某厂氩气纯化器失效分析及对策

某厂氩气纯化器是由1Cr18Ni9不锈钢制成,在使用过程中出现致密性的网状裂纹开裂。详细论述了氩气纯化器开裂失效的原因,并通过理论分析及实践摸索,找出了应对氩气纯化器失效的对策。并在实际运行中得到了验证,确保了新制氩气纯化器的安全可靠运行。     

远程氩等离子体对聚醚砜膜表面性能的改性

采用双悬浮探针和电子自旋共振法定量对远程氩等离子体进行诊断,确定了电子、离子浓度和自由基浓度的分布,以预测表面改性的最佳区;利用远程氩等离子体对聚醚砜（PES）超滤膜进行表面改性,通过接触角测量、扫描电子显微镜和X射线光电子能谱分析改性前后膜表面结构和性能的变化,最后利用牛血清蛋白分离实验分析改性前后膜的分离性能和抗污染性能变化.结果表明,氩等离子体中电子、离子浓度沿轴向距离逐渐降低,在30cm后接近于0,而40cm处自由基浓度仍维持在90%以上,为可能的最佳表面改性区;在该区对PES超滤膜改性后,引入含氧基团和含氮基团,膜表面（O+N）/C原子比从0.18增大到0.46,增强膜表面极性;在最佳处理条件下,膜表面接触角从67°减小到18°,使膜表面亲水性能增强,抑制了电子、离子对膜的刻蚀作用;通过牛血清蛋白实验测定改性后膜污染率由70.3%减小到64.7%,抗污染性能提高.     

Characteristic of emissive spectrum and the removal of nitric oxide in N2/O2/NO plasma with argon additive

Although the approach using non-thermal plasma (NTP) for deNOx has been studied for over 15 years,how to achieve higher removal efficiency with lower cost is still a barrier for its industrial application.In order to investigate the impact of the argon additive on the electron density,energy and the nitric oxide reduction process in plasma,the spectrum of the dielectric barrier discharge at atmospheric pressure in a coaxial reactor was measured using the monochromater with high resolution and the comparative experiments for NO reduction were carried out simultaneously in the N2/O2/NO plasma stream with and without argon,respectively.The nitrogen molecular spectrum which is attributed to the energy level transition (C3πu→B3πg ) was compared in the wavelength range 300-480 nm and the electron density and temperature were determined by the calculation based on the relative intensities and Stark broadening width of spectral lines.The spectrum results indicated that the argon additive could enhance the intensity of emissive spectrum of plasma,thus the electron concentration as well as the energy was increased,and finally prompted the ionization rate to produce active N,O and O3.The results of NO reduction showed that the NO conversion efficiency increased in the range of 10%-30% with 5% addition of argon in stream comparing with the condition without argon additive.This study will play a positive role in the industrial application of dielectric barrier discharge deNOx reactor.     

Characteristics of emissive spectrum and the removal of nitric oxide in N2/O2/NO plasma with argon additive

Although the approach using non-thermal plasma (NTP) for deNOx has been studied for over 15 years, how to achieve higher removal e ciency with lower cost is still a barrier for its industrial application. In order to investigate the impact of the argon additive on electron density, energy and nitric oxide reduction process in plasma, the spectrum of the dielectric barrier discharge at atmospheric pressure in a coaxial reactor was measured using the monochromater with high resolution. The comparative experiments for NO reduction were carried out simultaneously in N2/O2/NO plasma stream with and without argon, respectively. The nitrogen molecular spectrum which is attributed to the energy level transition (C3 u ! B3 g) was compared in the wavelength range 300–480 nm and the electron density and temperature were determined based on the relative intensities and Stark broadening width of spectral lines. The spectrum results indicated that the argon additive could enhance the intensity of emissive spectrum of plasma, thus the electron concentration as well as the energy was increased, and finally prompted the ionization rate to produce active N, O and O3. The results of NO reduction showed that NO conversion e ciency increased in the range of 10%–30% with 5% addition of argon in stream comparing with the condition without argon additive. This study will play a positive role in the industrial application of dielectric barrier discharge deNOx reactor.     

DISSOLVED GAS ANALYSIS FOR ASSESSING THE FATE OF NITRATE IN WETLANDS1

ABSTRACT: Dissolved gas analysis permits direct detection of ground water denitrification, a technique we used in this study to assess the fate of nitrate in a riparian wetland. Dissolved argon (Ar) and dinitrogen (N₂) were measured in transects of nested piezometers installed at different depths within upwelling regions of a riparian wetland. The method uses the Ar content in the water as a natural inert tracer for assessing background content of N₂ from the previous air/water equilibrium. Within the wetland under study, anoxic to suboxic ground water became more oxic in piezometers close to the aquifer layer, indicating upwelling of oxic ground water. Assessment of loss of nitrate and Ar in ground water within an upwelling zone indicated that shallow piezometers had significant N₂ loss through degassing. Most of the measured nitrate‐nitrogen (NO₃^?‐N) loss of 205 μM in a piezometer nest could be accounted for by total N₂‐N produced (169 μM N), calculated from changes in dissolved N₂ and estimated N₂ degassed. Degassing due to methane (CH₄) production was also detected in some shallow piezometers within nests. This technique for analysis of dissolved gases in ground water can be applied to detect small changes in N gas concentration and aids in assessing the fate of nitrate along a ground water flow path.     

通风条件下氩气泄漏空间氧气盈亏公式推导及应用*

为解决氩气等惰性气体使用场所窒息风险评估方法不足的问题，同时提高建筑通风换气有效性，减少特殊建筑缺氧窒息事故的发生。建立理想气体稀释模型，以氮氩气在空气中的总体积分数为直接指标，研究通风条件下氩气散发导致的氧气浓度变化过程，推导出在氩气泄漏或通风换气单独作用下氮氩气总体积分数与时间之间的函数关系，并在此基础上推导出维持氧气浓度的需用风量计算公式。最后在实例中应用，评估某实验室通风换气的有效性，给出实际需用风量建议。研究结果表明:氧气盈亏模型的建立，为缺氧环境的风险分析提供理论依据，相关公式简单易用，对建筑通风量的准确计算与有效性评估具有重要意义。