Your search keyword '"MERCADO-CABRERA, A."' showing total 7 results

1. NO’x Treatment by Dielectric Barrier Discharge.

Author

Mercado-Cabrera, A., Godoy-Cabrera, O. G., Valencia-Alvarado, R., López-Callejas, R., Barocio, S. R., Peña-Eguiluz, R., Muñoz-Castro, A., de la Piedad-Beneitez, A., and del Villar, E. León

Subjects

*CHEMICAL decomposition, *NITROGEN oxides, *CHEMICAL processes, *OXIDATION, *ELECTRIC discharges, *ALUMINUM electrodes

Abstract

We present an experimental technique for decomposing nitrogen oxides by means of chemical processes of oxidation and reduction assisted by electric discharges taking place in a reactor designed for this effect. The plasma reactor consists of two flat aluminium electrodes of circular geometry with gas input and output accesses capable of increasing slightly the turbulence of the gas flux so to homogenize the mixture to be treated. Both electrodes are covered with a dielectric material. During the experimental phase, an N2 + NO (200 ppm) with slight proportions of O2 (<1%) gas mixture flows at 1.0 lpm and at room pressure. The discharge voltage is measured with a high voltage probe and a digital storage oscilloscope, while the discharge current is gauged with a current transformer. The consumed power in the cells was experimentally determined through Manley’s method. The residual gases were measured by a Sensonic 2000 analyzer. The results showed that, a 12 mJ energy supply and a power of 20 W are enough to degrade up to 99% of the initial amount of NO in a 305 cm3 reaction volume. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006

2. Simulation Study of an Extended Density DC Glow Toroidal Plasma Source.

Author

Granda-Gutiérrez, E. E., López-Callejas, R., Peña-Eguiluz, R., Mercado-Cabrera, A., Valencia A., R., Barocio, S. R., Godoy-Cabrera, O. G., de la Piedad-Beneitez, A., Benítez-Read, J. S., and Pacheco-Sotelo, J. O.

Subjects

PLASMA density, TOROIDAL magnetic circuits, GLOW discharges, MATHEMATICAL optimization, PLASMA gases, IONIZED gases

Abstract

Conventional wisdom assigns the DC glow discharge regime to plasma currents below ∼500 mA values, beyond which the discharge falls into the anomalous glow and the turbulent arc regimes. However, we have found evidence that, during toroidal discharges, this barrier can be ostensibly extended up to 800 mA. Thus, a computer simulation has been applied to the evolution of the main electrical characteristics of such a glow discharge plasma in a toroidal vessel in order to design and construct a respective voltage/current controlled source. This should be able to generate a DC plasma in the glow regime with which currents in the range 10-3–100 A can be experimented and 109–1010 cm-3 plasma densities can be achieved to PIII optimization purposes. The plasma is modelled as a voltage-controlled current source able to be turned on whenever the breakdown voltage is reached across the gap between the anode and the vessel wall. The simulation outcome fits well our experimental measurements showing that the plasma current obeys power laws that are dependent on the power current and other control variables such as the gas pressure. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006

3. A Multicell Converter Model of DBD Plasma Discharges.

Author

Flores-Fuentes, A. A., Peña-Eguiluz, R., López-Callejas, R., Mercado-Cabrera, A., Valencia A., R., Barocio, S. R., Godoy-Cabrera, O. G., de la Piedad-Beneitez, A., Benítez-Read, J. S., and Pacheco-Sotelo, J. O.

Subjects

PLASMA displays, GLOW discharges, ELECTRODES, DIELECTRICS, POWER resources, DISTRIBUTION (Probability theory)

Abstract

A compact Matlab model of plasma discharges in a DBD reactor consisting of two parallel electrode plates with a small gap and a thin dielectric sheet between them is reported. Its DBD plasma is modelled as a voltage controlled current-source switched on when the voltage across the gap exceeds the breakdown voltage. A three cell voltage-source inverter, configured in half-bridge, has been used as a power supply. This configuration has an excellent performance when operating as an open-loop. The distribution of total energy between a large number of low power converters proofs to be advantageous, allowing an efficient high power drive. Simulation results show that the current source and its output current tend to follow an exponential behaviour. A phenomenological characteristic of the voltage-current behaviour of DBD is then described by power laws with different voltage exponent function values. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006

4. PIII Plasma Density Enhancement by a New DC Power Source.

Author

López-Callejas, R., Granda-Gutiérrez, E. E., Muñoz-Castro, A. E., Valencia A., R., Barocio, S. R., Mercado-Cabrera, A., Peña-Eguiluz, R., Godoy-Cabrera, O. G., and de la Piedad-Beneitez, A.

Subjects

PLASMA gases, IONIZED gases, POWER resources, PLASMA density, PLASMA sheaths, ELECTRIC potential

Abstract

In practical terms, those plasmas produced by a DC voltage power supply do not attain densities above the 108 to 109 cm-3 band. Here we present a power supply, controlled in current and voltage, which has been successfully designed and constructed delivering plasma densities in the orders of 109 – 1010 cm-3. Its experimental performance test was conducted within one toroidal and one cylindrical chambers capable of 29 and 35 litres, respectively, using nitrogen gas. The DC plasma was characterized by a double electric probe. Several physical phenomena present in the PIII process have been keenly investigated including plasma sheath dynamics, interaction of plasma and surface, etc. In this paper we analyze the effect of the implantation voltage, plasma density and pulse time in the PIII average heating power and fluence density. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006

5. Electrical Characterization of an RF Glow Discharge at Room Pressure.

Author

Pérez-Martínez, J. A., Peña-Eguiluz, R., López-Callejas, R., Mercado-Cabrera, A., Valencia A., R., Barocio, S. R., Godoy-Cabrera, O. G., de la Piedad-Beneitez, A., Benítez-Read, J. S., and Pacheco-Sotelo, J. O.

Subjects

PLASMA gases, IONIZED gases, QUANTUM tunneling, QUANTUM perturbations, TRANSFER functions, ELECTRIC impedance

Abstract

A non-thermal atmospheric-like plasma source able to operate at room temperature represents, by its physical nature, a considerable potential for biological applications, given its highly accurate action and extremely controllable penetration on the surface of biological tissue. As we start up a research line into this technology, we report the electrical characterization of a room pressure plasma discharge by means of a coupling network model. The discharge is produced by a 13.56MHz commercial generator. As it is impossible to measure directly its state variables (voltage and current intensity) due to the considerable perturbation created by introducing a low impedance at the system output, then an indirect estimation of such variables is achieved from experimental diagnostics at the input, so to validate the proposed electrical model. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006

6. A Simulation of Pre-Arcing Plasma Discharge Processes in Water Purification.

Author

Rodríguez-Méndez, B. G., López-Callejas, R., Peña-Eguiluz, R., Mercado-Cabrera, A., Valencia-A., R., Barocio, S. R., Godoy-Cabrera, O. G., de la Piedad-Beneitez, A., Benítez-Read, J. S., and Pacheco-Sotelo, J. O.

Subjects

PLASMA gases, IONIZED gases, WATER purification, ELECTRIC circuits, KIRLIAN photography, IONIZATION of gases

Abstract

The simulation of a water purification system within a coaxial cylinder reactor operated by 1 kHz frequency plasma discharges in pre-arcing regimes is presented. In contrast with precedent works, this computational model considers three mechanisms of the system operation: (a) the relevant physical characteristics of water, (b) the ionisation and expansion processes in the spark channel including the near-breakdown electric current generated by the rate of change of the effective capacitance and resistance in the discharge, and (c) the energy associated with this initial spark in the water. The outcome of the model seems to meet all main requirements to allow the design and construction of specific water purification technology devices. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006

7. Some Temperature Effects on AISI-304 Nitriding in an Inductively Coupled RF Plasma.

Author

Valencia-Alvarado, R., de la Piedad-Beneitez, A., de la Rosa-Vázquez, J., López-Callejas, R., Barocio, S. R., Godoy-Cabrera, O. G., Mercado-Cabrera, A., Peña-Eguiluz, R., and Muñoz-Castro, A. E.

Subjects

NITRIDING, PLASMA gases, IONIZED gases, STAINLESS steel, ELECTRON temperature, ELECTRON distribution

Abstract

Some recent results obtained from nitriding AISI 304 stainless steel samples, 1.2 cm in diameter and 0.5 cm thick are reported here in the case of an 85% hydrogen and 15% nitrogen mixture work gas. The process was carried out from 300 to 400 W for (13.56 MHz) inductively coupled plasma within a 60 cm long pyrex glass tube 3.5 cm in diameter where the samples were biased up to -300 V with respect to earth. The resulting hardness appears to be a function of the substrate temperature which varied from 200 °C at a 0 V bias to 550 °C at -300 V. The plasma density at 400 W reached 3×1010 cm-3 with a 4 eV electron temperature. Prior to nitriding, all the samples were polished with 0.05 μm diamond paste, leading to a 30 nm average roughness (Ra). After nitriding at -300 V, the Ra rose until ∼400 nm while hardness values of 1500 HV under 300 g loads were measured. X ray diffraction indicates that the extended phase amplitude (γN), Fe and Cr nitride depends on the substrate temperature. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006