储氢性能,hydrogen storage properties
1)hydrogen storage properties储氢性能
1.Hydrogen storage properties of mechanical milling alloy(Mg+Mg_2Ni)+TiO_2;机械合金化(Mg+Mg_2Ni)+TiO_2合金的储氢性能
2.The research history,preparation technologies and applications of Mg-based hydrogen storage materials in the recent years are expatiated systematically,and the factors affectinghydrogen storage properties of Mg-based hydrogen storage materials are analyzed.对近年来镁基储氢材料的研究开发概况、制备技术以及应用研究等方面进行了系统阐述,分析了影响镁基储氢材料储氢性能的主要因素,总结了采用机械合金化法、储氢合金组元部分替代、添加催化剂制成复合材料及表面改性等方法可以有效改善储氢性能,并对镁基储氢材料研究中存在的问题以及今后的发展方向进行了探讨与展望。
3.The phase structures andhydrogen storage properties of Ti100-x-yVxFey(x=54,49,44;y=5,7.储氢性能测试表明,3种合金的动力学性能均很好,在室温和4MPa初始氢压条件下,无需氢化孕育期就能快速吸氢;经4次~5次吸放氢循环即能活化,仅2min~3min就能吸氢饱和达到最大吸氢量363。
英文短句/例句
1.Synthesis of Mg-based Hydrogen Storage Material and Studies on Hydrogenation Properties;镁基复合储氢材料的制备及气态储氢性能研究
2.Improved Hydrogen Storage Performance of Pure Magnesium by Complex Hydrides;用复合氢化物改善纯镁储氢性能的研究
3.Effects of B and C on Hydrogen Storage Properties of Li-N-H Complex HydridesB和C对Li-N-H络合氢化物储氢性能的影响
4.Research on Hydrogen Storage Characteristics and Phase Composition of TiCr Based Alloys;TiCr基合金的储氢性能及相结构研究
5.Preparation, Characterization and Hydrogen Storage Properties of Mg-based Nanocomposite Particles;镁基纳米粒子的制备、表征及储氢性能
6.Hydrogen Storage Properies of Carbon Mesopore Loading LiAIH_4;介孔炭CMK-3负载LiAIH_4储氢性能研究
7.Research on Hydrogen Storage Properties of 95Mg-3Ni-2MnO_2-nCNTs Nanocrystalline Composite;95Mg-3Ni-2MnO_2-nCNTs纳米晶材料储氢性能研究
8.The Studies of the Hydrogen Storage Properties of Multi-walled Carbon Nanotubes (MWNTs) and Single-walled Carbon Nanotubes (SWNTs);多壁和单壁碳纳米管储氢性能的研究
9.Synthesis and Hydrogen Storage of Metal-Phosphate Molecular Sieves;磷酸盐分子筛的合成及储氢性能研究
10.Hydrogen Storage Property of Mg-Ni-CNTs CompositesMg-Ni-CNTs复合材料储氢性能研究
11.Hydrogen Storage Properties of Ca_(3-x)Mg_(2+x)Ni_(13) AlloysCa_(3-x)Mg_(2+x)Ni_(13)合金的储氢性能
12.Study of Hydrogen Storage Properties of TiF_3-Doped Li-Mg-B-H SystemTiF_3掺杂Li-Mg-B-H体系储氢性能研究
13.Hydrogen storage properties of Ti-Cr-Mn-M(M=V,Fe,Ni,Cu) alloysTi-Cr-Mn-M(M=V、Fe、Ni、Cu)合金的储氢性能
14.A Study on the Hydrogen Storage Properties of Slurry System Composed of Hydrogen-Storage Alloys and Organic Compound;储氢合金与有机液体所组成浆液的储氢性能研究
15.Preparation, Structure and Performances of New Li-Mg-N-H Complex Hydrogen Storage Materials;新型Li-Mg-N-H复合储氢材料的制备、结构及储氢性能
16.Characteristic of hydrogen sorption of alloy La_2Mg_(16)NiLa_2Mg_(16)Ni储氢合金吸放氢性能研究(英文)
17.Study on Hydrogen Absorption/Desorption Characteristics of Ti-V-based Solid Solution Type Hydrogen Storage Alloys;Ti-V基固溶体型储氢合金吸放氢性能的研究
18.Study on Preparation, Structure and Performance of Carbon Material for Hydrogen Storage;储氢碳材料的制备、结构及性能的研究
相关短句/例句
hydrogen storage property储氢性能
1.Phase composition andhydrogen storage property were also investigated by means of X-ray diffraction and pressure composition isotherm.8 MPa初始合成氢压下制备了镁基储氢合金氢化物Mg2NiH4,并利用XRD及PCT仪分析了其物相组成和储氢性能。
2.Thehydrogen storage property of Mg-Ni based alloy film with different deposition nickel is indicated that the property of Mg film is greatly improved.研究了Mg-Ni系储氢合金箔的组成及其储氢性能。
3.Magnesium-based hydrogen storage alloy Mg-Mg_2Ni was prepared by hydriding combustion synthesis,and the effect of Mg/Ni ratio in raw materials,particle size of magnesium on the phase composition andhydrogen storage property of HCS product was investigated.利用氢化燃烧合成法制备了镁基储氢合金Mg-Mg2Ni,分析了镁镍配比和镁粉粒径对HCS产物组成和储氢性能的影响。
3)hydrogen storage performance储氢性能
1.Study onhydrogen storage performance of FeTi_(1.2)+xwt%LaNi_5(x=0,1,2,3,4) alloys;合金FeTi_(1.2)+xwt%LaNi_5(x=0,1,2,3,4)储氢性能的研究
2.The effect of rapid quenching on phase structure andhydrogen storage performance of Ti-28V-15Mn-10Cr alloy is investigated.研究了快淬作用对Ti-28V-15Mn-10Cr合金的相结构和储氢性能的影响。
4)hydrogenation properties储氢性能
1.The effect of Cu addition onhydrogenation properties of Mg_2Ni alloy;Cu的添加对Mg_2Ni合金储氢性能的影响
5)hydriding property储氢性能
6)hydrogen absorption-desorption properties储放氢性能
延伸阅读
不锈钢的物理性能、力学性能和耐热性能不锈钢的物理性能 不锈钢和碳钢的物理性能数据对比,碳钢的密度略高于铁素体和马氏体型不锈钢,而略低于奥氏体型不锈钢;电阻率按碳钢、铁素体型、马氏体型和奥氏体型不锈钢排序递增;线膨胀系数大小的排序也类似,奥氏体型不锈钢最高而碳钢最小;碳钢、铁素体型和马氏体型不锈钢有磁性,奥氏体型不锈钢无磁性,但其冷加工硬化生成成氏体相变时将会产生磁性,可用热处理方法来消除这种马氏体组织而恢复其无磁性。 奥氏体型不锈钢与碳钢相比,具有下列特点: 1)高的电阴率,约为碳钢的5倍。 2)大的线膨胀系数,比碳钢大40%,并随着温度的升高,线膨胀系数的数值也相应地提高。 3)低的热导率,约为碳钢的1/3。 不锈钢的力学性 不论不锈钢板还是耐热钢板,奥氏体型的钢板的综合性能最好,既有足够的强度,又有极好的塑性同时硬度也不高,这也是它们被广泛采用的原因之一。奥氏体型不锈钢同绝大多数的其它金属材料相似,其抗拉强度、屈服强度和硬度,随着温度的降低而提高;塑性则随着温度降低而减小。其抗拉强度在温度15~80°C范围内增长是较为均匀的。更重要的是:随着温度的降低,其冲击韧度减少缓慢,并不存在脆性转变温度。所以不锈钢在低温时能保持足够的塑性和韧性。 不锈钢的耐热性能 耐热性能是指高温下,既有抗氧化或耐气体介质腐蚀的性能即热稳定性,同时在高温时双有足够的强度即热强性。 不锈钢国际标准标准 标准 标准名 GB 中华人民共和国国家标准(国家技术监督局) KS 韩国工业标准协会规格Korean Standard AISI 美国钢铁协会规格America Iron and Steel Institute SAE 美国汽车技术者协会规格Society of Automative Engineers ASTM 美国材料试验协会规格American Society for Testing and Material AWS 美国焊接协会规格American Welding Society ASME 美国机械技术者协会规格American Society of Mechanical Engineers BS 英国标准规格British Standard DIN 德国标准规格Deutsch Industria Normen CAS 加拿大标准规格Canadian Standard Associatoin API 美国石油协会规格American Petroleum Association KR 韩国船舶协会规格Korean Resister of Shipping NK 日本省事协会规格Hihon Kanji Koki LR 英国船舶协会规格Llouds Register of Shipping
