1) Dehydrocyclization
脱氢环合
2) dehydrogenation
脱氢
1.
High-temperature sensible heat recovery technology for effluent from ethylbenzene dehydrogenation unit;
乙苯脱氢制苯乙烯反应出料高温显热回收技术
2.
Preparation and characterization of Pt-Sn-Li/Al_2O_3/FeCrAl catalyst and its catalytic performance for long chain alkane dehydrogenation;
Pt-Sn-Li/Al_2O_3/FeCrAl催化剂的制备、表征和长链烷烃脱氢催化性能
3.
Effect of Preparation Methods on the Performance of Cr/Si-2 Catalysts during the Dehydrogenation of Ethane to Ethylene with CO_2;
制备方法对Cr/Si-2催化剂在CO_2氧化乙烷脱氢制乙烯反应中的催化性能的影响
3) dehydrogenation
氧化脱氢
1.
Synthesis and dehydrogenation of 4-nitro benzoyl acylhydrazines;
对硝基苯甲酰芳肼的合成及氧化脱氢研究
2.
Synthesis of adipic-1′,6′-bis(4-halogenphenyl hydrazine) and its dehydrogenation;
己二酰-1′,6′-双(4-卤苯肼)的合成及其氧化脱氢研究
3.
Synthesis of Adipic-1′,6′-Bis(4-Nitrophenyl Hydrazine) and Its Dehydrogenation;
己二酰-1′,6′-双(4-硝基苯肼)的合成及其氧化脱氢研究
4) ethylbenzene dehydrogenation
乙苯脱氢
1.
Effect of K_2O on forming of KFe_(11)O_(17) in catalyst for ethylbenzene dehydrogenation;
钾含量对乙苯脱氢催化剂中KFe_(11)O_(17)物相形成的影响
2.
Reclaimation of ethylbenzene dehydrogenation tail gas;
乙苯脱氢尾气的回收利用
3.
Effect of calcination condition on the water-tolerant stability of ethylbenzene dehydrogenation catalyst;
焙烧条件对乙苯脱氢催化剂耐水性能影响的研究
5) Oxidative dehydrogenation
氧化脱氢
1.
Catalytic performance of oxidative dehydrogenation of propane to propene over the cobalt oxide/titanium-bearing blast furnace slag catalyst;
氧化钴/高炉渣催化剂的丙烷氧化脱氢性能
2.
Progress in catalytic system of propane oxidative dehydrogenation;
丙烷氧化脱氢反应催化剂体系研究进展
3.
study of oxidative dehydrogenation of C_2H_6 on La_2O_3;
La_2O_3催化剂上乙烷氧化脱氢反应的研究
6) dehydrogenase
脱氢酶
1.
The application of method for measurement of TTC-dehydrogenase activity in dominant bacteria screening of coal coking waste water;
用TTC-脱氢酶活性测定法筛选焦化废水优势菌
2.
The Develop of The Instrument for Measuring TTC-Dehydrogenase Activity;
TTC—脱氢酶活性测定仪的研制
3.
Study on IgG-Glucosedehydrogenase Conjugates;
免疫球蛋白G-葡萄糖脱氢酶结合物的研究
参考词条
补充资料:合环与解环
合环与解环
loop closing and opening
hehuon yu Jlehuon合环与解环(loop elosing and opening)在并列运行的电力系统中,将发电厂或变电所间的输电线路连接成环状网络或将环状网络解开。合环运行能提高电力系统运行的灵活性、经济性、可靠性。可以利用先合环后解环的办法将发电厂或变电所在不解列和不停电的情况下由一个电力网切换到另一个电力网。解环运行常是为了减小电力系统短路容量和满足系统运行方式的要求。 合环若合环点两侧有相位差和电压差,合环后会出现环流,可能引起环路内的电力设备过负荷或使继电保护装置动作而跳闸。在电力系统实际运行中,电压差允许在10%以内(500 kV电网应在5环已内),相位差在5o以内合环即可,但由于系统结构不同,有的系统合环相位差允许100~150。在合环前,对合环环流一般都要进行计算,做模拟或实时工况合环试验,根据计算和试验结果确定合环时允许的相位差和电压差。进行合环操作时,若相位差和电压差不符合允许条件,则必须调整到允许范围内。 解环解环时要尽量减小解环点的有功功率和无功功率,以免解开环网时功率和电压的变化太大,引起电力系统发生异常或故障。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。