Microwave attenuation in forest fuel flames

Mphale, Kgakgamatso; Luhanga, P.V.C.; Heron, M.L.

doi:10.1016/j.combustflame.2008.07.006

Cited by 19 publications

(10 citation statements)

References 27 publications

(36 reference statements)

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“…Of the organic compounds found in black liquor, sodium and potassium are alkaline, and thus have low excitation energy. Consequently, they are highly combustible and when ignited create extra ionisation, which affects radio and microwave propagation, both attenuating and changing the phase of the signal [18].…”

Section: Conditions Inside Boiler Furnacesmentioning

confidence: 99%

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Microwave spectra inside the combustion chamber of a kraft recovery boiler – effects on communications

Korhonen

Ahola

2017

IET Science, Measurement & Technology

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Section: Conditions Inside Boiler Furnacesmentioning

confidence: 99%

“…Attenuation due to the medium, although indirectly affecting the measured spectrum, is omitted from this study. The attenuation of radio waves in flames at lower frequencies has been extensively studied in many articles [16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Microwave spectra inside the combustion chamber of a kraft recovery boiler – effects on communications

Korhonen

Ahola

2017

IET Science, Measurement & Technology

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“…With flames burning 10 days dried forest fuel, the attenuation was ranging at frequency band 10-12.5 GHz from 9 to ∼6 dB/m with eucalyptus litter, from 7 to ∼4.8 dB/m with grass, and 4 to ∼3 dB/m with pine litter, respectively. The results were measured at temperatures of 730-1000 K [8]. At higher frequencies from 30 to 60 GHz, at temperatures of 1000 K, the attenuation in scrub fires ranged from 0.06 to 0.7 dB/m.…”

Section: Introductionmentioning

confidence: 98%

“…The attenuation in combustion environment consists of typical scattering mechanisms such as attenuation due to free space loss [2,3], reflections [4], refraction [5], and multipath propagation [6,7]. In addition to these scattering mechanisms, attenuation due to charge collisions and ionisation exist in high-temperature flames [8].…”

Section: Introductionmentioning

confidence: 99%

Microwave attenuation in kraft recovery boiler

Korhonen

Ahola

2018

IET Microwaves, Antennas & Propagation

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The authors' research group is developing a mobile sensor for operation inside combustion chambers of big industrial power plants. The aim of developing the ball‐formed sensor is to measure process information inside big combustion chambers (heat power over 100 MW), hopefully mainly from places which cannot be reached by ordinary measurement equipment outside the chamber. The sensor ball needs means for communication during operation. In order to provide a reliable communication link through the extreme harsh conditions, one must clarify the basic phenomena inside combustors, especially electromagnetic noise and attenuation. According to measurements, attenuation at frequency band 2–18 GHz is ∼10 dB/m.

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“…The conductor-to-ground short-circuiting caused by conductive wildfires is responsible for a number of the power outages in many countries [31]. The failure to maintain radio communication at HF to UHF during wildfire suppression is also a safety concern for fire fighters [32]. In a similar vein, spacecraft and vehicles traveling at hypersonic velocities within Earth's atmosphere become enveloped by a plasma layer which attenuates microwave and radio signals, leading to 'radio blackout' [33].…”

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confidence: 99%

Electrical conductivity of the thermal dusty plasma under the conditions of a hybrid plasma environment simulation facility

et al. 2015

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We discuss the inductively heated plasma generator (IPG) facility in application to the generation of the thermal dusty plasma formed by the positively charged dust particles and the electrons emitted by them. We develop a theoretical model for the calculation of plasma electrical conductivity under typical conditions of the IPG. We show that the electrical conductivity of dusty plasma is defined by collisions with the neutral gas molecules and by the electron number density. The latter is calculated in the approximations of an ideal and strongly coupled particle system and in the regime of weak and strong screening of the particle charge. The maximum attainable electron number density and corresponding maximum plasma electrical conductivity prove to be independent of the particle emissivity. Analysis of available experiments is performed, in particular, of our recent experiment with plasma formed by the combustion products of a propane-air mixture and the CeO 2 particles injected into it. A good correlation between the theory and experimental data points to the adequacy of our approach. Our main conclusion is that a level of the electrical conductivity due to the thermal ionization of the dust particles is sufficiently high to compete with that of the potassium-doped plasmas. emission, photoemission, and thermionic emission [15-18]. It is possible in some cases for these emitted electrons to be major contributor to the electron density within the plasma, such as for UV-induced dusty plasmas [19,20], or in flames, where the thermionic emission from carbonaceous soot elevates the electron density by several orders of magnitude [21,22]. For a comprehensive discussion of these plasma types, see the review [23] and references therein. Recent studies based on the treatment of quantum states of the surplus electrons near the surface of charged particles make it possible to calculate such quantities as the electron sticking coefficient and desorption time, to account for the infrared extinction of dielectric particles etc [24][25][26][27].The characteristics of such complex plasmas have implications for applications as disparate as understanding volcanic eruptions, the explosiveness of dust clouds and powders, communications, wildfires, rocket propulsion, and fusion energy. Lightning associated with volcanic plumes is a direct result of the electrification of the particulate matter within the plume. As these particles are transported over large distances, the electric potentials which develop lead to lightning discharges. The electrical activity of volcanic eruptions is a possible method to monitor volcanic activity, both here on earth and on exoplanets [28]. Many industries handle large amount of powders such as paint, chemical fertilizer, grain powder, starch, detergent. As airborne dust particles become charged, a spark introduced into the system can ignite an explosion [29]. Care must be taken during transport to mitigate the effects, which can lead to accidental dust explosions [30]. Wildfires are weakly ionized ga...

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Microwave attenuation in forest fuel flames

Cited by 19 publications

References 27 publications

Microwave spectra inside the combustion chamber of a kraft recovery boiler – effects on communications

Microwave spectra inside the combustion chamber of a kraft recovery boiler – effects on communications

Microwave attenuation in kraft recovery boiler

Electrical conductivity of the thermal dusty plasma under the conditions of a hybrid plasma environment simulation facility

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