A new method for determining the kinetic order and activation energy for atom formation in electrothermal atomic absorption spec-trometry is proposed. The assumption of first order kinetics for atom formation and the ...A new method for determining the kinetic order and activation energy for atom formation in electrothermal atomic absorption spec-trometry is proposed. The assumption of first order kinetics for atom formation and the steady-state approximation which appeared in the previous models is avoided in the proposed method. The kinetic parameters for atom formation of Li have been obtained, and the effect of the amount of analysed sample, ashing temperature, atomization temperature, heating rate, gas flow and tube surface on the atomization of Li has also been investigated.展开更多
为了改善柴油机D6114喷油嘴291 DLLA150 FC PV01内部燃油流动状况,使喷入气缸内的燃油达到较好的雾化质量,在原有喷嘴基础上,针对喷嘴结构参数长径比、喷嘴入口过渡圆角及喷孔锥角设计了9种方案。在CFD(计算流体动力学)软件中建立了喷...为了改善柴油机D6114喷油嘴291 DLLA150 FC PV01内部燃油流动状况,使喷入气缸内的燃油达到较好的雾化质量,在原有喷嘴基础上,针对喷嘴结构参数长径比、喷嘴入口过渡圆角及喷孔锥角设计了9种方案。在CFD(计算流体动力学)软件中建立了喷嘴内部流场的三维模型,对整个流场区域进行了流体动力学模拟计算。分析了喷嘴结构参数对喷孔内部空化程度、湍动能及流速的影响,得出:随着长径比(L/D)的减小,燃油在喷孔中的空化程度增强,湍动能减小,流速增加;随着过渡圆角与直径比(r/D)的增大,喷孔内部流体空化程度增强,流速增大,湍动能减弱;随着喷孔锥角(θ)的增大,喷孔内燃油空化程度加强,湍动能减弱。展开更多
文摘A new method for determining the kinetic order and activation energy for atom formation in electrothermal atomic absorption spec-trometry is proposed. The assumption of first order kinetics for atom formation and the steady-state approximation which appeared in the previous models is avoided in the proposed method. The kinetic parameters for atom formation of Li have been obtained, and the effect of the amount of analysed sample, ashing temperature, atomization temperature, heating rate, gas flow and tube surface on the atomization of Li has also been investigated.
文摘为了改善柴油机D6114喷油嘴291 DLLA150 FC PV01内部燃油流动状况,使喷入气缸内的燃油达到较好的雾化质量,在原有喷嘴基础上,针对喷嘴结构参数长径比、喷嘴入口过渡圆角及喷孔锥角设计了9种方案。在CFD(计算流体动力学)软件中建立了喷嘴内部流场的三维模型,对整个流场区域进行了流体动力学模拟计算。分析了喷嘴结构参数对喷孔内部空化程度、湍动能及流速的影响,得出:随着长径比(L/D)的减小,燃油在喷孔中的空化程度增强,湍动能减小,流速增加;随着过渡圆角与直径比(r/D)的增大,喷孔内部流体空化程度增强,流速增大,湍动能减弱;随着喷孔锥角(θ)的增大,喷孔内燃油空化程度加强,湍动能减弱。