功能材料
功能材料
공능재료
JOURNAL OF FUNCTIONAL MATERIALS
2013年
20期
3045-3048
,共4页
张同环%周仕学%王德玺%贺炳慧%储慧超%田敏
張同環%週仕學%王德璽%賀炳慧%儲慧超%田敏
장동배%주사학%왕덕새%하병혜%저혜초%전민
Mg%储氢材料%烟煤%粘结%吸氢动力学
Mg%儲氫材料%煙煤%粘結%吸氫動力學
Mg%저경재료%연매%점결%흡경동역학
magnesium%hydrogen storage material%bituminous coal%binder%hydrogenation kinetics
以Mg、烟煤和碳化无烟煤为原料,经 H 2反应球磨、热处理制备了烟煤粘结的纳米镁基储氢材料,研究了储氢材料结构及吸放氢性能,并计算了材料的吸氢动力学参数。结果表明,在600℃热处理时材料中的Mg容易与煤中的 C 发生反应生成 Mg2 C3;添加15%(质量分数)烟煤,经500℃热处理能有效粘结纳米Mg颗粒,且未见Mg2 C3生成。储氢材料的吸氢速率随温度升高而增大,在2MPa H2下吸氢量在350℃达到最大值,约3.77%(质量分数),在400℃时吸氢量略有下降。根据 Arrhenius 公式得出储氢材料在300~350℃下吸氢的一级反应表观活化能为56.6kJ/mol H 2。用TPD测定了储氢材料的放氢温度,表明材料在250℃开始放氢,388℃时达到放氢高峰。储氢材料中的C 可结合少量 H,该类 H 在加热时会以 CH4等烃的形式释放出来。
以Mg、煙煤和碳化無煙煤為原料,經 H 2反應毬磨、熱處理製備瞭煙煤粘結的納米鎂基儲氫材料,研究瞭儲氫材料結構及吸放氫性能,併計算瞭材料的吸氫動力學參數。結果錶明,在600℃熱處理時材料中的Mg容易與煤中的 C 髮生反應生成 Mg2 C3;添加15%(質量分數)煙煤,經500℃熱處理能有效粘結納米Mg顆粒,且未見Mg2 C3生成。儲氫材料的吸氫速率隨溫度升高而增大,在2MPa H2下吸氫量在350℃達到最大值,約3.77%(質量分數),在400℃時吸氫量略有下降。根據 Arrhenius 公式得齣儲氫材料在300~350℃下吸氫的一級反應錶觀活化能為56.6kJ/mol H 2。用TPD測定瞭儲氫材料的放氫溫度,錶明材料在250℃開始放氫,388℃時達到放氫高峰。儲氫材料中的C 可結閤少量 H,該類 H 在加熱時會以 CH4等烴的形式釋放齣來。
이Mg、연매화탄화무연매위원료,경 H 2반응구마、열처리제비료연매점결적납미미기저경재료,연구료저경재료결구급흡방경성능,병계산료재료적흡경동역학삼수。결과표명,재600℃열처리시재료중적Mg용역여매중적 C 발생반응생성 Mg2 C3;첨가15%(질량분수)연매,경500℃열처리능유효점결납미Mg과립,차미견Mg2 C3생성。저경재료적흡경속솔수온도승고이증대,재2MPa H2하흡경량재350℃체도최대치,약3.77%(질량분수),재400℃시흡경량략유하강。근거 Arrhenius 공식득출저경재료재300~350℃하흡경적일급반응표관활화능위56.6kJ/mol H 2。용TPD측정료저경재료적방경온도,표명재료재250℃개시방경,388℃시체도방경고봉。저경재료중적C 가결합소량 H,해류 H 재가열시회이 CH4등경적형식석방출래。
Nanostructured Mg-based hydrogen storage material with bituminous coal as binder and carbonized anthracite coal as milling aid was prepared by hydrogen reaction ball milling and heat treatment.The structure and hydrogen storage properties of the material were investigated,and the hydrogen absorption kinetics param-eter was calculated.Results show that the carbon in the material can react with Mg,and Mg2 C3 was generated when the material gets heat treated at 600℃,while at 500℃ the nano-structured Mg particles are well binded with 15wt% of bituminous coal without the generation of Mg2C3.The hydrogen absorbing rate was enhanced with the increase of temperature,and the hydrogen uptake reached to 3.77wt% at 350℃,2 MPa H2 and a little reduction at 400℃.According to Arrhenius equation,the apparent activation energy for the first order reaction of hydrogen absorbing within 300-350℃ was 56.6kJ/mol H2 .The initial and peak hydrogen desorption temper-atures are 250 and 388℃,respectively.In the hydriding process,the carbon in the material can combine a small amount of hydrogen which can be released in the form of alkane like methane and ethane.