稀土元素替代对RBaCo_4O_(7+δ)氧吸附/脱附性能影响的研究

采用固态反应法制备了稀土元素(R=Yb、Er、Dy)替代的RBaCo_4O_(7+δ)氧吸附材料,对其进行了XRD和热重(TG)分析,研究了稀土元素元素替代对其氧吸附/脱附性能的影响。XRD结果表明:不同稀土元素替代的RBaCo_4O_(7+δ)材料具有单一的六方密排晶体结构(空间群为P63mc(186))。热重结果显示:从室温到1000℃,所有样品经历两次氧吸附过程,DyBaCo_4O_(7+δ)样品最大氧吸附量明显高于YbBaCo_4O_(7+δ)的最大氧吸附量。

Tb掺杂DyBaCo_(4)O_(7+δ)纳米粉体的制备及其氧吸附/脱附性能的研究

利用溶胶凝胶工艺合成了稀土元素Tb掺杂DyBaCo_(4)O_(7+δ)纳米粉体,采用XRD、SEM、差热分析仪等设备研究了不同浓度Tb掺杂对DyBaCo_(4)O_(7+δ)纳米粉体形貌、晶体结构及氧吸附-脱附性能的影响,测试结果表明:在较低掺杂浓度下,Tb很好地进入了Dy_(1-x)Tb_(x)BaCo_(4)O_(7+δ)的晶格,稀土Tb掺杂的DyBaCo_(4)O_(7+δ)纳米粉体仍是六方密排晶体结构;Tb元素掺杂对DyBaCo_(4)O_(7+δ)粉体的形貌影响不大。从室温到1000℃,DyBaCo_(4)O_(7+δ)纳米粉体与Tb掺杂的DyBaCo_(4)O_(7+δ)纳米粉体均表现出两次氧吸附和脱附现象,与未掺杂的DyBaCo_(4)O_(7+δ)纳米粉体氧吸附性能相比,Tb掺杂的DyBaCo_(4)O_(7+δ)纳米粉体的氧吸附性能明显高于未掺杂DyBaCo_(4)O_(7+δ)氧吸附性能,DyBaCo_(4)O_(7+δ)的氧吸附的变化量为1.4%,而Dy 0.85 Tb 0.15 BaCo_(4)O_(7+δ)的氧吸附的变化量4.9%,同时研究了在N_(2)/O_(2)气体切换过程,DyBaCo_(4)O_(7+δ)纳米粉体与Tb掺杂的DyBaCo_(4)O_(7+δ)纳米粉体的氧吸附/脱附行为。DyBaCo_(4)O_(7+δ)氧吸附/脱附性能的改善可以归因为Tb元素掺杂改善了DyBaCo_(4)O_(7+δ)的间距变宽,提高了DyBaCo_(4)O_(7+δ)样品的储氧空间增加有关。

Ce元素掺杂对YBaCo_4O_(7+δ)氧吸附/脱附性能的影响

本研究采用固态反应法制备了Ce掺杂的YBaCo_4O_(7+δ)氧吸附材料,对其进行了X射线衍射(XRD)分析和热重分析测试,研究了Ce掺杂对其氧吸附/脱附性能的影响。XRD分析结果表明:在x=0.10,0.15,0.20掺杂比例范围内,Ce很好地进入了YBaCo_4O_(7+δ)的晶格,具有单一的YBaCo_4O_(7+δ)的晶体结构,没有出现第二相。热重分析结果表明:从室温到1000℃,所有样品都经历了两次氧吸附过程,Ce掺杂的YBaCo_4O_(7+δ)样品最大氧吸附量明显高于YBaCo_4O_(7+δ)的最大氧吸附量。

YBaCo4O7+δ的制备及其氧吸附/脱附性能研究

采用溶胶凝胶法和固态反应法制备了不同比表面积的YBaCo4O7＋δ吸附材料,采用X射线衍射仪、电子扫描显微镜对不同比表面积粒径的YBaCo4O7＋δ料的结构、形貌进行了表征,测试结果表明：溶胶凝胶法和固态反应法制备的YBaCo4O7＋δ料均为六方密排晶体结构（空间群为P63mc（186））,与固态反应法相比,溶胶凝胶法制备的YBaCo4O7＋δ吸附材料粒径较小,且分布较为集中,并研究了粒径对YBaCo4O7＋δ料氧吸附/脱附性能的影响,从室温到1000℃,不同粒径的YBaCo4O7＋δ吸附材料均经历两次氧吸附过程,而溶胶凝胶法制备的YBaCo4O7＋δ 料氧吸附性能明显高于固态反应法制备的YBaCo4O7＋δ料的氧吸附性能,这是因为溶胶凝胶法制备的YBaCo4O7＋δ料具有较小的尺寸,较大的比表面积的缘故。

热排空法测试复合吸附剂吸附脱附性能

采用热排空法进行了复合吸附剂吸附脱附性能测试试验．该方法在不使用真空泵的情况下将空气排出，使得系统内空气分压力小于2Pa，符合国家标准对测试试验的要求．通过测定13X沸石原粉和整体成型复合吸附剂的吸附脱附性能得出：其测试值与文献值偏差小于8％，脱附过程和吸附过程中吸附床温度变化速率较高，分别为6．7℃／min和～13．7℃／min；对各个复合吸附剂性能的测试和比对得到复合吸附剂E，其脱附性能较好，将复合吸附剂E应用于太阳能冷管中的制冷系数COP约为0．24～0．28．

高分子树脂对正己烷的吸附-脱附性能研究

以DA-1,DA-2和D8三种商业树脂为吸附剂,考察了高分子树脂对典型油气废气正己烷的吸附-脱附性能.研究表明:在吸附实验中,高分子树脂对正己烷均表现出良好的吸附性能,其中DA-1和DA-2树脂具有大孔容、大比表面积和较小的孔径等特点,更有利于正己烷分子吸附;脱附实验中,真空脱附效果优于热脱附,在脱附温度达90℃,脱附时间30min,真空度为0.8时,脱附效率接近100%.

钛改性硅胶块体吸附剂除湿性能研究

采用浸渍沉积法制得钛改性硅胶块体吸附剂。对块体吸附剂的孔结构进行表征;考察了改性硅胶吸附剂动、静态除湿性能以及在吸附/脱附过程中湿度场、温度场的变化。结果表明,改性后的硅胶,其微孔、中孔孔径有所减少,而孔容和比表面显著增大;钛改性硅胶的吸附性能好于硅胶,而脱附能力劣于硅胶;由于钛改性硅胶产生更多的吸附热,吸附时出口气流温度略高于硅胶,而脱附时正好相反。

Adsorption and desorption properties of D318 resin for Cr(Ⅵ)

The adsorption capability of D318 resin for Cr（Ⅵ） was investigated by chemistry analysis. Experimental results show that D318 resin has the best adsorption ability for Cr（Ⅵ） at pH=3.16 in HAc-NaAc medium. The statically saturated adsorption capacity of the resin is 265.4 mg/g. The thermodynamic adsorption parameters, enthalpy change AH and free energy change AG298 of the adsorption reaction are 4.81 and -5.16 kJ/mol, respectively. The apparent activation energy Ea is 22.4 kJ/mol. The adsorption behavior obeys the Freundlich isotherm. The molar coordination ratio of the functional group of resin to Cr（Ⅵ） is 3：2. Cr（Ⅵ） adsorbed on D318 resin can be eluted by 5%NaOH-5%NaCl quantitatively.

Adsorption Refrigeration Performance of Shaped MIL-101-Water Working Pair

A new metal-organic framework of MIL-101 was synthesized by hydrothermal method and the powder prepared was pressed into a desired shape. The effects of molding on specific surface area and pore structure were investigated using a nitrogen adsorption method. The water adsorption isotherms were obtained by high vacuum gravimetric method, the desorption temperature of water on shaped MIL-101 was measured by thermo gravimetric analyzer, and the adsorption refrigeration performance of shaped MIL-101-water working pair was studied on the simulation device of adsorption refrigeration cycle system. The results indicate that an apparent hysteresis loop ap-pears in the nitrogen adsorption/desorption isotherms when the forming pressure is 10 MPa. The equilibrium ad-sorption capacity of water is up to 0.95 kg·kg^-1 at the forming pressure of 3 MPa （MIL-101-3）. The desorption peak temperature of water on MIL-101-3 is 82℃, which is 7 ℃ lower than that of silica gel, and the desorption temperature is no more than 100 ℃. At the evaporation temperature of 10 ℃, the refrigeration capacity of MIL-101-3-water is 1059 kJ·kg^-1, which is 2.24 times higher than that of silica gel-water working pair. Thus MIL-101-water working pair presents an excellent adsorption refrigeration performance.