷多個半(ban)波,除塵效率(�����lv)低;
(2) 為提高除塵效率,電流很大,電耗大幅度增加;
(3) 由于火花放電,對(dui)本體造成電腐(fu)蝕,除塵效率衰減快,使用壽命短縮。
3.3 高頻(pin)電源技術特點(dian)
高頻(pin)(pin)(pin)電源輸入(ru)三(san)相380v/50Hz交流(liu)(liu)(liu)電源,經(jing)三(san)相整(zheng)流(liu)(liu)(liu)濾波(bo)和(he)IGBT模塊(kuai)構(gou)成的高頻(pin)(pin)(pin)逆(ni)變(bian)(bian)(20~50KHz)、高頻(pin)(pin)(pin)變(bian)(bian)������壓整(zheng)流(liu)(liu)(liu)后,經(jing)限流(liu)(liu)(liu)電阻R0供給(gei)(gei)ESP極(ji)板(ban)。輸出電流(liu)(liu)(liu)、電壓、反饋(kui)至控(kong)制系統改變(bian)(bian)脈沖工作頻(pin)(pin)(pin)率�����或(huo)脈沖寬(kuan)度經(jing)隔離(li)驅(qu)動器(qi)(qi)送給(gei)(gei)IGBT全(quan)橋高頻(pin)(pin)(pin)逆(ni)變(bian)(bian)器(qi)(qi)以對輸出電流(liu)(liu)(liu)輸出電壓進行調(diao)節。
1)高頻電源的優點:
(1)電(dian)場(chang)(chang)擊(ji)穿(�������chuan)(chuan)后恢(hui)復快,工頻(pin)電(dian)源從電(dian)場(chang)(chang)擊(ji)穿(chuan)(chuan)到電(dian)場(chang)(chang)恢(hui)復約需(xu)(xu)要(yao)80ms,高頻(pin)電(dian)源從電(dian)場(chang)(chang)擊(ji)穿(chuan)���(chuan)到電(dian)場(chang)(chang)恢(hui)復約需(xu)(xu)要(yao)20ms;
(2) 由于采用高頻電力電子技術,使功率(lv)因數大幅度(du)提(ti)高,在(zai)不考(kao)慮減排(pai)的��������情(qing)況下,可實現大幅度(du)節(jie)能;
(3) 控(kong)制方式靈活、體積小、重量輕。
2)高頻電源的(de)缺(que)點:
(1) 高頻(pin)高�����壓電(dian)(dian)源的(de)(de)控制模式是以檢測火(huo)花為(wei)前提的(de)(de)。在檢測到火(huo)花后,通(tong)過(guo)(guo)較(jiao)大(da)幅度降壓供電(dian)(dian)或較(jiao)短時間內(nei)停止(zhi)供電(dian)(dian)的(de)(de)方式火(huo)花,超過(guo)(guo)火(huo)花電(dian)(dian)壓的(de)(de)部(bu)分電(dian�����)(dian)能全部(bu)浪費,低于(yu)火(huo)花電(dian)(dian)壓的(de)(de)部(bu)分無法(fa)全部(bu)荷電(dian)(dian),“無效”比例較(jiao)大(da);
(2) 平均場強遠低于(yu)火(huo)花(hua)始發點的臨(lin)界電壓(ya),荷電與(yu)驅(qu)進(jin)�����能力較差;
(3) 為減排,盡可能地向(xiang)電場輸(shu)入能量(liang),�����造成電能浪(lang)費;
(4) 由于火花放電(dian)對極線和極板(ban)產生電(dian)腐蝕,使電(dian)除(chu)塵(chen)器效率衰(shuai)減較快,不僅(�����jin)影響除(chu)塵(chen)效果,也造成除(chu)塵(chen)器本�������體(ti)維護費用的(de)增加。
3.4 脈沖電源技術特點
脈(mo)沖(chong)(chong)(chong)(chong)電(dian)(dian)(dian)源(yuan)是混合供(gong)電(dian)(dian)(dian)模式,即是指在(zai)靜電(dian)(dian)(dian)除(chu)塵(chen)器直(zhi)流供(gong)電(dian)(dian)(dian)的基(ji)(ji)礎上疊加高(gao)頻脈(mo)沖(chong)(chong)(chong)(chong)電(dian)(dian)(dian)壓(ya)。主要由基(ji)(ji)礎電(dian)(dian)(dian)壓(ya)調節電(dian)(dian)(dian)路(lu)(lu)、脈(mo)沖(chong)(chong)(chong)(chong)產生電(dian)(dian)(dian)路(lu)(lu)、保護電(dian)(dian)(dian)路(lu)(lu)、脈(mo)沖(chong)(chong)(chong)(chong)幅值調節電(dian)(dian)(dian)路(lu)(lu)等組成。由脈(mo)沖(chong)(chong)(chong)(chong)電(dian)(dian)(dian)路(lu)(lu)構成的脈(mo)沖(chong)(chong)(chong)(chong)電(dian)(dian)(dian)源(yuan)通過耦合電(dian)(dian)(dian)容一同輸出到(dao)靜電(dian)(dian)(dian)除(chu)塵(chen)器的電(dian)(dian)(dian)場(chang)進(jin)行除(chu)塵(chen)。瞬間高(gao)電(dian)(dian)(dian)壓(ya)輸出,提(ti)高(gao)了(le)電(dian)(dian)(dian)場(chang)場(chang)強和電(dian)(dian)(dian)暈功率(lv),提(ti)高(gao)了(le)除(chu)塵(chen)效率(lv)。而且,由于作為基(ji)(ji)礎直(zhi)流電(dian)(dian)(dian)壓(ya)設定在(zai)火花(hua)始發點以下,������也(ye)降低了(le)除(chu)塵(chen)時電(dian)(dian)(dian)能消(xiao)耗(hao)。
1)脈(mo)沖電源的優(you)點:
(1) 脈沖(chong)電(dian������)壓上升沿小������,持續時(shi)間(jian)短,不易觸發閃絡,地提高了場強(qiang);
(2) 如果本體極配(pei),脈(mo)沖電壓(ya)幅(fu)值匹����(pi)配(pei),可提(ti)高(gao)空(kong)間自由(you)離子密度,提(ti)高(gao)粉塵的荷電效率;
(3) 采用間(jian)(jian)歇脈(mo)沖(chong)�����供�������電技術來克服高(gao)比(bi)電阻(zu)粉塵(chen)引起的反電暈(yun),根據(ju)工況(kuang)條件變化自(zi)動選擇工作方式(選擇間(jian)(jian)歇脈(mo)沖(chong)供電的占空(kong)比(bi))、自(zi)動選擇運行參(can)數,可以提(ti)高(gao)除(chu)塵(chen)效率而且還(huan)可以較大幅度節約電能(neng)。
2)脈沖電源(yuan)的(de)缺點:
(1) 其在大功(gong)率(lv)連續工作狀態下,易損�����毀,抗浪涌電(dian)壓和(he)有待(dai)商(shang)榷,后續維護費用很高;
(2) 初(chu)期投資太(tai)高;
(3) 在������國內(nei)尚無大型�������電(dian)廠應用(yong)實際成(cheng)功(gong)案例。
3.5 臨界脈沖電源技術特點
臨界(jie)脈(mo)(mo)沖(chong)電(dian)源(yuan)是將380V三(san)相(xiang)交流(liu)電(dian)經整流(liu)濾波成直流(liu),再(zai)逆變(bian)為高(gao)頻交流(liu),經高(gao)頻變(bian)壓器(qi)�����升壓后,再(zai)經&��ldquo;臨界(jie)柔性模(mo)塊”變(bian)為帶有微小脈(mo)(mo)動的平穩(wen)直流(liu)。航天電(dian)控公司在行業(ye)內提出“空間自由離子密(mi)度對除(chu)塵(chen)效率的影響遠大(da)于場強”的理論(lun)并進行了量化(hua),提出“臨界(jie)區”的概念并量化(hua)應用。臨界(jie)脈(mo)(mo)沖(chong)電(dian)源(yuan)突破了現有工(gong)頻(單相(xiang)、三(san)相(xiang))、高(gao)頻及脈(mo)(mo)沖(chong)除(chu)塵(chen)電(dian)源(yuan)增效節能的瓶頸,實現了大(da)幅度(70%以(yi)上)減排的同時(shi)大(da)幅度(30~80%)節能,并避免了火(huo)花放電(dian)產生的電(dian)腐蝕從而使本(ben)體性能長期穩(wen)定運行。
3.5.1 臨界脈沖電源的基本原理(li)
臨界脈(mo)沖電(dian)源采用“硬件儲能(neng)與限(xian)能(neng)、軟件監視電(dian)壓變化(hua)趨(qu)勢”的(de)控制方式,從能(neng)量(liang)梯度(du)控制入手,使工作點(dian)保持(chi)在空氣放(fang)電(dian)特(te)性(xing)曲(qu)線的(de)較高點(dian)及其的(de)右(you)側很小的(de)區域內(nei)。體現(xian)“可變內(nei)阻”特(te)性(xing),即,“限(xian)能(neng)”流注生(������sheng)長,避免產生(sheng)火花(hua)放(fang)電(dian)。同時,“儲�����能(neng)”以保持(chi)高電(dian)壓。
3.5.2 臨界脈沖電源的技(ji)術特(te)點:
(1)具有(you)節能和長(chang)期穩定的(de)本質
① 臨(lin)界(jie)脈沖(柔)特性:
臨界(jie)脈沖(chong)電(dian)(dian)(dian)源具(ju)有“硬件(jian)儲能與限(xian)能”和“微脈沖(chong)” 式供(gong)電(dian)(dian)(dian)特性(xing),輸(shu)出(chu)的(de)電(dian)(dian)(dian)壓(ya)隨著(zhu)工況(電(dian)(dian)(dian)場內溫度、濕度、壓(ya)力(li)、粉(fen)塵(chen)濃度、粒度、比電(dian)(dian)(dian)阻以及市電(dian)(dian)(dian)波動(dong))的(de)變(bian)化,自動(dong)調節動(dong)態適應,使輸(shu)出(chu)電(dian)(dian)(dian)����壓(ya)值(zhi)穩(wen)定(ding)位(wei)于火花始發點以下臨界(jie)區。
無須(xu)大幅降壓或關斷(duan)以熄(xi)滅(mie)火(huo)花,連續輸出臨界電壓,可實現理想的(de)也是運行中(zhong)較高的(de)場強(qiang)(荷(he)電場強(qiang)、驅進場強(�������qiang))。
使電(dian)場保(bao)持(chi)在(za����i)“二(er)次電(dian)子崩”與“流注初期(qi)”狀態(tai),空間自由離子密度(����du)較(jiao)大,荷電(dian)效(xiao)率較(jiao)高。
其工作電壓如下圖所示:
② 高電(dian)壓低(di)電(dian)流������:在使電(dian)壓保持在臨界區的同時(shi�������),避免了大量(liang)的無效電(dian)耗,實現小電(dian)流供(gong)電(dian)。而且,采用(yong)高頻(pin)技術功率因數高。
③ 避(bi)免電(dian)腐蝕(shi):由于(yu)臨界脈沖電(dian)源技術在供電(dian)過程都處于(yu)無火花(hua������)放電(dian)狀態,避(bi)免了對除塵器本體極(ji)(ji)線(xian)、極(ji)(ji)板的電(dian)腐蝕(shi)。
臨界脈(mo)沖電源的(de)提效節能示意圖如下:
(2)集塵
① 場強:平均輸出(chu)(chu)電壓(ya)越高,電場越強,則荷電場強和驅進(集塵(chen))場強越大(da)。使輸出(chu)(chu)電壓(ya)一致保持在“臨界(jie)區”(靜(jing)態�����火花始發臨界(jie)線及(ji)其(qi)下(xia)面的3%以內的區域(yu)),可實現理想的也是運行中較(jiao)高的場強。
② 空間(jian)(jian)自(zi)由離(li)子:煙(yan)塵通過(guo)的空間(jian)(jian),自(zi)由離(li)子越多(duo),則(ze)荷電(dian)(dian)(dian)時間(jian)(jian)常數越短(duan),荷電(dian)(dian)(dian)速度(du)越快。使(shi)電(di������an)(dian)(dian)場(chang)保持(chi)在“二次電(dian)(dian)(dian)子崩”與“流注初期”狀態,可實現(xian)空間(jian)(jian)自(zi)由電(dian)(dian)(dian)荷多(duo),荷電��������(dian)(dian)(dian)效率較高。
③ 電(dian)(dian)暈(yun)封(feng)閉:高(gao)(gao)場強和高(gao)(gao)空間自由氣體離子密度(du),使電(dian)(dian)暈(yun)放電(dian)(dian)能力保(bao)持狀態(tai)而且,由于電(dian)(dian)流較小,減少(shao)了同量大顆粒粉塵的多余荷(he)電(dian)(dian)量,電(dian)(dian)暈(yu�������n)封(feng)閉。
④ “Z”字型運動������:低比電阻粉(fen)塵(chen)離開極板后,由(you)于空間自由(you)氣體離子密(mi)度高,再次荷電,利于集塵(c������hen)。
(3)反電暈
反(fan)(fan)電(dian)(dian)暈(yun)機理:當陽極(ji)(ji)板(ban)(ban)灰積到厚度時(shi),比電(dian)(dian)阻高的(de)(de)灰在荷電(dian)(dian)后的(de)(de)負離(li)子向除塵器陽極(ji)(ji)板(ban)(ban)趨近過程(cheng)中,其荷電(dian)(dian)不容(rong)易釋放到陽極(ji)(ji)板(ban)(ban),負離(li)子逐漸積累到陽極(ji)(ji)板(ban)(ban)表面,與(yu)(yu)陽極(ji)(ji)板(ban)(ban)形(xing)成(cheng)類似電(dian)(dian)容(rong)的(de)(de)電(dian)(dian)場(chang),這個電(dian)(dian)場(chang)將(jiang)抵消主電(dian)(dian)場(chang),降(jiang)低除塵效果;如果電(dian)(dian)場(chang)強度進一步(bu)加強后,這個電(dian)(dian)場(chang)將(jiang)局部擊穿激發出反(fan)(fan)向正離(li)子向陰極(ji)(ji)線遷(qian)移,造成(cheng)除塵器電(dian)(dian)流(liu)增大(da),但消耗的(de)(de)電(dian)(dian)能沒(mei)有起到吸(xi)塵作用,這種現象就(jiu)是(shi)反(fan)(fan)電(dian)(dian)暈(yun)現象。振打(da)周期內集塵層(ceng)所(suo)帶的(de)(de)電(dian)(dian)荷是(shi)動態(tai)的(de)(de),取決于(yu)釋放到陽極(ji)(ji)的(de)(de)電(dian)(dian)量(liang)與(yu)(yu)重新荷電(dian)(dian)電(dian)(dian)量(liang)的(de)(de)差值,供電(dian)(dian)電(dian)(dian)流(liu)越小,則越有利于(yu)反(fan)(fan)電(dian)(dian)暈(yun)。所(s������uo)謂“脈沖式供電(dian)(dian)反(fan)(fan)電(dian)(dian)暈(yun)”,其實質(zhi)就(jiu)是(shi)平均電(dian)(dian)流(liu)較(jiao)小。
解決方案:低電流
① 平均后(hou)續荷電電流(liu)小于(yu)荷電后(hou)的灰塵(chen)(chen)放(fan�������g)電電流(liu),使陽極(ji)板上粉塵(chen)(chen)積層的再次(ci)荷電量小于(yu)釋放(fang)電量,降低了粉塵(chen)(chen)層在極(ji)板上的電荷積�������累。
② 平均再荷(h�������e)電電流等(deng)于或略大(da)于荷(he)電后������的灰塵(chen)放電電流,但到下次(ci)振(zhen)打為止,粉塵(chen)層電量的積累不足(zu)以(yi)產(chan)生反電暈。
(4)減少二次揚塵
① 降低了粉塵(chen)(chen)層對極(ji)板的吸引力(li),易振打脫落,在振打力(li)度(du)可調(diao)(如電磁振打)的情況(kuang)下,可適當(dang)降低振打力(li)度(������du),減(jian)少二次揚(yang)塵(chen)(chen)。
② 不必斷電或(huo)減壓振打,保持高場強集塵狀態,則二次揚塵。
③ 避免(mian)火(huo)花放(fa�����ng)電,減(jian)少������因火(huo)花擊穿(chuan)而造成的擾動二次揚塵。
(5)大幅度節能
一、二(er)電(dian)(dian)(dian������)(dian)(dian)(dian)(dian)(dian)場(chang),粉(fen)塵(chen)濃(nong)(nong)度高(gao),粒徑較大,粉(fen)塵(chen)荷電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)用電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)量(liang)也相應增加(jia)。但粉(fen)塵(chen)荷電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)用電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)量(liang)不(bu)足(zu)目前(qian)傳統電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)源耗電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)的(de)(de)2%,對電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)除塵(chen)總耗電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)量(liang)基本(ben)沒有影響。但高(gao)濃(nong)(nong)度的(de)(de)荷電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)粉(fen)塵(chen)會使(shi)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)場(chang)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)阻(zu)變小(xiao)(xiao),其它電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)源,為實(shi)現較高(gao)場(chang)強,被(bei)迫(po)輸(shu)(shu)出了較大電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)流(liu)。從表面(mian)現象看,確實(shi)注入了較多能量(liang)。但電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)流(liu)越(yue)大,造成(cheng)(cheng)(cheng)局(ju)部火花(hua)(hua)放(fang)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)越(yue)多,通過粉(fen)塵(chen)而傳導的(de)(de)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)量(liang)也越(yue)大,形成(cheng)(cheng)(cheng)浪(lang)費。火花(hua)(hua)放(fang)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian),時間占比(bi)很小(xiao)(xiao),但消(xiao)耗能量(liang)巨大。火花(hua)(hua)放(fang)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)始發(fa)點與(yu)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)場(chang)介(jie)質(zhi)相關(guan),粉(fen)塵(chen)濃(nong)(nong)度高(gao),更(geng)易閃落,這也是造成(cheng)(cheng)(cheng)“一、二(er)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)場(chang)輸(shu)(shu)入很量(liang)”的(de)(de)原(yuan)因(yin)。臨(lin)界脈(mo)沖電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)源避(bi)免了火花(hua)(hua)放(fang)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)(全貫穿火花(hua)(hua)放(fang)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)和局(ju)部火花(hua)(hua)放(fang)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)),大幅度節(jie)電(dian)(dian)(dian)(dian)(dian)(dian)(dian)(dian)。
綜上所述(shu),而臨界脈(mo)沖電源(yuan)技術(shu)在這些(xie)重要方面實現了革命性的(de�����)突破,目(mu)前(qian)是世界上減排(pai)效果較強同時節能(neng)幅度較大的(de)電源(yuan),是超凈排(pai)放中(zhong)電源(yuan)的(de)理想選擇。今后將除�������塵電源(yuan)技術(shu)發展方向。
English
