稀有金属材料与工程
稀有金屬材料與工程
희유금속재료여공정
RARE METAL MATERIALS AND ENGINEERNG
2010年
2期
214-218
,共5页
刘守平%邱贵宝%刘小军%李进%白晨光
劉守平%邱貴寶%劉小軍%李進%白晨光
류수평%구귀보%류소군%리진%백신광
贮氢合金%组织结构%电化学性能
貯氫閤金%組織結構%電化學性能
저경합금%조직결구%전화학성능
hydrogen storage alloy%microstructure%electrochemical property
用XRD、SEM等方法与手段,研究TiMn_(2-5x)(V_4Fe)_x(x=0.30,0.35)贮氢合金的相结构及电化学性能.结果表明:主相为体心立方(bcc)结构的合金,其晶胞参数随x的增加而增大;SEM显示在基体中存在岛状结构,随着x的增加,岛状结构较基体的比率减少;电化学测试表明,x=0.35合金在常温下难以活化,加热到327 K才能活化;而x=0.30合金常温下即可活化,该合金在充电过程中出现钝化,327 K温度下钝化消除.比较合金在298 K的PCT曲线,发现x=0.30合金的平台氢压约为0.2 MPa,平台宽度较大,更有开发价值;同时计算x=0.30合金放氢过程的焓和熵,分别为-36.1 kJ/mol,-126.9 J/(mol·K).
用XRD、SEM等方法與手段,研究TiMn_(2-5x)(V_4Fe)_x(x=0.30,0.35)貯氫閤金的相結構及電化學性能.結果錶明:主相為體心立方(bcc)結構的閤金,其晶胞參數隨x的增加而增大;SEM顯示在基體中存在島狀結構,隨著x的增加,島狀結構較基體的比率減少;電化學測試錶明,x=0.35閤金在常溫下難以活化,加熱到327 K纔能活化;而x=0.30閤金常溫下即可活化,該閤金在充電過程中齣現鈍化,327 K溫度下鈍化消除.比較閤金在298 K的PCT麯線,髮現x=0.30閤金的平檯氫壓約為0.2 MPa,平檯寬度較大,更有開髮價值;同時計算x=0.30閤金放氫過程的焓和熵,分彆為-36.1 kJ/mol,-126.9 J/(mol·K).
용XRD、SEM등방법여수단,연구TiMn_(2-5x)(V_4Fe)_x(x=0.30,0.35)저경합금적상결구급전화학성능.결과표명:주상위체심립방(bcc)결구적합금,기정포삼수수x적증가이증대;SEM현시재기체중존재도상결구,수착x적증가,도상결구교기체적비솔감소;전화학측시표명,x=0.35합금재상온하난이활화,가열도327 K재능활화;이x=0.30합금상온하즉가활화,해합금재충전과정중출현둔화,327 K온도하둔화소제.비교합금재298 K적PCT곡선,발현x=0.30합금적평태경압약위0.2 MPa,평태관도교대,경유개발개치;동시계산x=0.30합금방경과정적함화적,분별위-36.1 kJ/mol,-126.9 J/(mol·K).
Structures and electrochemical properties of TiMn_(2-5x)(V_4Fe)_x(x=0.30,0.35)alloys were investigated. The results of XRD analysis show that the alloys are mainly composed of body centered cubic (bcc) phase, whose lattice parameters are enhanced with the increase of V and Fe content. The SEM images of the alloys show that there are some colonies in the matrix phase. The proportion of colony to the matrix decreases with increasing of V and Fe content. The electrochemical measurements show that TiMn_(0.25)(V_4Fe)_(0.35) alloy has unfavorable activation performance until temperature reaches 327 K, while TiMn_(0.50)(V_4Fe)_(0.30) alloy shows better activation performance, but passivation phenomenon was found in the process of charging at low temperature, which can be eliminated by heating to high temperature. The PCT curves of alloys show that the TiMn_(0.50)(V_4Fe)_(0.30) alloy has a good comprehensive performance, with a favorable plateau pressure at room temperature and wide plateau. The enthalpy and entropy in hydrogen desorption of TiMn_(0.50)(V_4Fe)_(0..30) alloy were also calculated and they are -36.1 kJ/mol, -126.9 J/(mol·K), respectively.