S. Tsukamoto scite author profile

Nitric monoxide (NO) is widely used in medical treatment of acute respiratory distress syndrome (ARDS). The production of NO is of interest to the medical community. In the present work, NO is generated by pulsed discharges between two rod electrodes in a mixture of nitrogen and oxygen. An arc discharge having a temperature of about 10 000K was produced, which was sufficient to generate NO. Some of the important parameters affecting the production of NO have been investigated. These include the percentage of O 2 (6-94%) in the mixture of N 2 and O 2 , the energy of the discharge (0.5-12 J/pulse), the pulse repetition rate (0.5-4.5 pps) and the flow rate (1.35-5.4 l/min) of the gas mixture. NO 2 produced in the discharge was successfully changed to NO using a heated molybdenum tube. NO 2 must be extracted from the gas before clinical inhalation. The concentration of ozone was completely eliminated by bubbling the gas mixture through water. A maximum of NO and a minimum of NO 2 concentrations were generated when the proportion of O 2 in the gas mixture was in the range of 20-27%. The concentrations of NO and NO 2 increased with increasing pulse repetition rate and with decreasing flow rate of the mixture. In all cases, NO 2 was effectively removed using a heated molybdenum tube.Index Terms-Acute respiratory distress syndrome, medical application, nitric monoxide, pulsed arc discharge.. Manuscript

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Influence of gas flow rate and reactor length on NO removal using pulsed power

Namihira

Tsukamoto

Wang

et al. 2001

IEEE Trans. Plasma Sci.

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A short duration of 100-ns pulsed power has been used to remove nitric oxide (NO) in a mixture of nitrogen, oxygen, water vapor, and NO, simulating flue gases from a power station. The effects of the gas flow rate, the reactor length, and the pulse repetition rate on the percentage of NO removal and its energy efficiency are reported. The percentage of NO removal at a fixed gas flow rate increased with increasing pulse repetition rate due to the increased energy into the discharge. At a fixed pulse rate, the removal of NO increased with decreasing gas flow rate due to the increased residence time of the gas in the discharge reactor, thus facilitating the creation of increased radicals of O and N which then decreased NO. The energy removal efficiency of NO (in mol/kWh) decreased with increasing gas flow rate and increasing removal ratio of NO. The removal of NO increased with increasing energy density (J/l) input into the discharge at different reactor length.

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Application of pulsed power to mushroom culturing

Tsukamoto

Maeda

Ikeda

et al.

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Production of nitric monoxide in dry air using pulsed discharge

Namihira

Tsukamoto²,

Wang

et al.

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S. Tsukamoto

Improvement of NO/sub X/ removal efficiency using short-width pulsed power

Production of nitric monoxide using pulsed discharges for a medical application

Influence of gas flow rate and reactor length on NO removal using pulsed power

Application of pulsed power to mushroom culturing

Production of nitric monoxide in dry air using pulsed discharge

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