Modeling Nonlinear Coupling between Plasma, Electrodes and Walls for High-Pressure Hg Arc Discharge Lamps

Cristea, M.; Iova, I.; Cristescu, C.; Popescu, Iulian; Damelincourt, J. J.

doi:10.1002/1521-3986(200009)40:5/6<545::aid-ctpp545>3.0.co;2-9

Cited by 3 publications

References 13 publications

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A numerical study of the supply mode effects on high-pressure mercury discharge lamp dynamic thermal behavior

et al. 2005

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This paper presents a numerical study of the dynamic behavior of high-pressure mercury discharge lamp as a function of supply mode. Bidimensional time-dependent equations have been solved by using a semi-implicit finite-element code. The model has been developed in the frame of the local thermodynamic equilibrium hypothesis. After validation by using experimental data from the literature, this model was applied to analyze the effects of some key parameters such as frequency for an ac arc current and the ratio cycle parameter for square arc-current wave form on the convective process. The results obtained have been used to analyze the dynamic thermal behavior of high-pressure mercury plasma (pressure equal to 0.3 MPa) working under currents widely different in frequency and wave form.

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A numerical study of the supply mode effects on high-pressure mercury discharge lamp dynamic thermal behavior

et al. 2005

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An Electrical Cathode Model of a High Pressure Sodium Lamp

Tapia-Fabela

Sotelo

Rodriguez

et al. 2010

2010 IEEE Electronics, Robotics and Automotive Mechanics Conference

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Modeling the Voltage Drop Across the Cathode Sheath in HPS

Fabela

Pacheco-Sotelo

Pacheco

et al. 2007

IEEE Trans. Plasma Sci.

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An electrical cathode model (ECM) of a highpressure sodium (HPS) lamp based on physical laws has been developed. The proposed ECM calculates the instantaneous voltage drop in a cathode sheath and the temperature distribution inside the cathode using as input parameter the cathode geometry and the positive column current. The model is based on the electrode heat transport equation, which is solved using the finite-element method. So, since it stems from the physics describing the cathode behavior, it is found that the ECM predicts in a satisfactory way the cathode voltage drop over a wide range of work conditions. The obtained results were compared with those reported in the current literature. It can be concluded that the ECM is a useful tool in understanding the interaction between the positive column and the cathode in order to improve, for instance, HPS lamp ballast designs, as measuring the potential drop across the cathode sheath using a commercial lamp is particularly difficult. The model takes into account the temperature dependence of the thermal conductivity, the electrical cathode resistivity, and the total emissivity. Index Terms-Cathode temperature distribution, electrical cathode model (ECM), finite-element method, high-pressure sodium (HPS) lamps.

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Modeling Nonlinear Coupling between Plasma, Electrodes and Walls for High-Pressure Hg Arc Discharge Lamps

Cited by 3 publications

References 13 publications

A numerical study of the supply mode effects on high-pressure mercury discharge lamp dynamic thermal behavior

A numerical study of the supply mode effects on high-pressure mercury discharge lamp dynamic thermal behavior

An Electrical Cathode Model of a High Pressure Sodium Lamp

Modeling the Voltage Drop Across the Cathode Sheath in HPS

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