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Pulverized sponge iron, a zero-carbon and clean substitute for fossil coal in energy applications Henrik Wiinikka, Therese Vikström, Jonas Wennebro, Pal Toth, and Alexey Sepman Energy Fuels, Just Accepted Manuscript • DOI: 10.1021/acs.energyfuels.8b02270 • Publication Date (Web): 16 Aug 2018 Downloaded from http://pubs.acs.org on August 24, 2018
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Energy & Fuels
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Pulverized sponge iron, a zero-carbon and clean substitute for fossil coal in
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energy applications
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Henrik Wiinikka,ab* Therese Vikström,a Jonas Wennebro,a Pal Toth,ac and Alexey Sepmana
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a
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RISE Energy Technology Center AB, Division of Bioeconomy, RISE Research Institutes of Sweden, Box 726, SE-941 28, Piteå, Sweden
6 b
7 8
c
Division of Energy Science, Luleå University of Technlogy, SE-971 87, Luleå, Sweden
Department of Combustion and Thermal Energy, University of Miskolc, Miskolc-Egyetemvaros,
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H3515 Hungary
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*Corresponding author:
[email protected] 11 12
ABSTRACT:
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The direct combustion of recyclable metals has the potential to become a zero-carbon energy
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production alternative, much needed to alleviate the effects of global climate change caused by
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the increased emissions of the greenhouse gas CO2. In this work, we show that the emission of
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CO2 is insignificant during the combustion of pulverized sponge iron, compared to that of
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pulverized coal combustion. The emissions of the other harmful pollutants NOx and SO2 were 25
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and over 30 times lower, respectively, than in the case of pulverized coal combustion.
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Furthermore, 96 %wt. of the solid combustion products consisted of micron-sized, solid or
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hollow hematite (α-Fe2O3) spheres. The remaining 4 %wt. of products was maghemite (γ-Fe2O3)
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nanoparticles. According to thermodynamic calculations, this product composition implies near-
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complete combustion, with a conversion above 98%. The results presented in this work strongly
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suggest that sponge iron is a clean energy carrier and may become a substitute to pulverized coal
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as fuel in existing or newly designed industrial systems.
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Keywords: metal combustion, sponge iron, maghemite, coal combustion, 1 ACS Paragon Plus Environment
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1. INTRODUCTION
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Transitioning to clean, zero-carbon, renewable-based energy production technologies is essential
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in order to reduce greenhouse gas emissions from fossil fuel use in fulfilment of the Paris
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Agreement goals in order to alleviate the effects of global climate change.1-3 Solar-, wind- and
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hydropower can eliminate the need for fossil fuels in electricity generation;4 however, the storage
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and transportation of the renewable-based energy from the production site to the end-users
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remain challenging. Recyclable metals have the potential to become storage and carrier materials
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of renewable-based energy .5-7 Fig. 1A shows a proposed cycle of metals in energy production.
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The metal powder is combusted in air, producing heat and power in-situ in areas with high energy
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demand. In principle, no combustion products are formed apart from the solid metal oxides. Once
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combusted, the metal powder can be regenerated by direct reduction using electrolytic hydrogen
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(H2) in regions where renewable electricity is abundant. With respect to energy density (MJ/dm3),
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metal powder energy carriers outperform batteries and liquid H2 (Fig. 1B, Table S1), higher
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energy density (MJ/dm3) of the metal fuels will which facilitate long distance transportations by,
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for example merchant ships (tankers and cargo vessels) or railway. Benefits of metal powders as
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energy carriers over liquid H2 can include secure handling and less stringent safety requirements.6
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Among possible metal fuel candidates (e.g. aluminum,9 magnesium,10 lithium11), iron has been
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suggested as the optimal carrier since it is thought to combust in solid state without forming any
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metal vapor, gaseous oxides or nanoparticles;6 hence, the resulting combustion products are
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easily separable and a micron-sized oxide fraction can be recovered from the product stream.
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Another significant benefit of using iron as an energy carrier is that reduction technology is
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already commercially available: for example, the direct reduction (DR) process that converts iron
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ore in the form of fines, pellets or sinter into sponge iron at a temperature well below the melting
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point of the iron itself,12 held a share of 73 Mt of global iron production in 2016.13 In general, the 2 ACS Paragon Plus Environment
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DR process uses carbon monoxide (CO) and H2 from natural gas reforming as reducing agents.12
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However there are also technologies that use H2 exclusively as a reducing agent.14 In the future,
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the direct reduction of iron by using H2 from solar-powered water electrolysis will likely become
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feasible with prices similar to that of steam-reformed H2 produced from natural gas15 – in this
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case, the reduction process in the metal fuel cycle will also be zero-carbon. Preliminary
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theoretical investigation has shown that the sponge iron system can be more efficient in storing
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and transporting renewable-based energy than systems of other energy storage media, such as
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liquid H2.16 One of the challenges in implementing an iron-based, zero-carbon energy system is
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the lack of industrial devices that can combust the iron fuel.6 Assuming that existing combustors
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can be retrofitted or used without modification for the combustion of pulverized sponge iron
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(PSI), the scale of benefits of transitioning to an iron-based energy system can be estimated: for
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example, the wide-scale replacement of pulverized coal (PC) with PSI in existing combustion
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facilities can significantly reduce global CO2 emission, considering that in 2014, 46% of global
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CO2 emissions originated from coal combustion.17 The combustion of micron-sized iron particles
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(3-27 µm) has been demonstrated, showing that flame speeds in PSI flames are similar to those in
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hydrocarbon flames.18 Combustion of iron nanoparticles (25-85 nm) has also been investigated in
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enginelike conditions.19 However, the combustion of PSI with technically relevant particle sizes,
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in the context of becoming a practical substitute for PC, has not been investigated before. Known
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results regarding iron-based oxygen carriers20,21 from the chemical-looping combustion (CLC)
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and chemical-looping reforming (CLR) fields, obtained using fluidized bed reactors are not
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directly applicable to pulverized fuel combustion due to the significantly higher temperatures and
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heating rates of powder combustion. The objective of this work was therefore to assess if PSI can
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replace PC in large-scale energy applications by studying the combustion behavior of PSI and
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comparing it with that of PC. The typical combustion environment inside a PC boiler was 3 ACS Paragon Plus Environment
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modeled by using a small-scale entrained flow reactor. Similar reactors have been routinely used
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before to investigate many aspects of PC combustion.22-29 Combustion behavior and emissions
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were compared to those of PC.
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2. EXPERIMENTAL
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2.1. Combustion experiments. The combustion experiments were performed in a small scale
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entrained flow reactor (EFR), see Fig. 2. The EFR consisted of a 2 m long alumina (Al2O3) tube
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with an inner diameter of 50 mm installed in an electrically heated (SiC heating element) vertical
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tubular furnace (Entech Energiteknik). The EFR was designed to operate at temperatures up to
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1400°C using five individually controlled heating zones (each 354 mm long). The powder was
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injected pneumatically into the EFR with a syringe particle feeder30 installed above the EFR. The
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powder transport gas (N2) flow rate (1 NL/min) was controlled by a mass flow controller (MFC).
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The particle injection tube, which was installed in the center of the EFR had an inner diameter of
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6 mm and was encased in a water-cooled jacket with an outer diameter of 16 mm. The oxidizer (a
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mixture of N2 and O2) was injected into the EFR outside the particle injection tube. Before
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entering the EFR, the oxidizer passed a flow straightener made of a sintered porous disk (1.6 mm
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thick). The amount of N2 and O2 was controlled by two MFC’s that supplied gas in the ranges of
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0-5 NL/min and 0-50 NL/min for for O2 and N2, respectively.
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After the EFR, the flue gas passed through a pre-cyclone (Dekati) which separated particles
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with an aerodynamic diameter above 10 µm from the flue gas. The particle separated in the pre-
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cyclone is hereafter referred as solid residues. After the pre-cyclone, a small portion of the flue
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gas flow was withdrawn from the flue gas channel and analyzed with respect to CO2, CO, H2O,
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NO and SO2 by a Fourier Transform Infrared Spectroscopy (FTIR) instrument (MKS 2030-HS).
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The O2-content in the same slip stream was analyzed by using a lambda sensor. Another 4 ACS Paragon Plus Environment
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representative portion of the flue gas flow was sampled from the same location in the flue gas
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channel, diluted approximately 50 times with N2 in two steps (Dekati) and analyzed with respect
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to particle concentration and particle mass size distribution with a 30 L/min multi-stage, low
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pressure impactor (LPI). The LPI (Dekati) was designed according to the principle of inertial
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impaction.31 The LPI separated particles from the gas according to their aerodynamic diameters
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in 13 stages from 0.03 to 10.7 µm.32 The particles, collected in the LPI is hereafter referred to
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fumes since most of them are most like produced from condensation of inorganic vapor as
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discussed later in this paper.
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2.2. Fuels and experimental conditions. Two commercially available sponge iron powders,
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delivered by Höganäs (Iron A) and Alibaba (Iron B), were used as fuel in this work. A
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bituminous coal was used as a reference fuel. The morphology (SEM micrographs) and chemical
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composition of the fuels are presented in Table 1.
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Operational parameters of the EFR are summarized in Table 2. The amount of O2 supplied
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with the combustion air approximately corresponded to an excess air ratio (λ) of 2 for all studied
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fuels. Theoretically, in stoichiometric combustion (λ=1), all Fe is oxidized to the most stable iron
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oxide form, Fe2O3. The same thermal power, ~310 W, was supplied to the EFR independent of
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the fuel. The EFR was operated at a temperature of 1200°C during all experiments. The λ used in
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this experiment is slightly larger than what would be expected during industrial combustion in of
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PSI and PC performed in a highly turbulent flow. The reason for the larger λ is the low
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turbulence level in this small scale experiment (Reynold number ~ 70) and therefore more O2 is
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made available in order to secure that oxidation rate in the EFR is not limited by mixing and
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instead controlled by reaction kinetics.
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2.3. X-ray powder diffraction (XRD). X-ray powder diffraction (XRD) was used for the
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identification of possible crystalline phases in the iron oxide solid residue and fumes. Both Umeå
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University (UmU) and ALS Global (ALS) independently analyzed the solid residue from PSI
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combustion with an XRD instrument equipped with a CuKα radiation source. The fumes from
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PSI combustion were only analyzed by UmU. Particulate matter samples collected on the
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impactor plates 4-6 with a d50 size cut of 0.160-0.400 µm were analyzed together in order to
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obtain a sufficient sample size. The quantification (wt-%) of the identified crystalline phases was
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carried out by using the Rietveld method.33
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2.4. Wet chemistry analysis. Complementary quantification of the amount of Fe, FeO, Fe3O4
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and Fe2O3 compounds in the solid residue samples were also determined by an inhouse wet
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chemistry analytic method (titration). The analysis was performed by Luossavaara-Kiirunavaara
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AB (LKAB), the largest supplier of iron ore pellets in Europe. The average results and the
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standard deviation from these three independent measurements (2 from XRD and 1 from
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titration) are presented in the paper.
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2.5. Scanning Electron Microscopy (SEM). The fuels (iron and coal powders), the solid
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particles collected in the pre-cyclone and the particulate matter collected on the impactor plates
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were characterized with respect to morphology and elemental composition by Scanning Electron
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Microscopy (SEM, model Hitachi TM3030 plus) equipped with an energy disperse spectroscopy
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(EDS) detector (Bruker Quantax 70).
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2.6. Transmission Electron Microscopy (TEM). Iron oxide nanoparticles were imaged and
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analyzed in a transmission electron microscope (TEM, Jeol JEM 2100F) equipped with an energy 6 ACS Paragon Plus Environment
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dispersive X-ray spectrometer (EDS, JED 2300). Images were recorded by using a bottom
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mounted CCD camera (Gatan, Ultra Scan) operated using the Digital Micrograph program
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package. The chemical composition of observed particles was determined by spot measurements
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by using a focused beam. The diffraction mode was used to confirm the appearance of crystallites
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in the materials which were then imaged in dark field mode.
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2.7. Thermodynamic equilibrium calculations (TEC’s). In order to interpret the experimental
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results, thermodynamic equilibrium calculations (TEC’s) were performed by using the
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equilibrium module (Gibbs energy minimization) in FactSage™ 6.4.34 In general, the
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thermodynamic model calculates the composition of the product gas and inorganic components
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as a function of temperature. However, in FactSage there is also an option to specify the standard
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enthalpy of formation, ∆hf (J/mol) for the reactants, and solve directly for temperature (i.e., to
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include the energy equation). This option was used in this work for some calculations. The
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thermodynamic databases used in the calculations were FACTPS that includes data for pure
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stoichiometric gas, liquid and solid phases and FToxide that contains data for pure oxides and
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oxide solutions. By using the oxide solution models SLAGA (oxide melt: FexOy), SPINA
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(spinel: Fe3O4) and MeO_A (monoxide: FeO, Fe2O3) it is possible to calculate the complex phase
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diagram of Fe-Fe2O3.35
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Three sets of TEC’s were performed in order to understand the combustion behavior of the
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iron particles in the EFR. In all TEC’s, λ was varied from sub-stoichiometric conditions (λ=0.17)
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to conditions representing an excess of the oxidizer (λ=2.68). In the first set of TEC’s, the energy
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equation was included in the calculations. Adiabatic combustion was assumed. The initial
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temperature of the iron particle and the combustion air was 25°C. The first set of calculations can
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be used to in the interpretation of the initial oxidation of the iron ore particles close to the burner 7 ACS Paragon Plus Environment
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(i.e., the iron dust flame). In the second set of TEC’s, the process temperature was fixed to the
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process temperature of the EFR. This calculation can be used in the interpretation of the
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combustion products when the iron ore particle temperature equals to that of the EFR. Finally, in
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order to investigate the influence of preheating on the amount of gaseous iron species (Fe(g) and
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FeO(g)) the first set of TEC’s was repeated with a varying degree of air preheating (200, 400, and
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600°C). This set of TEC’s was motivated by the fact that combustion air can be preheated in the
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EFR before it reacts with an iron ore particle.
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3. RESULTS AND DISCUSSIONS
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3.1. Flue gas emissions. The emission of CO2, minor gaseous components (CO, NOx, and SO2)
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and SR during the combustion of two types of PSI and coal were measured. Solid residues (SR)
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and fumes were defined as particulate matter with an aerodynamic diameter above and below 10
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µm, respectively. The flue gas composition (Table S1) and emissions (Fig. 3) showed significant
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differences between PSI and PC combustion at similar experimental conditions. As expected, the
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emission of CO2 was insignificant in PSI combustion, verifying that the combustion stage in the
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metal fuel cycle is a zero-carbon process. In addition to being the most significant contributor to
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anthropogenic CO2 emissions, PC combustion is a significant emitter of the controlled pollutants
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NOx and SO2,36,37 responsible for approximately 15% and 50% of global emissions,
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respectively.38 Our tests showed that substituting PSI for PC has a significant positive impact on
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NOx and SO2 emissions: the emission of NOx was reduced from approximately 500 mg/MJfuel to
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20 mg/MJfuel, while the emission of SO2 was reduced from 230 mg/MJfuel to 1-7 mg/MJfuel,
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depending on the type of PSI. The NOx emissions for PSI are also significantly lower compared
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to reported values from industrial PC boilers,39,40 see Table 3. Furthermore, the observed NOx
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emissions from PC combustion is similar compared industrial emissions verifying that the EFR 8 ACS Paragon Plus Environment
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and the experimentally conditions used in this work is relevant. This observation suggests that
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implementing a retrofit metal fuel cycle might also alleviate adverse environmental effects
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typically attributed to NOx and SO2 emissions, such as acid rain, atmospheric particulate matter,
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and the reduced concentration of tropospheric ozone.41 Furthermore, the emissions of NOx from
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PSI combustion was much lower compared to the NOx emission of 125±16 mg/MJ recalculated
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by us from the reported value of 1100±140 mg/Nm3 (O2 % in flue gas ~9 %), for magnesium
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combustion in air,10 indicating that PSI also is a superior fuel with respect to NOx emissions.
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The large reduction in NOx emission can be explained by the fact that different formation
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mechanisms dominate in PSI and PC combustion. In coal combustion, NOx are formed by the
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thermal-, Fenimore- and fuel-bound nitrogen mechanisms.41 Both the Fenimore- and fuel-bound
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nitrogen mechanisms require interaction with either hydrocarbon radicals or nitrogen from the
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fuel itself. Compared to PC, PSI does not contain a significant amount of nitrogen (see Table 1),
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and no hydrocarbon intermediates are formed during its combustion; therefore, in PSI
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combustion, the NOx are only produced by the thermal mechanism. This mechanism involves the
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dissociation of N2 and O2 and is initiated at temperatures above 1500°C. At stoichiometric
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conditions, the adiabatic flame temperature of PSI combustion almost reaches 2000°C;6
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therefore, one can conclude that during PSI combustion, most of the NOx are formed by the
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thermal mechanism. The much higher NOx emissions observed during magnesium/air
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combustion9 can again be attributed to the dominance of the thermal mechanism and the
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significantly higher temperatures of magnesium flames,42 compared to those observed in flames
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of PSI. Similarly to hydrocarbon combustion, optimization through e.g., oxidant staging or flue
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gas recirculation41 can most likely further reduce NOx emissions from PSI combustion. The
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pollutant SO2 is formed when sulfur inherent to the fuel is oxidized in the combustion process. As
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the types of PSI studied here had significantly lower sulfur content compared to that of typical
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PC (see Table 1), SO2 emissions were also lower.
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3.2. Solid products after combustion. The solid residues (SR) of PSI combustion consisted of
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micron-sized oxide particles and a fine fume fraction of nanoparticles. The micron-sized particles
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were separated from the flue gas by using a cyclone. The chemical composition and morphology
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of the separated SR from PSI combustion are shown in Fig. 4A-B and Figs. S1-S3. The amount
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of hematite (α-Fe2O3, 88-92 wt%), the most oxidized form of the three relevant iron oxides (FeO,
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Fe3O4 and Fe2O3), indicated efficient combustion and near-complete oxidation. The rest of the
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micron-sized particles consisted mostly of magnetite (Fe3O4). The morphology of the PSI
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particles changed significantly during combustion: from an irregular shape to a nearly spherical
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or slightly ellipsoidal shape (Fig. 4B). During combustion, the size of the reacting particles
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increased and small cracks and holes appeared on their surface. Most of the produced particles
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were solid; however, many appeared to have large internal cavities (Fig. 4B and Fig. S3). Small
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voids inside iron oxide particles (10-60 µm) has been observed before during the solid state
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oxidation of iron at 700 °C20 and explained by the Kirkendall effect.43 In this case, with the
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temperature of the iron oxide particles being above the melting point, we instead suggest that the
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observed changes in size and shape can be explained by a combination of oxidation and melting,
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as well as by the evaporation of a small portion of the iron from the center of the particles in a
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way similar to what has been observed in aluminum combustion.44
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Thermodynamic equilibrium calculations (TEC’s) predicted the presence of both an iron oxide
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melt and gaseous iron in the early stage of the oxidation process as well as particle temperatures
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exceeding 1500°C (Fig. S4). The oxidation of iron to wustite (FeO) causes rapid heating – the
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ejection of rapidly expanding, gaseous iron formed in the center of a molten iron oxide particle 10 ACS Paragon Plus Environment
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can result in the hollow structures. Further oxidation of FeO to Fe3O4 and Fe2O3 increases
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particle temperature, approaching the adiabatic temperature of approximately 2000°C (Fig. S4).
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Simultaneously, particle size increases due to mass uptake from oxygen and decreasing density
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(7.9 g/cm3 to 5.2 g/cm3). For example, the diameter of a spherical, homogeneous iron particle can
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increase by approximately 30% when it is converted to Fe2O3 – the diameter of hollow particles
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might increase even more. As seen from the TEC’s (Fig. S5), at a reactor temperature of 1200°C,
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solid Fe3O4 can be fully oxidized to solid Fe2O3, supporting the experimental observation
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regarding the Fe2O3 and Fe3O4 content of the produced iron oxide particles.
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Experimental results indicated that approximately 4 wt% of the iron evaporated and formed
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fumes after condensation (Fig. 5) – this observation is in reasonable agreement with the
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predictions of TEC’s (Fig. S6); however, it contradicts the results of previous studies that
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reported the fully solid state combustion of PSI, without forming any metal fumes.6 The fumes
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consisted of aggregates of iron oxide nanoparticles in the form of maghemite (γ-Fe2O3) and α-
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Fe2O3 (Figs. 6A and 6B and Figs. S7 and S8). Nanoparticles form when gaseous iron (Fig S6) in
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the form of Fe(g) or FeO(g) reacts with oxygen. Due to the extremely low vapor pressure of iron
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oxides, nuclei form by homogeneous condensation and grow by heterogeneous condensation
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until all Fe(g)/FeO(g) have been absorbed, resulting in primary particle sizes between 30 and 50
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nm. The aerodynamic diameters of the vast majority of aggregates formed by the coagulation of
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primary particles were below 5 µm (Fig. 5). The observation regarding the formation of γ-Fe2O3
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nanoparticles is interesting, due to the known superparamagnetic and ferromagnetic properties of
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these particles and their potential applications in magnetic data storage, sensors, biosensing, drug
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delivery, catalysis and cancer treatment.45-47 Flame synthesis is one possible production method
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of γ-Fe2O3 nanoparticles.48,49 Although considered as material loss in the metal fuel cycle, a small
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amount of the fumes produced during PSI combustion may therefore become a high value by-
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product.
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3.3. Practical implications. The amount of produced SR and fumes during PSI combustion was
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significantly higher compared to that observed during PC combustion (Fig. 3), suggesting that
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handling the residues might become the first technical challenge in implementing PSI
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combustion. However, due to the high melting point of the iron oxides (above 1550°C) and the
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absence of impurities, one can expect that PSI can be combusted without any ash-related
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operational problems that often occur during coal combustion.50 Therefore, steam pressure can
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potentially be increased relative to that typically achievable in PC combustion, allowing for
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increasing power efficiency. Due to the coarse granularity of the SR, iron oxide particles can be
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separated from the flue gas by using ordinary cyclones, in a manner similar to the separation of
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coal combustion fly ash. A subsequent cleaning device such as an electrostatic precipitator or
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baghouse filter might be necessary for the separation of fumes and nanoparticles from the flue
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gas. Compared to PC combustion, the mass load of fumes is higher during PSI combustion;
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however, the iron oxide nanoparticles were non-adhering at relevant flue gas temperatures
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(150°C), in contrast with fumes from coal combustion (Fig. S9). Maintaining low flue gas
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temperature is of significant interest in order to maximize energy recovery from the combustion
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system. During PC combustion, the dew point of sulfuric acid (H2SO4) sets a practical limit on
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the minimum achievable flue gas temperature. At the dew point, H2SO4, formed from SO2 and
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H2O, condenses from the flue gas forming a corrosive deposit, leading to the low temperature
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corrosion and plugging of economizers and air preheaters.51 Since the flue gas of PSI combustion
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is practically free from H2O and SO2, the flue gas temperature can be reduced without risking the
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condensation of H2SO4 (Fig. S10A). Based on our experiments, when substituting PC with PSI, 12 ACS Paragon Plus Environment
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we estimated that the heat losses through the flue gas can be reduced from 6.5% to below 2%
290
(Fig. S10B).
291 292
4. CONCLUSIONS
293
In this work, pulverized sponge iron (PSI) and pulverized coal (PC) were combusted under
294
similar conditions in an entrained flow reactor. The following conclusions can be drawn from the
295
results of the study:
296
•
substitute for PC in furnaces and boilers.
297 298
•
The emissions of harmful pollutants, NOx and SO2 were insignificant compared to that of PC, indicating that PSI can become an environmentally friendly substitute for PC.
299 300
The combustion of PSI was almost complete (>98%) indicating that PSI can be used as a
•
In contrast with results of previous studies, a small part of the iron (~4 wt%) actually
301
vaporized during the combustion process and iron oxide nanoparticles (or fumes) formed
302
from the gaseous iron through condensation.
303
•
Because of its many advantageous combustion characteristics, we believe that PSI can
304
become a zero-carbon fuel in a recyclable metal fuel cycle substituting PC in existing or
305
newly designed combustion devices in the future and the results presented in this paper
306
should encourage more studies relevant for using PSI as an energy carrier such as cyclic
307
studies of the reduction-oxidation behavior of PSI, pilot scale combustion trials with PSI
308
as fuel and techno-economic analysis of the concept.
309 310
Acknowledgment
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The authors gratefully acknowledge LKAB for assistance in wet chemistry analysis of the iron
312
oxides and B. Lindblom (LKAB) for helpful discussions. We also thank K. Jansson (Stockholm
313
University) for carrying out TEM analysis, N. Skoglund (Umeå University) for carrying out XRD
314
measurements and H. Sefidari (Luleå University of Technology) for advice on TEC’s. This work
315
was financed by the Swedish Government via the strategic-competence model for RISE ETC.
316 317 318 319 320 321
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Tables
435
Table 1. Physical and chemical composition of the fuels. Iron A
Iron B
Coal
3190
3000
780
-
-
74.2
-
-
3.9
99
99
1.33 0.372 0.01 -
7.39
7.39
29.6
Morphology
Bulk density (kg/m3) Elemental comp. (wt% dry) Carbon (C) Hydrogen (H) Nitrogen (N) Sulfur (S) Chlorine (Cl) Iron (Fe) Effective heating value (MJ/kg dry)
436 437
Table 2. Operating conditions of the EFR for the different fuels Powder mass flow (g/min) Thermal power (W) N2 in transport gas (g/min) N2 in combustion gas (g/min) O2 in combustion gas (g/min) Reactor temperature (°C)
Iron A 2.50 310 1.25 5.75 2.14 1200
Iron B 2.50 310 1.25 5.75 2.14 1200
Coal 0.63 310 1.25 8.13 2.86 1200
438 439
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Energy & Fuels
Table 3: NO emissions from industrial combustion of coal. The table compares literature data regarding NO emissions from seven industrial PC boilers39,40 with the data obtained in this study. Some information regarding the boiler, burner arrangement, NOx controlling technology and fuel is also given in the table. Facility Literature data 300 MWe, sub-critical, W-fired, no NOx controlling strategy39 360 MWe, sub-critical, W-fired, no NOx controlling strategy39 200 MWe, sub-critical, T-fired, Proprietary NOx controlling strategy39 1000 MWe, ultra supercritical, T-fired and twin furnace, low NOx burners and overfire air NOx39 600 MWe, sub-critical, T-fired, overfire air39 600 MWe, sub-critical, T-fired, overfire air39 300 MWe, down-fired boiler with deep-airstaged and low-NOx technology40 This study Entrained flow reactor Entrained flow reactor Entrained flow reactor
Fuel
NO emissions (mg/Nm3 at 6 % O2)
Anthracite, 1.6 wt-% N
1290 – 1500
Anthracite, 0.94 wt-% N
990 – 1080
Bituminous, 0.79 wt-% N
360 – 450
Bituminous, 1.12 wt-% N
320 – 400
Bituminous, 1.07 wt-% N Lignite, 0.47 wt-% N Anthracite, 0.78 wt-% N
375 – 410 556 – 686 674-836
Iron A Iron B Bituminous, 1.33 wt-% N
33 ± 1.5 36 ± 0.2 684 ± 2.6
444 445
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Figures
447 448
Fig. 1. An overview of the metal fuel cycle and energy densities of current and
449
potential future energy carriers. (A) The meal fuel cycle for iron. (B) Energy density
450
and specific energy of iron and iron powder compared to those of fossil fuels (coal, diesel,
451
gasoline, and LNG), biomass (forest residue, bio oil, MeOH), H2 compressed to 700 bar
452
(CH2), liquefied H2 (LH2) and batteries.
453
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454 455
Fig. 2. Experimental facility. A schematic of the experimental setup used to combust the fuels.
456
The setup was based on an EFR and different flue gas analysis systems including a pre-cyclone,
457
FTIR and LPI.
458
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459 460
Fig. 3. The results of combustion tests. Emission of CO2, minor gaseous components (CO,
461
NOx, and SO2) and SR during the combustion of two types of PSI and coal. Solid residues (SR)
462
and fumes were defined as particulate matter with an aerodynamic diameter above and below 10
463
µm, respectively. Note the different vertical scales for different emitted species.
464
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465 466
Fig. 4. Chemical composition and morphology of iron oxide SR. (A) XRD pattern and
467
chemical composition of the SR particles. (B) SEM images (500x) of PSI before (left plate) and
468
after the combustion experiments (right plate) together with a crushed hollow particle under
469
higher magnification (1500x).
470
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471 472
Fig. 5. Particle concentration and aggregate size distribution. Particle concentrations and
473
aggregate size distributions of the fumes measured by DLPI for both sponge iron powders and the
474
pulverized coal. The particulate matter for which the analysis results are shown here included the
475
part of mineral matter injected to the EFR with the fuel that was emitted in the fume fraction.
476
Note the logarithmic scale of the x-, and y-axes. Aggregates with a particle diameter below 1.0
477
µm (i.e., submicron aggregates) dominated the aggregate size distribution. Particulate emission
478
during coal combustion was much lower compared to that of PSI combustion.
479
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Fig. 6. Chemical composition and morphology of iron oxide fumes. (A) XRD pattern and
482
chemical composition of fume particles. (B) TEM and HRTEM images illustrating the primary
483
particle size in the aggregates and the microstructure of individual nanoparticles.
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