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阳极负载     
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  anode-supported
     Anode-supported SOFCs withLDC-LSGM bilayer electrolyte were fabricated, in which the LDC layer canrestrain the reaction of LSGM and NiO at high temperatures and the LSGM layercan block the electronic conductivity of the LDC electrolyte.
     首次制备了阳极负载LDC-LSGM双层电解质型电池,其中LDC 层隔绝了NiO 与LSGM 的高温反应,LSGM 阻隔了LDC 的电子电导。
短句来源
     Fabrication and Investigation of Anode-supported Intermediate Temperature Solid Oxide Fuel Cells with Novel Composite Electrolytes
     阳极负载新型复合电解质中温固体氧化物燃料电池的研制及其性能研究
短句来源
     ELECTROCHEMICAL PERFORMANCE OF ANODE-SUPPORTED INTERMEDIATE TEMPERATURE SOLID OXIDE FUEL CELLS FED WITH HYDROGEN SULFIDE
     阳极负载型H_2S中温固体氧化物燃料电池电输出性能
短句来源
  anode supported
     The Effect of Anode Thickness in SOFCs with Anode Supported YSZ Film
     阳极负载型SOFC阳极基底厚度对性能的影响
短句来源
  “阳极负载”译为未确定词的双语例句
     A glycine-nitrate combustion process was adopted to prepare samaria doped ceria [(CeO2)1-2x(Sm2O3)x,SDC] electrolyte on NiO-SDC anode substrate.
     以NiO-(CeO2)1-2x(Sm2O3)x固体氧化物燃料电池(solidoxidefuelcell,SOFC)的阳极负载,采用甘氨酸-硝酸盐燃烧法制备(CeO2)0.8(Sm2O3)0.1固体电解质前驱体粉末并流延成膜。
短句来源
     Recent years, much effort is directed to novel thin electrolytes, such asLaGaO_(3-) and ceria-based electrolytes, for intermediate temperature solid oxidefuel cells (IT-SOFCs).
     阳极负载电解质薄膜电池是近年来中温固体氧化物燃料电池(IT-SOFC)研究的热点之一。
短句来源
  相似匹配句对
     Photoelectrocatalytic Degradation of Alizarin Red on Titanium Dioxide Photo-anode
     负载型二氧化钛光阳极对茜素红的光电催化降解
短句来源
     The Effect of Anode Thickness in SOFCs with Anode Supported YSZ Film
     阳极负载型SOFC阳极基底厚度对性能的影响
短句来源
     Load Balancing of System Level Application Systems
     负载均衡技术
短句来源
     Graphitic Anode of Electron Tube
     电子管石墨阳极
短句来源
     The Load Matching of Cablecasting
     有线广播的负载匹配
短句来源
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  anode-supported
A tubular anode-supported solid oxide fuel cell with a double-layer anode for the direct conversion of CH4 has been prepared and operated at 800?°C successfully.
      
Comparison of polarization effects on the cell performance between the electrolyte-supported and anode-supported cells showed that the latter would give a better cell performance.
      
Development of LSM/YSZ composite cathode for anode-supported solid oxide fuel cells
      
A power density of ~1 W cm-2 at 800 °C was achieved with an anode-supported cell using an LSM-B/YSZ composite cathode.
      
As of this year, the materials development as well as the component manufacturing was focused on anode-supported cells.
      
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  anode-support
The anode-support system: an alternative for the electrorefining of tin in sulphuric acid medium
      
This paper describes a study of the application of an anode-support system to the electrorefining of tin in sulphuric acid medium.
      
The authors have established that it is feasible to utilize a metallic basket of AISI-316 stainless steel mesh as the anode-support, with granules of 97% tin inside the basket.
      
It is possible to utilize the anode-support system under the same conditions used for the industrial electrorefining of tin with conventional cast anodes.
      
In fact, electrolyses of 10 days duration can be carried out continuously using the anode-support system, with the cell voltage remaining practically constant.
      
更多          
  anode supported
Fabrication of anode supported thick film ceria electrolytes for IT-SOFCs
      
Anode supported thick film ceria electrolyte unit cells were fabricated using a colloidal dip coating method for IT-SOFCs.
      
Anode supported structure schematic Several anode supported cells were constructed.
      
As a consequence, anode supported fuel cell structure was introduced as objective 4.
      
The Argonne Lab Research group is combining CGO electrolyte technology with the anode supported design for operation at o C.
      
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Solid oxide fuel cells with supported yttria stabilized zirconia electrolyte films on anode substrates of various thickness have been fabricated. The electrochemical performances of the SOFCs have been examined. The results showed that the cell performance was limited by the anodic overpotential, which is caused mainly by a concentration polarization when the anode substrate is thick. The anodic overpotential was reduced obviously as the thickness of anode substrate was decreased. As a result, the performance...

Solid oxide fuel cells with supported yttria stabilized zirconia electrolyte films on anode substrates of various thickness have been fabricated. The electrochemical performances of the SOFCs have been examined. The results showed that the cell performance was limited by the anodic overpotential, which is caused mainly by a concentration polarization when the anode substrate is thick. The anodic overpotential was reduced obviously as the thickness of anode substrate was decreased. As a result, the performance of the SOFC cell was improved. With a 0.5 mm anode substrate, a SOFC cell produced a power density about 0.19 W/cm 2 at 800 ℃, which was 1.5 times as high as that of the cell with a 1.0 mm thickness anode (0.13 W/cm 2).

制备不同厚度阳极负载型YSZ薄膜固体氧化物燃料电池 ,并对电池的极化、放电性能进行了测试 .结果表明 ,电池的性能明显受阳极性能的影响 ,阳极过电位大的原因之一是受多孔阳极气体扩散的影响 .降低阳极基底的厚度 ,阳极过电位明显减小 ,电池性能明显提高 .当阳极基底厚度为 0 .5mm时 ,在 80 0℃工作温度下 ,电池的功率密度达到 0 .1 9W·cm- 2 ,较之阳极厚度为 1 .0mm的电池性能提高近 1 .5倍 (0 .1 3W·cm- 2 ) .

Gd_(0.1)Ce_(0.9)O_(1.95)(GDC), La_(0.45)Ce_(0.55)O_(2-σ/2)(LDC) and La_(0.9)Sr_(0.1)Ga_(0.8)Mg_(0.2)O_(2.85)(LSGM) electrolyte materials were synthesized by the citric method. Anode-supported single cells with GDC-LSGM, LDC-LSGM and LDC-LSGM-LDC multi-layer thin film electrolyte were prepared. The U-J characteristics and output power performance of the single cells were measured. The results showed that no current could be taken from the cell with GDC-LSGM electrolyte.The cell with LDC-LSGM electrolyte gave...

Gd_(0.1)Ce_(0.9)O_(1.95)(GDC), La_(0.45)Ce_(0.55)O_(2-σ/2)(LDC) and La_(0.9)Sr_(0.1)Ga_(0.8)Mg_(0.2)O_(2.85)(LSGM) electrolyte materials were synthesized by the citric method. Anode-supported single cells with GDC-LSGM, LDC-LSGM and LDC-LSGM-LDC multi-layer thin film electrolyte were prepared. The U-J characteristics and output power performance of the single cells were measured. The results showed that no current could be taken from the cell with GDC-LSGM electrolyte.The cell with LDC-LSGM electrolyte gave the maximum output power density of 0.72 W/cm~2 at 800 ℃, but it was not stable. The open circuit voltage of the cell with LDC-LSGM-LDC electrolyte was the highest, reaching to 0.814 V at 800 ℃.

采用柠檬酸法合成了Gd0 1Ce0 9O1 95(GDC)、La0 45Ce0 55O2-σ/2(LDC)、La0 9Sr0 1Ga0 8Mg0 2O2 85(LSGM)电解质材料,并制备了阳极负载型GDC LSGM、LDC LSGM和LDC LSGM LDC多层薄膜电解质单体电池,考察了单体电池的U J特性和功率输出性能。结果显示:GDC LSGM电解质电池没有电流产生;LDC LSGM电解质电池最大输出功率密度最高,800℃时约为0 72W/cm2,但不稳定;LDC LSGM LDC多层电解质电池的开路电压最高,800℃时可达0 814V。

Anode-supported solid oxide fuel cell with LDC-LSGM bilayer electrolytes and GDC+NiO anode substrate was fabricated and operated by using H_2 and methanol as the fuels respectively at temperatures from 650 to 800 ℃. At 800 ℃, the single cell exhibits the maximum output power density of 1.54 W/cm~2 with H_2 as the fuel and that of 1.07 W/cm~2 with methanol as the fuel. The impedance spectra of the single cell show some differences when the two different fuels are respectively used, and the anode activity towards...

Anode-supported solid oxide fuel cell with LDC-LSGM bilayer electrolytes and GDC+NiO anode substrate was fabricated and operated by using H_2 and methanol as the fuels respectively at temperatures from 650 to 800 ℃. At 800 ℃, the single cell exhibits the maximum output power density of 1.54 W/cm~2 with H_2 as the fuel and that of 1.07 W/cm~2 with methanol as the fuel. The impedance spectra of the single cell show some differences when the two different fuels are respectively used, and the anode activity towards methanol is the key factor for the cell performance.

制备了阳极负载型LDC-LSGM双层电解质薄膜电池.考察了单电池在分别使用甲醇和氢气两种燃料时,不同温度下的I~V性能.以甲醇为燃料,以空气为氧化剂时,800℃下的最大输出功率密度为1.07W/cm2,而使用氢气为燃料时,最大输出功率密度为1.54W/cm2.通过交流阻抗研究了造成甲醇性能降低的可能原因.结果表明,以甲醇作为燃料时,单电池性能较氢气作为燃料时低.

 
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