Design and Testing of a Prototype De-NO<sub>x</sub>System for 100 kVA Diesel Engine Generator using a Silent Discharge Reactor

Yoshioka, Yoshio; Yukitake, T.; Nakai, Masato; Souma, Kenichi; Tuchiya, Keiichi; Annou, K.; Hori, Yasurō

doi:10.1080/00102209808952024

Cited by 16 publications

(2 citation statements)

References 9 publications

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“…Important contributions are as follows: plasma-catalyst with hydrocarbon (aldehyde) injection method [20,21], plasma-SCR with urea injection method [22], oil droplet plasma injection system [23,24] that was already in the stage of a truck demonstration test stage, silent discharge plasma system for the exhaust of 100 kVA diesel engine generator [25], corona radical shower system with higher energy efficiency [26] and nitrogen gas reduction with ultra small gap plasma reactor [27]. However, large consumption of plasma electric energy is required in these systems because the plasma must be always turned on during the aftertreatment.…”

Section: Introductionmentioning

confidence: 99%

Total Diesel Emission Control Technology Using Ozone Injection and Plasma Desorption

Okubo

Arita

Kuroki

et al. 2008

Plasma Chem Plasma Process

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An innovative total diesel emission control system for diesel particulate and NOx simultaneous reduction is proposed. In this system, the plasma reactor is located outside the emission exhaust pipe and activated gas induced from ozone activated by the plasma is injected into the exhaust pipe. On the other hand, the NOx reduction is achieved using oxygen-poor nonthermal plasma desorption. The concentration of oxygen can be changed either by controlling the incineration state of the engine or by injecting oxygenpoor gas. Experiments are carried out for the emission of small diesel engine generator and high performance is demonstrated. The effective or apparent required plasma energy can be decreased further using this system because of the periodic or intermittent application of the plasma. In the present study, the excellent reduction energy efficiencies of 6.6 g/kWh for PM and 16 g (NO 2 )/kWh for NOx are achieved.

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Section: Introductionmentioning

confidence: 99%

Total Diesel Emission Control Technology Using Ozone Injection and Plasma Desorption

Okubo

Arita

Kuroki

et al. 2008

Plasma Chem Plasma Process

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“…Over the past decade, research has been conducted in the area of nonthermal plasma-assisted NO x /SO x removal from the exhaust of power plants , and for diesel engine exhaust, volatile organic compounds (VOC) removal, heavy hydrocarbon removal (tar) removal from biomass gasification gas, and water treatment . Some of the applications are on the verge of bridging the gap between laboratory and industry , The investigations focus on understanding physical processes inside a nonthermal plasma reactor and, furthermore, the engineering of reactors for various processing conditions. , However, from the process optimization point of view, the chemical kinetics and the reaction pathways , provide the key information in addressing the energy costs and obtaining the relevant process parameters.…”

Section: Introductionmentioning

confidence: 99%

In Situ Fourier Transform Infrared (FTIR) Study of Nonthermal-Plasma-Assisted Methane Oxidative Conversion

Nair

Nozaki

Okazaki

2007

Ind. Eng. Chem. Res.

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Nonthermal plasma-assisted methane conversion has been widely investigated as a potential low-temperature process. The desired end objective is synthesis gas production, one-step production of liquid oxygenates, or coupling products. Either oxygen or steam or both is used as a second reactant or reactants, to provide additional O atoms and initiate plasma-assisted radical processing. The present paper intends to investigate the various possible products/reactive species that are formed during plasma processing. In situ Fourier transform infrared (FTIR) absorption spectrometry is used to monitor the products/reactive groups. Experiments are performed at room temperature and at low energy inputs (50 kJ/(mol CH 4 )) in a gas mixture of CH 4 /O 2 /N 2 /H 2 O (atmospheric humidity). In the absence of oxygen, alkane, alkene, and alkyne groups are formed as the products, which indicates termination reactions. With increasing oxygen concentration (11, 15, and 33%) a gradual shift from alkane to a -CHO group is observed. In addition, alcohol group formation is detected with oxygen input, which indicates coupling between the CH 4 dissociation products and the O radicals as a primary step. The effect of higher energy input and the presence of catalytic surfaces such as platinum also are investigated.

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Nonthermal Plasma Processing for Air‐Pollution Control: A Historical Review, Current Issues, and Future Prospects

Kim

2004

Plasma Processes & Polymers

617

366

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Summary: This review describes the historical development, current status, and future prospects for nonthermal plasma (NTP) technology and its application as an air‐pollution control. In particular, this review focuses on the cutting‐edge technology of hybrid NTP, where it is combined with other methods such as wet processing, the use of adsorbents, and catalysis. Historical landmarks in the development of NTP technology and the current status of large‐scale applications are discussed. The general characteristics of the combined system of NTP with catalysts are described in the context of the decomposition of NOx and benzene.Comparison of different NTP reactors for 200 ppm benzene decomposition (water vapor 0.5 vol.‐%).magnified imageComparison of different NTP reactors for 200 ppm benzene decomposition (water vapor 0.5 vol.‐%).

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Design and Testing of a Prototype De-NO_xSystem for 100 kVA Diesel Engine Generator using a Silent Discharge Reactor

Cited by 16 publications

References 9 publications

Total Diesel Emission Control Technology Using Ozone Injection and Plasma Desorption

Total Diesel Emission Control Technology Using Ozone Injection and Plasma Desorption

In Situ Fourier Transform Infrared (FTIR) Study of Nonthermal-Plasma-Assisted Methane Oxidative Conversion

Nonthermal Plasma Processing for Air‐Pollution Control: A Historical Review, Current Issues, and Future Prospects

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Design and Testing of a Prototype De-NOxSystem for 100 kVA Diesel Engine Generator using a Silent Discharge Reactor

Cited by 16 publications

References 9 publications

Total Diesel Emission Control Technology Using Ozone Injection and Plasma Desorption

Total Diesel Emission Control Technology Using Ozone Injection and Plasma Desorption

In Situ Fourier Transform Infrared (FTIR) Study of Nonthermal-Plasma-Assisted Methane Oxidative Conversion

Nonthermal Plasma Processing for Air‐Pollution Control: A Historical Review, Current Issues, and Future Prospects

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Design and Testing of a Prototype De-NO_xSystem for 100 kVA Diesel Engine Generator using a Silent Discharge Reactor