化工进展
化工進展
화공진전
CHEMICAL INDUSTRY AND ENGINEERING PROGRESS
2013年
8期
1960-1966,1993
,共8页
王奕雪%宁平%谷俊杰%田森林%关清卿%夏凤高%韦朝海
王奕雪%寧平%穀俊傑%田森林%關清卿%夏鳳高%韋朝海
왕혁설%저평%곡준걸%전삼림%관청경%하봉고%위조해
底泥%褐煤%超临界水%共气化%氢
底泥%褐煤%超臨界水%共氣化%氫
저니%갈매%초림계수%공기화%경
sediment%lignite%supercritical water%co-gasification%hydrogen
采用间歇式超临界水反应装置,以滇池疏浚底泥和褐煤为原料,分别将褐煤、底泥单独进行超临界水气化,对比不同反应原料对气化制氢的影响。再将二者按不同混合比例(1∶9、2∶8、3∶7、4∶6、5∶5)进行共气化,对比不同混合比例对气化制氢的影响。结果表明,相对褐煤,底泥气化具有气体组分富氢、气相收率高、产气量小的特点;褐煤气化则具有碳气化率高、产气量大的特点。褐煤单独气化的气相收率低于底泥,共气化时气相收率达到834 mL/g。褐煤和底泥在超临界水共气化过程中碳气化率和产氢率存在明显协同效应。与加权平均值相比,碳气化率和H2产率分别提高了3.12%和55 mL/g。共气化存在最优比例,超过3∶7后,碳气化率逐渐下降。以最优比例进行共气化,既可达到处置底泥的目的,又可保持相对较高的H2产率(350 mL/g)和CH4产率(113 mL/g)。
採用間歇式超臨界水反應裝置,以滇池疏浚底泥和褐煤為原料,分彆將褐煤、底泥單獨進行超臨界水氣化,對比不同反應原料對氣化製氫的影響。再將二者按不同混閤比例(1∶9、2∶8、3∶7、4∶6、5∶5)進行共氣化,對比不同混閤比例對氣化製氫的影響。結果錶明,相對褐煤,底泥氣化具有氣體組分富氫、氣相收率高、產氣量小的特點;褐煤氣化則具有碳氣化率高、產氣量大的特點。褐煤單獨氣化的氣相收率低于底泥,共氣化時氣相收率達到834 mL/g。褐煤和底泥在超臨界水共氣化過程中碳氣化率和產氫率存在明顯協同效應。與加權平均值相比,碳氣化率和H2產率分彆提高瞭3.12%和55 mL/g。共氣化存在最優比例,超過3∶7後,碳氣化率逐漸下降。以最優比例進行共氣化,既可達到處置底泥的目的,又可保持相對較高的H2產率(350 mL/g)和CH4產率(113 mL/g)。
채용간헐식초림계수반응장치,이전지소준저니화갈매위원료,분별장갈매、저니단독진행초림계수기화,대비불동반응원료대기화제경적영향。재장이자안불동혼합비례(1∶9、2∶8、3∶7、4∶6、5∶5)진행공기화,대비불동혼합비례대기화제경적영향。결과표명,상대갈매,저니기화구유기체조분부경、기상수솔고、산기량소적특점;갈매기화칙구유탄기화솔고、산기량대적특점。갈매단독기화적기상수솔저우저니,공기화시기상수솔체도834 mL/g。갈매화저니재초림계수공기화과정중탄기화솔화산경솔존재명현협동효응。여가권평균치상비,탄기화솔화H2산솔분별제고료3.12%화55 mL/g。공기화존재최우비례,초과3∶7후,탄기화솔축점하강。이최우비례진행공기화,기가체도처치저니적목적,우가보지상대교고적H2산솔(350 mL/g)화CH4산솔(113 mL/g)。
Supercritical water gasification of lignite and sediment (independent and co-gasification) for hydrogen production were investigated in a batch autoclave under different conditions,including different feedstocks. The effect of different mixed ratio,i.e. 1∶9,2∶8,3∶7,4∶6,5∶5,on hydrogen production were also investigated. The results indicated that the gasification of sediment is a process with a rich composition of hydrogen,high recovery of gaseous products but low gasification yields;meanwhile,the gasification of lignite is one with high carbon gasification efficiency and high gasification yields. Although the gaseous yields of lignite gasification were lower than that of sediment,it was increased to 834 mL/g under co-gasification. The obvious synergistic effect on carbon gasification efficiency and hydrogen production were observed in co-gasification process. Carbon gasification efficiency and hydrogen yield were 3.12% and 55 mL/g respectively,higher than that in terms of average value. The optimal ratio existed in co-gasification;when it is beyond 3∶7,carbon gasification efficiency declined. Therefore,co-gasification under optimal ratio not only could achieve effective sediment disposal,but also obtain high gaseous yields about 350 mL/g H2 and 113 mL/g CH4.
