1. Introduction
Ozone has been recently extensively applied as a potent oxidizing agent in many fields of science, technology and everyday life including chemical synthesis, semiconductor surface treatment, water disinfection, destruction of pollutants and odor removal, purification of products, decolorization (bleaching), vermin and insects control, automotive fuel afterburning, skin treatment and dental care, just to name a few [1,2,3,4]. However, at the same time, ozone is considered a highly toxic gas—its PEL (Permissible Exposure Limit) and REL (Recommended EL) health limits are as low as 0.1 ppm (0.2 mg/m3) while IDLH (Immediate Danger Lethal Dose) is set at 5 ppm [5]. Lowest lethal concentrations (LCLo) range from 4.8 ppm in rats (for 4 h exposure) to 50 ppm in humans (for 30 min contact) [6]. Ozone (discovered by F. Schoenbein in 1839) is a colorless or, at higher concentrations, pale blue gas containing three oxygen atoms in its molecule (O3), thus it is a triatomic allotrope of O2. It is highly unstable and readily reacts with other substances as a powerful oxidizer. In some references, it is regarded as odorless although other sources quote it as having “very pungent odor” or even “characteristic, pleasant odor” [6] (however, such inconsistency is rather related to secondary smell sensation caused by malodorous products of olfactory tissue oxidized by O3 than its primary olfaction). O3 is generated naturally in the Earth stratosphere by photolysis of molecular O2 by short-wave (λ < 200 nm) solar ultraviolet (UV) radiation, which produces excited oxygen O* atoms, undergoing binding collisions with O2 to form O3 molecules afterward.
O3 is also readily produced (in so-called three-body reaction, involving O, O2 and O3) in electrical discharges generated in pure oxygen or in atmospheric air and such processes are commonly applied in laboratory and industrial ozone generators. Such systems commonly make use of non-thermal plasma generated in dielectric barrier discharges (DBD), corona or surface discharges as it allows to attain elevated effectiveness of O3 generation process and to perform it on-demand and on-site, directly when and where ozone is required as it essentially cannot be effectively stockpiled [7].
Corona discharge (also referred to as pre-discharge) arises when the dielectric strength of a discharge gap is exceeded only locally in a strongly non-uniform electric field resulting in a situation when a discharge channel cannot develop into a spark or flashover discharge. It appears as a dim filamentary discharge emanating outward from the high voltage electrode of a small curvature radius. Corona discharge term is commonly used to describe discharges developing between gas-insulated bare metal electrodes without a solid dielectric involved however, some authors use this term in conjunction or even interchangeably with DBD [8]. Corona discharges exist in several forms depending on the electrode geometry and supply voltage type and polarity, including intermittent, glow, burst, pulse, pulseless, streamer and leader corona. Corona discharge may be generated using either DC or AC voltage although both types of pre-discharge differ in character. The term surface corona discharge (or creeping discharge) is used in a situation when the electrode configuration results in an electric field with a substantial tangential gas–solid interphase component and thus the corona discharges propagate (slide) along the interphase. A comprehensive study of topics related to corona discharge and its use in O3 making may be found in the relevant literature [8,9,10].
On the other hand, DBD (named also as silent discharge or ozonizer discharge) is also a non-thermal electrical discharge developing in a gas phase except that a layered barrier insulation system containing solid dielectric(s) is involved. In such configuration, a uniform (or slightly non-uniform) electric field is strong enough to produce a localized breakdown in the entire gas gap but not in the dielectric barrier. As such an arrangement can only pass the displacement current, DBDs are generated using AC electric supply. Volume DBD is in some way analogous to cavity discharge (internal partial discharge, PD) developing in a gaseous void inside a solid dielectric subjected to AC high voltage stress. To illustrate this analogy, a bird’s eye view photographs of the spatial distribution of DBD developing in a lens-like air gap formed in a polymeric body at various AC supply voltages are presented in Figure 1. In such an exotic gas cavity, taken after gas hollows present in voided ferroelectric material, DBD starts developing mostly near the rim of the void and tends to shift towards the void’s center as the voltage is ramped up [11].
Volume DBD at atmospheric pressure consists of a large number (ca. 106/cm2 s) of randomly appearing but spatially-localized short-lived (ca. 100 ns) microdischarges. They take the form of thin (ca. 100 μm wide) cylindrical columns (filaments) normal to the gas-dielectric interphase and developing into much larger footings at the dielectric exterior while individual columns are separated by a non-plasma gaseous medium. The microdischarge activity results in short (a few ns), high-frequency current pulse trains registered in the discharge circuit during each AC voltage raise period. In the filament mode, observed at elevated (atmospheric-like) pressure in most gases (including air) each weakly ionized microdischarge channel is formed by a fully-developed but transient glow discharge dissipating just microjoules of energy. Volume DBD channels contain thus non-thermal non-equilibrium plasma. Consequently, thermal effects of volume DBD related to gaseous medium heating are minute (typically below 10 °C is observed in the air in mm-range discharge gaps). The spatial and temporal DBD parameters depend on the supply power density while the strength of DBD is mainly determined by discharge gap width, gas properties (composition, pressure, humidity and flow rate) and dielectric barrier properties. Similarly to surface corona discharges, stable surface DBD (SDBD) may also be initiated over a dielectric surface using a tangential electric field shaped by a system of electrodes in creepage configuration located on opposite walls of a dielectric barrier. The electrodes may be partially or completely embedded in the dielectric or a three-electrode variation of such set-up may be used, which involves additional capacitively coupled floating-potential surface electrode. A detailed and comprehensive discussion of the DBD and SDBD physics, plasma chemistry, developments and applications may be found in the relevant literature [12,13,14,15,16].
Application of volume DBD for ozone production has been well-known for over a century as it was introduced by W. von Siemens already in 1857 in his air/oxygen-fed AC-energized ozone generator [17]. The original design consisted of two coaxial glass pipes forming a narrow annular gas flow channel in which silent discharges were sustained using alternating electric field formed by two electrodes located also coaxially but outside the discharge channel. Figure 2a briefly illustrates various flat and concentric electrode–barrier–gap configurations, commonly used in volume DBD while Figure 2b schematically outlines conventional SDBD electrode–barrier arrangements (including 2- and 3-electrode as well as uncovered and buried electrode designs).
A growing environmental awareness of air pollution originated from fuel combustion exhausts (of either internal combustion engines or gas burners) has resulted in research aiming at fuel-burning performance improvement relying on combustion promotion attained by means of plasma/ozone processing of the intake air [18,19,20]. The latter may be realized in an automotive application using by-pass scheme DBD (exemplified in Figure 3) however it requires effective yet energy- and space-constrained air-fed non-thermal plasma and ozone generator. Thus, experimental verification of the electrical and thermal performance of a newly-designed volume DBD flow-through ozone generator (OG) of a spiral-tubular electrode design was presented in relation to a conventional volume cylindrical DBD as well as a commercial OG making use of SDBD generated in a floating electrode arrangement (advertised by its supplier as having amazingly high 8 g/h O3 production). Improvement of O3 generation effectiveness through high voltage (HV) electrical supply tuning was also investigated and discussed.
2. Materials and Methods
A volume DBD OG of a tubular design, shown in Figure 4a, consisted of a metallic inner HV rod electrode (∅18x250 mm) enclosed inside a silica (SiO2) glass tube (∅20/∅25 mm) providing a 1 mm wide flow-through tubular gas channel, connected to gas ports, installed at end caps of the tube (as detailed in Figure 1a upper inset). The inner rod electrode was made either of brass (EN-CW617N grade) or duralumin (EN-2017 grade); in the latter case, its surface was covered with anodic-deposited Al2O3 layer. The silica glass tube was fitted with a grounded (GND) electrode made of Sn-platted thin Cu foil with a conductive adhesive layer (1183, 3M). It was firmly affixed to the silica tube external wall leaving no air bubbles at the Cu-SiO2 interphase. Foil electrodes of a cylindrical as well a spiral design (as detailed in Figure 4a) were investigated; in each case 20 mm clearance between the foil electrode and the HV electrode metallic end caps ensured no surface sliding discharges in this area. The volume DBD OG was operated in a horizontal position with no forced cooling.
A commercial surface DBD OG (Sihon Ozone, China), used for comparative study, was claimed by its manufacturer to produce 8.0 g/h O3 thanks to intensive surface DBDs generated in floating three-electrode arrangement. Metal-ceramic OG, shown in Figure 4b, consisted of two 1.3 mm thick duralumin (of unknown make) electrodes spaced by 5 mm and embedded in 2.8 mm thick alumina body forming 106x54x2.8 mm OG composite plate. The OG plate was fitted at both alumina faces with two 0.2 mm thick stainless steel, unprotected slotted electrodes (as drafted in the schematic cross-section shown in Figure 4b). Laboratory tests were conducted using two such SDBD OG plates collocated one over another, spaced vertically by 10 mm and placed in a hermetic metal vessel fitted with gas and electric supply ports.
Both tested OGs were supplied with unprocessed (not dehumidified) atmospheric laboratory air at 23–25 °C and 42%–45% RH (exemplifying commonplace laboratory conditions). The airflow rate was controlled using either a mass flow controller (F-201-CV, Bronkhorst) or a flow meter (SD6000, IFM Electronik), depending on the operational airflow rate. In low flow rate experiments (1.0 Nl/min) the entire gas stream was passed through the O3 analyzer while at moderate flow rates (10–100 Nl/min) the air-O3 output stream was sampled at 1.0 Nl/min (as required by the O3 analyzer).
O3 concentration was monitored using a photometric analyzer at 254 nm UV radiation (BMT964, BMT Messtechnik), it was thus insensitive to N2, H2O or NOx. O3 volumetric concentration was expressed in ppmv and all data (including flow rates expressed in Nl/min) was corrected for normal 1 atm and 0 °C conditions (expressing O3 concentration in volumetric (ppmv)=0.0001 (%v/v) is unambiguous and it does not require information on the carrier gas density as in case of (%wt/wt) [21]. The temperature of the OG was monitored using a metal sheath K-type thermocouple attached directly to one of its electrodes while thermal imaging camera (i3, Flir) was also used to monitor the silica glass tube temperature in case of the spiral-tubular OG assay.
Commercial surface DBD OG was electrically supplied using either its build-in HV power supply (~230 V mains-operated) or a laboratory variable sinusoidal HV supply system consisted of Agilent 33521a signal generator and Trek 20/20C HV amplifier. Only the latter laboratory HV supply set-up was used in case of the volume DBD OG of the spiral-tubular design. HV electric supply parameters were recorded using a digital oscilloscope (MSO2014, Tektronix) fitted with 1:1000 HV probe (HP 1137A) for HV (peak value) measurement and 1:10 probe (P1110, Tektronix) interfaced to 98.0 nF low loss capacitor connected in series with DBD OG for charge measurement. All experimental data points presented if the figures were supplemented with dashed lines drawn to guide the eyes only, thus indicating no intended numerical data fit. 3. Results 3.1. Volume Spiro-Tubular DBD OG Design
The initial experiments involving the volume tubular DBD OG employing a brass internal axial HV electrode and a solid outer cylindrical Cu foil electrode were run at a low airflow rate (1.0 Nl/min). Figure 5a shows the recorded dependence of O3 production on the 10 kV HV supply frequency. Increasing supply frequency steadily escalated O3 throughput however, for a given airflow rate and the supply voltage, there was an optimal frequency of 700 Hz resulting in the maximized O3 production reaching 3350 ppmv. Further increase of the supply frequency resulted in the temperature rise bringing about O3 concentration decline due to the predomination of O3 thermal destruction over DBD ozone generation. The O3 output was therefore mainly limited by the processed gas temperature, translated to the outer silica glass surface temperature of 40 °C in the optimal conditions for a given airflow rate, HV supply and internal electrode material.
Additional O3 generation enhancement was achieved due to geometry-related management of DBDs and O3-synthesis zones illustrated experimentally in Figure 5b for 1.0 Nl/min airflow and 10 kV sinusoidal HV supply. The spiral design of the outer GND electrode unambiguously enhanced O3 throughput. By varying its width and pitch it was possible to increase the maximal O3 concentration from 3550 ppmv at the optimal 2.8 kHz and 7/32 mm width/pitch up to 3980 ppmv at the optimal 1.2 kHz and 19/35 mm width/pitch. Thus, an almost 19% increase in O3 production was attained at the cost of 71% supply power rise comparing to the solid Cu foil electrode (as the active supply power was directly proportional to the frequency). On the other hand, geometrical tweaking and supply power rise resulted in only a moderate increase of the overall process temperature, manifested in the silica glass tube temperature reaching 45 °C at the optimal O3 yield conditions (Figure 5b).
Further ozone concentration enhancement was brought in by fitting the discussed volume DBD OG with an alumina-covered HV internal axial electrode. While such modification was introduced a steady production of 4180 ppmv O3 at 1 Nl/min airflow (corresponding to 0.54 g/h O3) was commenced at optimized 10 kV 1.6 kHz sinusoidal HV supply and 19/35 mm outer spiral electrode, as illustrated in Figure 6a. O3 production in such circumstances required 8.1 W of active supply power (as verified using measurement method based on voltage–charge V-Q Lissajous curve) and resulted in 0.09 W/cm2 active power surface density translated into the maximal silica glass tube temperature of 46 °C and 67 g/kWh O3 generation efficiency.
Experiments run at moderate airflow brought about even lower silica glass tube temperature which dropped to 33 °C at 100 Nl/min and 1.6 kHz 10 kV HV power supply (delivering 8.8 W active power at 0.1 W/cm2 power surface density) as shown in Figure 6b. It such conditions production of O3 decreased to 64 ppmv (corresponding to 0.82 g/h O3 production and 93 g/kWh efficiency).
3.2. Surface DBD OG Design
In contrast to appealing experimental results presented so far for the volume DBD OG with a spiral electrode design, the examined commercial SDBD OG performed very feebly. Figure 7a illustrates variations of O3 concentration and electrode temperature recorded for the surface-type DBD OG two-plate unit supplied using its build-in mains-operated HV power supply at low air intake (1 Nl/min). Although the HV-supply energization triggered an abrupt rise of its O3 output up to 2035 ppmv, however, as the electrode temperature exceeded 29 °C, it started to decline and reached 12 ppmv at 48 °C and finally no O3 was produced when temperature of the OG electrodes exceeded 90 °C after just 120 s of its operation. Thus, the commercial surface DBD OG design produced expedient amounts of O3 at low airflow only when the temperature of its composite plates was below 48 °C but, on the other hand, if it was running on the build-in HV power supply longer than approximately 1 min generation of O3 was completely brought to a standstill. At moderate air flowrate (as illustrated in Figure 7b) O3 generation became unremitting. Its concentration remained very low (5–6 ppmv) up to 25 Nl/min and then over 30 Nl/min escalated up to 59 ppmv observed at 100 Nl/min. It corresponded to 0.76 g/h of O3 throughput at 100 Nl/min flow rate, which was over 10 times lower than the value quoted by the SDBD OG manufacturer.
Although elevated airflow rate facilitated cooling of the SDBD OG plates, even at 100 Nl/min their temperature exceeded 90 °C. Thus, even running the commercial SDBD OG at a high airflow rate, which was actually endorsed by its manufacturer, did not help in attaining the manufacturer-certified O3 production. The observed swift rise of the SDBD OG temperature and its excessive final value was related to dense surface discharges sliding on its alumina exposed surface (Figure 8a) and to excessively high active supply power furnished by the original mains-operated HV supply (operating at 6.2–6.5 kV 19.1 kHz distorted sinusoidal voltage and delivering from 90 to 113 W).
Conversely, the ill-performing commercial SDBD OG was made to steadily produce 1115 ppmv O3 at 1 Nl/min airflow (corresponding to 0.14 g/h O3) when energized using purely sinusoidal HV supply at optimized 6.0 kV 1.1 kHz. Active power consumption of the SDBD OG in such a supply regime reached merely 7.4 W, which was equivalent to 18.9 g/kWh O3 yield. In such a supply regime, O3 generation was optimal when the temperature of the SDBD plates was kept below 50 °C. Although similar experiments run at moderate airflow rates, illustrated in Figure 8b, led to further reduction of the DBD plate temperature down to 30 °C at 100 Nl/min airflow yet the O3 concentration plummeted in this conditions to 29 ppmv, corresponding to 0.37 g/h.
4. Discussion
The stability of gaseous O3 is strongly temperature-, gas velocity- and humidity-dependent as its half-life time is reduced from approximately 1500 min (at 24 °C, 0% RH and no gas movement) to approximately 800 min at 40 °C, to approximately 700 min at 45% RH and to approximately 210 min at 100 m3/h gas streaming [22]. Thus, if the relative humidity of the supply air is not varied significantly, correct thermal management of the OG operated at low gas velocity is mandatory when its optimal performance is targeted. As it was experimentally shown, tweaking the HV supply enabled effective thermal control of the volume DBD OG and its performance optimization. However, its extent was limited by self-cooling of the volume OG as no forced cooling was intended to be put into operation in the tested design.
The spiral design of the outer GND electrode enhanced O3 throughput. First of all, spiral electrode geometry resulted in boosting O3 production by keeping the process temperature at a moderate level at increased power supply conditions due to decreased volume in which discharge-generated heat transfer was commenced. However, it has also created recurring discharge-reach and discharge-free zones. Even narrowed discharge regions provided effective O2 dissociation into excited O* atoms due to the fast nature (ns time scale) of electron and ion collision ionization processes. When conveyed to the discharge-free zones, O* atoms were effectively recombining with O2 to form O3 and this process was not interfered with by the discharges. A high density of discharges and thus generation of excessively energetic and concentrated excited species is known to lead to unfavorable recombination of O* into diatomic O2 (resulting in no O3 production) as well as to the reaction of O3 with O* and electron-triggered dissociation of O3 leading to the destruction of already formed O3. According to Kitayama and Kuzumoto, the dissociation rate of O3 is 6–8 times higher than the dissociation rate of O2 molecule in the discharge channel [23]. Moreover, as the spiral design of the electrode system resulted in a subsided volume in which DBD non-thermal plasma was ignited, it may be accounted for diminished generation of atomic nitrogen N* (originating from electron impact dissociation of N2). Thus, less NO and NO2 nitrous oxides would be formed and therefore so-called autocatalytic cycle for O3 destruction [24] would be less sizable (however such stipulation has not been verified experimentally in the presented research).
All those detrimental processes are electron energy- and temperature-amplified and decrease the overall effectiveness of O3 formation. Thus, the geometrical introduction of discharge-free zones (supplying no energy to electrons and ions and providing moderate temperature) but still reach in the active oxygen atoms favored global O3 synthesis effectiveness. To address the above remarks, electrostatic and conjugated heat transfer finite element method (FEM) simulations were performed using the Comsol Multiphysics software package. The volume DBD OG design (with optimized 19/35mm spiral electrode width/pitch) was simplified by representing the outer helical electrode as 5 rings of the same total surface area separated by 16 mm distance (thus furnishing the same surface power density and similar heating and cooling conditions) while other dimensions of the model were kept analogous to the real design. Figure 9a illustrates simulated static electric field distribution in the volume DBD OG axisymmetric cross-section constrained to one of the outer electrode segments at the maximal 10 kV supply voltage. In order to better visualize the DBD region, Figure 9b expands the inter-electrode area in which the electric field was shown only in the region where the air breakdown strength of 4.37 MV/m was surpassed (as calculated for 1 mm discharge gap and 1 atm pressure according to Hussain and Nema [25]). As might be expected, the DBD region was limited merely to the ring-like sub-volume of the flow-through tubular gas channel zoned by the outer foil electrode.
For the purpose of the conjugated heat transfer FEM simulation, it was stipulated that only those inter-electrode ring narrow gas volumes were the sources of the heat generated by DBD and that the entire active supply energy was converted into heat in those volumes. Simulation results obtained for such a simplified model were shown in Figure 10a for the case of 1 Nl/min laminar airflow and 8.1 W active supply power. The simulated temperature of the outer silica surface was generally lower than that registered experimentally; 45 °C was modeled in the locations in the middle between the last two ring electrodes (at the point marked with X in Figure 10a) while 46 °C was observed experimentally in the corresponding location in the middle between the last twist of the real helical electrode. Similarly, underestimated temperature data was obtained when the simulation was run at 100 Nl/min air flow rate yielding 29 °C (as shown in Figure 10b) while 33 °C was registered empirically. The negative temperature bias discovered in both simulation cases might be related to the overestimated natural cooling modeled by the mean heat transfer coefficient (3.5 W/m2 K) of the outer silica glass and copper electrode surface as well as to their overrated radiative cooling. The turbulent airflow conditions (which exist in the real tubular pneumatic system at 100 Nl/min air flow rate) have also not been taken into account in the FEM simulation.
There are literature references related to catalytic effects of Al2O3 in DBD ozone synthesis, however, such effects are pronounced in packed-bed-type ozonizers or if surface discharges are employed [26,27]. However, as it was verified experimentally a perceptible catalytic action of Al2O3 was also perceived in the presented volume-type DBD OG, accounting for approximately 5% increase in its performance in relation to the non-catalytic scheme using a brass internal electrode. As the optimal process temperature (manifested by the silica tube temperature) was almost identical in both cases (brass- and alumina-covered electrode) thus it seems to be justified that Al2O3 surface catalytic action was not temperature-activated in this low-temperature region.
On the other hand, the operation of a popular commercial SDBD OG was mostly bringing about thermal destruction of O3. Very high active power consumption as well as the vigorous surface discharges advancing on the alumina plate exterior were responsible for the observed excessive thermal effects. Taking into account the estimated surface area covered by surface discharges (approximately 2.7 cm2; calculated using digitally processed discharge image shown in Figure 5a inset) it was translated to 33–42 W/cm2 active power density (a value comparable to power density used in electrical resistive water heaters [28]) and thus low O3 generation efficiency of 8.4 g/kWh.
5. Conclusions
The presented spiral-electrode volume DBD OG operated at active power surface density 0.09–0.1 W/cm2 achieved 67 g/kWh O3 generation efficiency at low airflow rate (1 Nl/min) while at high airflow (100 Nl/min) its efficiency crested at 93 g/kWh. Those experimentally determined values are higher than figures of merit cited in the literature for photocatalytic DBD ozone generator designs and similar airflow rates [16,29]. However, as the obtained results are still 2–4 times lower than the maximal efficiency predicted by theoretical calculations (200–280 g/kWh, depending on the estimating methodology summarized in [30]) further optimization is still possible through research involving other photocatalyst selection as well as HV impulse supply.
Surprisingly, a commercially popular SDBD ozone generator, habitually yet incorrectly so-called “corona ozone generator” performed very feebly and proved to be very energy-ineffective and far from the manufacturer-stated ozone output yield due to its high operational temperature.
Enlarge this image.Figure 1. Spatial distribution of DBD developing in a lens-like 1.1 mm high and 16 mm in diameter air gap formed in 2.1 mm thick polyethylene terephthalate polyethylene terephthalate (PET) body at various 100 Hz AC supply voltages (peak value).
Enlarge this image.Figure 2. Schematic representation of various DBD electrode-barrier arrangement:(a) volume DBD, (b) surface DBD (drawings not to scale).
Enlarge this image.Figure 3. Hardware approach to process automotive engine intake air using manifold by-pass and non-thermal plasma/ozone generated in: (a) volume DBD, (b) SDBD.
Enlarge this image.Figure 4. DBD OGs: (a) volume flow-through arrangement of a spiral-tubular design, (b) surface three-electrode metal-ceramic plate - a real view and schematic cross-section (drawings not to scale).
Enlarge this image.Figure 5. Variations of O3 concentration and temperature in the volume DBD OG fitted with the internal brass electrode and outer Cu foil electrode of (a) solid design, (b) spiral design (supplied using variable-frequency 10 kV sinusoidal high voltage (HV) power supply at 1 Nl/min airflow).
Enlarge this image.Figure 6. Variations of O3 concentration and temperature in the volume DBD OG fitted with Al2O3-covered internal and 19/35mm width/pitch spiral outer Cu electrode supplied using 10 kV sinusoidal HV power supply: (a) at 1 Nl/min airflow, (b) at moderate airflow and 1.6 kHz HV power supply.
Enlarge this image.Figure 7. Variations of O3 concentration and electrode temperature in surface DBD OG supplied using the build-in mains HV power supply at (a) 1 Nl/min air flow rate, (b) at moderate airflow.
Enlarge this image.Figure 8. Surface DBD OG: (a) discharge pattern (real image and its digitally-processed section used for real discharge area calculation), (b) variations of O3 concentration and electrode temperature at moderate airflow and optimized sinusoidal 6 kV 1.1 kHz HV power supply.
Enlarge this image.Figure 9. Electrostatic finite element method (FEM) simulation results for a simplified volume DBD OG model: (a) electric field distribution at 10 kV HV supply, (b) air gap breakdown section corresponding to Paschen air breakdown strength at 1 atm and 1 mm gap (spatial dimensions in mm).
Enlarge this image.Figure 10. Thermal FEM simulation results for a simplified volume DBD OG model: (a) temperature distribution for 1 Nl/min airflow and 8.1 W active power supply, (b) for 100 Nl/min and 8.8 W (all spatial dimensions in mm).
Funding
This research was financed by the subsidy of the Department of Electrical Engineering Fundamentals of the Wroclaw University of Science and Technology, under project number 049U/0004/19.
Conflicts of Interest
The author declares no conflict of interest.
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Pawel Zylka
Department of Electrical Engineering Fundamentals, Wroclaw University of Science and Technology, Wyb. Wyspianskiego 27, 50-370 Wroclaw, Poland
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