Your search keyword '"Ma, Lun"' showing total 35 results

1. A novel Swiss-roll micro-combustor with double combustion chambers: A numerical investigation on effect of solid material on premixed CH4/air flame blow-off limit

Author

Gang Chen, Qingyan Fang, Cheng Zhang, and Ma Lun

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, Flow (psychology), Heat recirculation, Energy Engineering and Power Technology, chemistry.chemical_element, Heat losses, 02 engineering and technology, Mechanics, Solid material, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Copper, 0104 chemical sciences, Fuel Technology, chemistry, Limit (music), Combustor, Combustion chamber, 0210 nano-technology

Abstract

A novel Swiss-roll micro-combustor with double combustion chambers is proposed to improve flame stability and extend blow-off limits. This study is aimed to numerically investigate the effect of solid material (i.e., SiC, stainless steel and copper) on premixed CH4/air flame blow-off limit and reveal the flame stability mechanism. The simulated results show that this developed novel Swiss-roll micro-combustor not only can significantly anchor the flame owing to the flow recirculation behind the flame holders and the backward-facing steps, but also can further extend CH4 blow-off limits owing to heat recirculation in the long Swiss-roll preheating channels. The three solid material micro-combustors present the relatively slight difference in the recirculation-zone size but the remarkably difference in heat recirculation and heat loss. Good heat recirculation and low heat loss rate are the dominant reason that is responsible for the differences of the blow-off limits in this micro-combustor. The stainless steel micro-combustor achieves the highest blow-off limits while the copper micro-combustor achieves the lowest blow-off limit. These deep insights can give some useful information to design a similar Swiss-roll micro-combustor.

Published

2021

2. Effect of H2O on the combustion characteristics and interactions of blended coals in O2/H2O/CO2 atmosphere

Author

Gang Chen, Qingyan Fang, Yu Shenghui, Cheng Zhang, Ma Lun, and Xinke Chen

Subjects

Power station, 020209 energy, Metallurgy, Coal combustion products, 02 engineering and technology, Ignition delay, Combustion, law.invention, Atmosphere, Ignition system, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering

Abstract

Blending coal combustion technology is commonly used in coal-fired power stations, and the combustion interactions (i.e., the ignition promotion and burnout inhibition) during blended coal combustion affect their combustion characteristics. The combustion interactions under conventional air-fuel condition have been well studied. Oxy-fuel firing considerably differs from air-fuel combustion and the combustion interactions of blended coals in O2/CO2 atmospheres have been investigated in our previous research. However, the H2O concentration in actual oxy-fuel condition is relatively high, which may influence the combustion interactions. This study further investigates the effect of H2O on the combustion characteristics and interactions of blended coals in O2/H2O/CO2 atmospheres. The results show that adding H2O into the oxy-fuel atmosphere remarkably affects the combustion characteristics with the more notable ignition delay, faster burnout and better comprehensive combustion characteristics (CCI). In addition, the presence of H2O strengthens the ignition promotion, the burnout inhibition and the comprehensive interactions, resulting in the more obvious non-additive behaviors of CCI. In O2/H2O/CO2 mixtures, enhancing the H2O/CO2 ratio slightly strengthens the ignition promotion, the burnout inhibition, and the comprehensive interactions, which increases the non-additive behaviors of CCI. Furthermore, both of increasing O2/H2O or O2/CO2 ratios significantly weaken the ignition promotion, strengthen the burnout inhibition and the comprehensive interactions, which increases the non-additive behaviors of CCI. The findings shed light on the interaction effects observed during blended coal combustion in O2/H2O/CO2 mixtures, which can provide useful information to improve the combustion characteristics of the blended coals in the real oxy-fuel atmospheres.

Published

2021

3. Effect of CO2 atmosphere on Ca-containing mineral transformation behaviors during a Ca dominated coal co-firing with a Si/Al dominated coal in oxy-fuel condition

Author

Zhang Zhongjian, Gang Chen, Yu Shenghui, Qingyan Fang, Ma Lun, Cheng Zhang, and Xinke Chen

Subjects

Coal blending, Materials science, Mineral, business.industry, 020209 energy, Metallurgy, Low melting point, 02 engineering and technology, Combustion, Atmosphere, Oxy-fuel, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Coal, 0204 chemical engineering, business

Abstract

Coal blending is an effective method to reduce the slagging tendency. The mineral transformation within blended coal ashes has an important influence on the slagging behaviors, which have been well studied under conventional air-fuel condition. Oxy-fuel combustion is recognized as one of the most promising CO2 reduction technologies. However, the mineral transformation within blended coal ashes in oxy-fuel condition has yet to be fully understood. This work is aimed to comprehensively study the influence of CO2 atmosphere on Ca-containing mineral transformation behaviors during a Ca dominated coal co-firing with a Si/Al dominated coal in O2/CO2 condition by TG-DSC, XRD and HSC simulation. These results show that the atmosphere significantly affects on the transformation of Ca-containing mineral and the final existing form of Ca in the blended coal ashes. When the high content Ca coal is blended with the high content Al/Si coal in the O2/CO2 atmosphere, the CO2 promotes the transformation of Ca into CaCO3 and Ca under low temperature mainly exists in the form of CaCO3 (little CaSO4) in the blended coal ashes. CaCO3 under high temperature is decomposed to produce highly active CaO, and CaO reacts with Al/Si to form the low melting point minerals, which may aggravate the slagging tendency. The present study can provide useful information to reduce the slagging behavior of the blended coals in the O2/CO2 atmosphere.

Published

2020

4. Effect of separated over-fire air angle on combustion and NO emissions in a down-fired utility boiler with a novel combustion system

Author

Gang Chen, Qingyan Fang, Yu Shenghui, Ma Lun, and Cheng Zhang

Subjects

021110 strategic, defence & security studies, Environmental Engineering, Computer simulation, General Chemical Engineering, Nozzle, 0211 other engineering and technologies, Combustion system, Environmental engineering, Boiler (power generation), 02 engineering and technology, Limiting, 010501 environmental sciences, Combustion, 01 natural sciences, Fly ash, Environmental Chemistry, Environmental science, Safety, Risk, Reliability and Quality, NOx, 0105 earth and related environmental sciences

Abstract

A novel combustion system, consisting of moving fuel-lean nozzles from the arches to the front/rear walls, rearranging staged air, and introducing separated over-fire air (SOFA), has been proposed and successfully applied in a 600 MWe Foster Wheeler down-fired boilers to reduce high NOx emissions while limiting the carbon content in the fly ash. This study comprehensively evaluates the effect of SOFA angles on flow, combustion characteristics and NOx emissions for the novel combustion system by numerical simulation and in-situ experiment. The numerical simulation shows in acceptable consistence with the in-situ experiment. The simulated results show that significant NOx reduction is obtained for all five SOFA angles compared to the original combustion system. O2 and CO concentrations at the furnace outlet, as well as the carbon content in the fly ash decrease significantly with increasing SOFA angle from 0° to 40°. NOx emissions increase slightly and the average temperature at the re-heater entrance changes slightly with the increase of SOFA angle from 0° to 30°. However, with further increasing SOFA angle from 30° to 40°, NOx emissions increase substantially due to the smaller reducing region below the SOFA and the average temperature at the re-heater entrance falls significantly. Taking combustion, NOx and steam parameters into account, a SOFA angle of 30° is advisable. The actual industrial measurements also show that the steam can achieve the designed values when the SOFA angle is set at 30° instead of 40°. Significant NOx reduction (over 50 %) and good performance are attained after adopting the novel combustion technology of 30 °SOFA angle.

Published

2020

5. Improving combustion and lowering NO emissions of an industrial coal swirl burner by optimizing its nozzle structure

Author

Su, Xianqiang, Fang, Qingyan, Ma, Lun, Yao, Bin, Li, Yuan, Zhao, Xinping, Mao, Rui, and Yin, Chungen

Subjects

Burner aerodynamics, Energy Engineering and Power Technology, Burner nozzle optimization, Swirl burner, Industrial and Manufacturing Engineering, Coal combustion, Flexible operation

Abstract

To accommodate rapidly growing but highly variable renewable power in the grid and large variations in power demand, coal-fired power plants need to be flexibly operated through fast and wide load changes, still with high efficiency and reliability and low emissions. Towards reliable implementation in a power plant under flexible operation, this paper comprehensively investigates the improvement of an industrial low-NOx swirl burner via numerical simulation and various field tests. Burner aerodynamics, which play a vital role in its performance, are largely affected by the burner nozzle structure. For the low-NOx swirl burner under study, the inner secondary air cone structure is found to have the most significant impact on the burner aerodynamics and the combustion performance. For the coal fired in the power plant, the newly designed inner secondary air cone structure, which is a kind of an extended smooth diverging duct, greatly facilitates the entrainment of the primary air into the surrounding swirl secondary air stream and largely enhances lateral mixing. A large recirculation zone is formed between the primary air and the inner secondary air stream, stabilizing ignition and combustion under flexible operation conditions. This is particularly important for low-load operation. Comparatively, reducing the secondary air duct area for a higher axial momentum of the secondary air stream and adding a new particle separation ring for more dispersed particle distribution are found to have a minor impact on the burner aerodynamics. The optimized burner nozzle structure via numerical simulation has been finally adopted by the power plant for the burner retrofit, on which various field tests have been performed on the retrofitted burner. The tests show that the nozzle structure optimization remarkably improves the burner performance, which is also consistent with the numerical prediction. This study also provides useful guidance for optimizing the swirl burners of the similar type.

Published

2023

6. Combustion Interactions of Blended Chars under Oxidation and Gasification Competition in Oxy–Fuel Condition

Author

Gang Chen, Qingyan Fang, Xinke Chen, Cheng Zhang, Ji Xia, and Ma Lun

Subjects

Oxy-fuel, Nuclear Energy and Engineering, Waste management, Renewable Energy, Sustainability and the Environment, media_common.quotation_subject, Energy Engineering and Power Technology, Environmental science, Coal combustion products, Combustion, Waste Management and Disposal, Competition (biology), Civil and Structural Engineering, media_common

Abstract

The combustion interactions during blended coal combustion affect their combustion characteristics, and the combustion interactions under air–fuel conditions have been well studied. However...

Published

2021

7. Geochemical characteristics and genesis of deep marine carbonate natural gas in China

Author

Bin Zhang, Shi Jianglong, Wang Lei, Jian Li, Jin Li, Bin Hao, Aisheng Hao, Wei Lin, Chen Bintao, Xue Luo, Ma Lun, Xuening Qi, and Zhongsheng Shi

Subjects

business.industry, Fossil fuel, Geochemistry, Mineral resource classification, chemistry.chemical_compound, Igneous rock, chemistry, Petroleum industry, Geochemistry and Petrology, Natural gas, Clastic rock, Carbonate, Carbonate rock, business, Geology

Abstract

The deep and ultra-deep oil and gas has been a prominent exploration direction in the field of petroleum industry in recent years. The deep oil and gas resources are mainly distributed in the carbonate rocks, clastic rocks and igneous rocks, of which the carbonate rock reservoirs account for about 40% of global oil and gas reserves for their superior reservoir properties. Currently, a number of large oil and gas fields have been discovered in the deep marine carbonate rocks in China, especially in the Sichuan and Tarim Basin, thus showing a broad oil and gas exploration potential in the deep marine carbonate rocks. In this paper, the genesis and source of deep natural gas in the Tarim and Sichuan Basin has been systematically studied. The results show that the natural gas in the deep marine carbonate rock reservoirs is not only sourced from the deep-source rocks, but the substantial crack of crude oil in the reservoir under the condition of high burial depth and high geotemperature can provide abundant natural gas sources for the deep reservoir. Accordingly, the contribution of gas from oil cracking should be concerned in evaluation on deep natural gas resources.

Published

2021

8. Effect of different conditions on the combustion interactions of blended coals in O2/CO2 mixtures

Author

Gang Chen, Qingyan Fang, Cheng Zhang, Jichang Liu, Wang Tingxu, Guo Anlong, and Ma Lun

Subjects

Materials science, Power station, business.industry, 020209 energy, 02 engineering and technology, Combustion, Atmosphere, 020401 chemical engineering, Chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Limiting oxygen concentration, Coal, Particle size, 0204 chemical engineering, business

Abstract

The combination of oxy-fuel and blended-coal combustion may be one of these effective methods to both reduce CO2 emissions and improve energy utilization efficiency in coal-fired power stations. The aim of this study is to investigate oxy-fuel combustion interactions of blended coals under different conditions using a thermo-gravimetric analyzer. The results show that compared with those in an O2/N2 mixture, the promotive and inhibitive effect and the comprehensive interactions are considerably weaker in an O2/CO2 mixture. In the O2/CO2 mixture, both increasing the O2 concentration and decreasing the particle size result in decreasing the promotive effect but increasing the inhibitive effect and the comprehensive interactions, which increase the non-additive combustion characteristics. Enhancement of the heating rate increases the promotive effect but decreases the inhibitive effect and the comprehensive interactions, which weaken the non-additive combustion characteristics. Of these factors, the effects of the oxygen concentration and heating rate on comprehensive interactions are greater than that of particle size. This study provides useful information for the design and optimization of thermo-chemical conversion systems of coal blends in the O2/CO2 atmosphere.

Published

2019

9. Research on Error Detection Technology of English Writing Based on Recurrent Neural Network

Author

Li Yong-An, Ma Lun, Wang Wei, and Qu Qianqian

Subjects

Grammar, business.industry, Computer science, media_common.quotation_subject, Feature extraction, computer.software_genre, Grammatical error, Information extraction, Recurrent neural network, Reading (process), Active listening, Artificial intelligence, business, Error detection and correction, computer, Natural language processing, media_common

Abstract

In learning English, learners are faced with various challenges, such as listening, speaking, reading and writing. Among them, writing is the most important and difficult one, and grammatical errors are the most common type of errors in English writing. The research and implementation of grammatical error detection and correction in English writing is of great significance to both English learners and English teachers. In this paper, we propose a sequence annotation model based on recurrent neural network to solve the problem of the influence of grammar errors and other noises in English writing corpus on sequence information extraction. Aiming at the grammatical errors in English writing, this paper proposes two methods of English grammatical error detection and correction. The experimental results show that the accuracy of RNN is higher than that of CAMB after 10 to 20 iterations, ranging from 0.848 to 0.916.

Published

2021

10. An Analysis of AI Technology Assisted English Teaching Based on the Noticing Hypothesis

Author

Li Yong-An, Wang Wei, Ma Lun, and Qu Qianqian

Subjects

Language ability, Software, business.industry, Foreign language, ComputingMilieux_COMPUTERSANDEDUCATION, English education, Mathematics education, Language education, business, Noticing hypothesis, Second-language acquisition, Learning data

Abstract

As a new form of education, the language education software based on AI (Artificial Intelligence) technology effectively improves the timeliness and interest of language teaching, and enrich and improve the English education system to a certain degree. Second language acquisition (SLA) theory integrates linguistics, language education, sociology, psychology and other disciplines, focusing on the study of people’s acquisition of foreign languages and the mechanism of language ability. This article is based on teaching practice materials and students’ English learning data, and uses the Noticing Hypothesis theory to try to solve the problems emerged from artificial intelligence teaching courses.

Published

2021

11. Combustion interactions of blended coals in an O2/CO2 mixture in a drop-tube furnace: Experimental investigation and numerical simulation

Author

Gang Chen, Qingyan Fang, Guo Anlong, Cheng Zhang, Ma Lun, and Wang Tingxu

Subjects

Materials science, business.industry, 020209 energy, technology, industry, and agriculture, Energy Engineering and Power Technology, Coal combustion products, 02 engineering and technology, Combustion, complex mixtures, Industrial and Manufacturing Engineering, law.invention, Ignition system, Chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Coal, Limiting oxygen concentration, Tube furnace, Char, business

Abstract

Interactions, known as the ignition promotion and burnout inhibition, exist during the combustion of blended coals in the air. The oxy-fuel conditions influence these interactions due to the change of the gas physical properties and the gasification reaction. However, little research has focused on the oxy-fuel combustion interactions of blended coals. To investigate the combustion interactions of blended coals in an O2/CO2 atmosphere, experimental and numerical studies of the mixed combustion of less- and more-volatile coals are performed in a drop tube furnace. The results show that the more-volatile coal combustion brings the promotive effect on the devolatilization of the less-volatile coal and the inhibitive effect on the char combustion of the less-volatile coal. Compared with that in the air, the promotive effect is weaker, but the inhibitive effect is stronger in the 21%O2/79%CO2 environment due to the different physical properties of the gases. In the O2/CO2, increasing the oxygen concentration increases the promotive effect but weakens the inhibitive effect owing to the change of the physical properties of gases and the reactivity improvement of the less-volatile coal char. In addition, the promotive and inhibitive effects achieve a level similar to that in the air when the oxygen concentration is increased to approximately 30–35%. Furthermore, the char-CO2 gasification reaction in the O2/CO2 has little impact on the promotive effect but weakens the inhibitive effect. Increasing the reactor wall temperature weakens both the promotive effect and the inhibitive effect.

Published

2018

12. Study on improving the SO2 tolerance of low-temperature SCR catalysts using zeolite membranes: NO/SO2 separation performance of aluminogermanate membranes

Author

Qingyan Fang, Ma Lun, Chen Gang, Zhang Xiaopei, Zhang Cheng, Wei Li, Xin Li, and Tan Peng

Subjects

Surface diffusion, Chromatography, Chemistry, General Chemical Engineering, Diffusion, Selective catalytic reduction, 02 engineering and technology, General Chemistry, Permeation, 010402 general chemistry, 021001 nanoscience & nanotechnology, complex mixtures, 01 natural sciences, Industrial and Manufacturing Engineering, respiratory tract diseases, 0104 chemical sciences, Catalysis, Membrane, Chemical engineering, Environmental Chemistry, 0210 nano-technology, Selectivity, Zeolite

Abstract

A novel idea is proposed to improve the SO2 tolerance of low-temperature selective catalytic reduction (SCR) catalysts by using a RHO zeolite membrane to separate NO from SO2 to reduce the contact between SO2 and the SCR catalysts. RHO zeolite membranes were prepared on a macroporous stainless steel tube. The results from XRD and SEM measurements indicated that the crystals on the surface were pure RHO zeolites and a uniform and continuous layer of RHO zeolite membrane covered the surface of the support. Permeation measurements using different feed gases indicated that the prepared RHO zeolite membrane could effectively separate NO from SO2. A maximum NO/SO2 selectivity of 36.14 was obtained when using NO/SO2/N2 mixtures. The SO2 permeation decreased a lot in the present of water. Surface diffusion and activated diffusion were believed to be the main transport mechanisms of the RHO zeolite membrane.

Published

2018

13. Insights into the causes and controlling strategies of gas temperature deviation in a 660 MW tangentially fired tower-type boiler

Author

Jichang Liu, Gang Chen, Qingyan Fang, Zhang Ping'an, Cheng Zhang, Rui Mao, Ma Lun, Liming Ren, Li Yuan, and Xinke Chen

Subjects

Flue gas, Suction, Boiler (power generation), Energy Engineering and Power Technology, Environmental science, Mechanics, Division (mathematics), Rotation, Tower, Industrial and Manufacturing Engineering, Damper, Degree (temperature)

Abstract

Gas temperature deviation is a common problem for tangentially fired boilers, affecting the boiler operation safety and the boiler generation efficiency. The gas temperature deviation in the tangentially fired π-type boilers has been well studied. However, the gas temperature deviation in the tangentially fired tower-type boilers has yet to be fully understood. This paper develops insights into the causes and controlling strategies of gas temperature deviation in a 660 MW tangentially fired tower-type boiler with obvious steam temperature deviation by experiment and simulation. Firstly, four upper furnace structures are established to fully reveal the causes of gas temperature deviation. The gas temperature deviation is mainly caused by the flue gas rotation, the heating tubes division, and the suction effect of the induced draft fan. More evident recirculation is observed near the right side than the left side in the platen heater region, resulting in that the flue gas deflects to the left side, and the left side region presents higher temperature. Furthermore, the controlling strategies of gas temperature deviation are studied comprehensively by adjusting SOFA (Separated Over-fire Air) horizontal angle and setting SOFA left–right-side velocity offset. Properly SOFA horizontal angle or enhancing the left-side SOFA velocity may effectively reduce the gas temperature deviation. 34–45° for the SOFA horizontal angle and 1.2 for the SOFA left–right-side velocity ratio are recommended. In the actual operation, offsetting the SOFA left–right-side velocity (i. e. SOFA air damper opening degree: left side—80% and right side—50%) is successfully applied to reduce the re-heated steam temperature deviation from 18 K to 1 K without bringing adverse effects under the low load. These deep insights may provide useful information to control the steam temperature deviation in the platen heater zone.

Published

2021

14. Insight into As2O3 adsorption characteristics by mineral oxide sorbents: Experimental and DFT study

Author

Gang Chen, Qingyan Fang, Cheng Zhang, Yu Shenghui, and Ma Lun

Subjects

Sorbent, Mineral, Materials science, business.industry, General Chemical Engineering, Inorganic chemistry, Oxide, chemistry.chemical_element, Coal combustion products, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Industrial and Manufacturing Engineering, 0104 chemical sciences, chemistry.chemical_compound, Adsorption, chemistry, Density of states, Environmental Chemistry, Coal, 0210 nano-technology, business, Arsenic

Abstract

As a highly toxic element of coal, arsenic (As) is mainly converted into As2O3 vapor during coal combustion. Mineral oxides are effective and abundant sorbents to control As2O3 emissions. In this paper, the characteristics of As2O3 adsorption by mineral oxides were studied in a two-stage reactor, and the density of states, adsorption sites, and adsorption energies for the adsorption reaction were investigated using molecular simulation. The results demonstrate that CaO is an excellent As2O3 sorbent. The As2O3 adsorption effect of CaO, MgO, and Al2O3 was found to become better with increasing temperature within the range of 300–900 °C. The order of As2O3 adsorption at 300–700 °C follows CaO > Fe2O3 > Na2O > MgO > Al2O3 > SiO2, and SiO2 hardly adsorbs any As2O3. At 900 °C, the melting of Na2O and Fe2O3 greatly reduces their As2O3 adsorption capacity. The O atoms in Na2O/CaO/MgO/Al2O3/SiO2 and the Fe atoms in Fe2O3 are the adsorption active sites for As2O3. The order of the calculated adsorption energy follows Fe2O3 > Na2O > CaO > Al2O3 > MgO > SiO2, and the As2O3 adsorption involves chemical adsorption. The adsorption products are Ca3(AsO4)2, FeAsO4, AlAsO4, etc., for which As exists in the form of As3+ and As5+, with As3+ transformed into As5+ with increasing adsorption temperature.

Published

2021

15. Effects of burner tilt angle on the combustion and NOX emission characteristics of a 700 MWe deep-air-staged tangentially pulverized-coal-fired boiler

Author

Gang Chen, Qingyan Fang, Honggang Zhang, Cheng Zhang, Dengfeng Tian, Ma Lun, Lijin Zhong, and Tan Peng

Subjects

Pulverized coal-fired boiler, Chemistry, 020209 energy, General Chemical Engineering, Nuclear engineering, Organic Chemistry, Boiler (power generation), Energy Engineering and Power Technology, Mineralogy, 02 engineering and technology, Combustion, Reaction rate, Fuel Technology, 020401 chemical engineering, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Combustor, Char, 0204 chemical engineering, NOx

Abstract

The burner tilt angle has a significant influence on the combustion characteristics of a furnace, but few studies have focused on this topic. In this study, a numerical model was developed and validated to investigate the effect of the burner tilt angle on the combustion and NOX emission characteristics of a 700 MWe pulverized-coal-fired boiler with deep-air-staging technology. The turbulence, heat transfer and chemical reactions in the furnace were reproduced in detail by the model. Deep insight into the effects of burner tilt angle on combustion and NOX emission characteristics was acquired. The results show that the turbulence intensity in the burnout zone of furnace increases as the burner tilt angle increases, leading to a significant increase in the reaction rate of CO combustion. Hence, the level of CO emission is continuously reduced. The char burnout rate changes little with increasing burner tilt angle since the kinetic reaction rate and oxygen diffusion rate increase while the particle residence time decreases. The NOX emission increases as the burner is tilted farther upward because of an enhancement in fuel NO formation and a decrease in NO reburning. This study provides useful guidelines for improving the performance of deep-air-staged tangentially coal-fired boilers.

Published

2017

16. Formation of the stratigraphic hydrocarbon accumulations of the Upper Yabus Formation in the Northern Sub-basin of the Melut Basin, South Sudan

Author

Yanjun Zhao, Wenzhu Pang, Wang Lei, Ma Lun, Chen Bintao, Pingsheng Wei, Zhongsheng Shi, Xue Luo, and Shi Jianglong

Subjects

Rift, 010504 meteorology & atmospheric sciences, Lithology, Geochemistry, Geology, 010502 geochemistry & geophysics, 01 natural sciences, Petroleum reservoir, Sedimentary depositional environment, Source rock, Facies, Petroleum geology, Paleogene, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

The Melut Basin is an important petroliferous rift basin in Africa, and a large number of structural hydrocarbon accumulations of the Paleogene Yabus and Samma Formations have been discovered in it. However, there are few published research results and exploration discoveries on stratigraphic hydrocarbon accumulations in the Melut Basin. Based on information from the evaluation of the lithology assemblage, oil-source, migration pathway, preservation condition and the detailed analysis of typical exploration cases, the favorable exploratory interval, formation conditions and accumulation characteristics of the stratigraphic hydrocarbon accumulations have been studied in the northern Melut sub-basin. The sedimentary facies study indicated that the Upper Yabus Formation developed widespread delta front deposits with the lithology assemblage of “sand wrapped by mud”, which was conducive to forming depositional stratigraphic traps dominated by facies change or depositional pinchout. The Adar Formation is a set of mudstone deposition with a thickness of 200–600 m above the Yabus Formation and well sealed the Yabus and Samma hydrocarbon accumulations as the regional top seal. The parameters of organic matter, and the thickness and distribution of source rocks showed that the Al Renk Formation has good source rock quality with an average TOC value of 2.08% wt. and type II kerogen prone to oil generation. The thermal modelling revealed that the Al Renk source rocks continuously generated and expelled hydrocarbon since the Late Cretaceous to the present and provided sufficient oil source for the Upper Yabus stratigraphic traps. The tectonic evolution research showed that the multi-stage rifting cycles made the Melut Basin develop numerous normal faults, which provided essential vertical migration pathways for the hydrocarbon charging of the Paleogene stratigraphic traps. Among these faults, the basinal border faults and the intra-basinal late-rifting faults are the primary hydrocarbon conduit faults. The details of exploration cases showed that the hydrocarbon conduit faults are the key controlling factors for the formation of the Upper Yabus stratigraphic hydrocarbon accumulations, and the stratigraphic traps jointly dominated by lithology change (depositional pinchout) and hydrocarbon conduit faults have low hydrocarbon filling risk. The sandstones of the Upper Yabus Formation are shallow (700–2500 m) and have high porosity with a value of greater than 20% and high oil production of a few hundred to more than 1000 barrels per day. Therefore, the Upper Yabus Formation develops favorable petroleum geology conditions for the formation of stratigraphic hydrocarbon accumulations, and exploring such stratigraphic traps is of great significance to the increasing exploration in the mature northern Melut sub-basin.

Published

2021

17. Experimental and DFT studies on the characteristics of PbO/PbCl2 adsorption by Si/Al- based sorbents in the simulated flue gas

Author

Ma Lun, Gang Chen, Qingyan Fang, Cheng Zhang, and Yu Shenghui

Subjects

021110 strategic, defence & security studies, Flue gas, Environmental Engineering, Materials science, Health, Toxicology and Mutagenesis, Inorganic chemistry, Doping, 0211 other engineering and technologies, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Pollution, Gibbs free energy, law.invention, Bond length, symbols.namesake, Adsorption, Molecular geometry, law, symbols, Environmental Chemistry, Calcination, Density functional theory, Waste Management and Disposal, 0105 earth and related environmental sciences

Abstract

Mineral oxides are effective in-furnace sorbents used to control lead (Pb) emissions in flue gas at high temperatures. In this paper, the PbO/PbCl2 adsorption characteristics of sorbents were investigated via experimental and density functional theory (DFT) methods. The results show that Si/Al-based compounds can chemically adsorb Pb, and the adsorption is related to the Si-O and Al-O bonds in the sorbents. Exposed Si and O atoms on SiO2 surfaces and exposed Al and O atoms on Al2O3 surfaces are the active sites for Pb adsorption, and PbO is easier to remove than PbCl2. Pb adsorption is promoted in a mixture of SiO2 and Al2O3. Doping Si atoms into Al2O3(100) promotes PbO adsorption, and doped three-coordinate Si atoms have a more obvious promotion effect than doped two-coordinate Si atoms. Doping Al atoms into SiO2(001) has no obvious effect on PbO adsorption. The effect of temperature on Pb adsorption was studied by thermodynamic analysis. The Gibbs free energy difference for PbO adsorption on SiO2(001) increases from −373.04–32.42 kJ/mol as the temperature increases from 300 to 1800 K. High-temperature calcination changes the bond length and bond angle of the system, affecting the stabilities of atomic configurations and decreasing the Pb adsorption capacity.

Published

2021

18. Deep insight into the effect of NaCl/HCl/SO2/CO2 in simulated flue gas on gas-phase arsenic adsorption over mineral oxide sorbents

Author

Cheng Zhang, Gang Chen, Qingyan Fang, Ma Lun, Yu Shenghui, and Tan Peng

Subjects

inorganic chemicals, 021110 strategic, defence & security studies, Flue gas, Environmental Engineering, Mineral, integumentary system, Chemistry, Health, Toxicology and Mutagenesis, Inorganic chemistry, 0211 other engineering and technologies, Oxide, Coal combustion products, chemistry.chemical_element, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Pollution, chemistry.chemical_compound, Adsorption, Acid gas, Fly ash, Environmental Chemistry, Waste Management and Disposal, Arsenic, 0105 earth and related environmental sciences

Abstract

Coal combustion is one of the major pathways by which arsenic enters the ecological environment. An effective method to control arsenic emissions in-furnace is to transform the arsenic from a vapour to fly ash particles using mineral sorbents. However, flue gas components have a significant effect on gas-phase arsenic adsorption, which limits the industrial application of mineral sorbents. In this paper, the effect mechanism of flue gas components (NaCl/HCl/SO2/CO2) on gas-phase arsenic adsorption over different mineral oxide sorbents was investigated. The results demonstrate that the order of arsenic adsorption is CaO > MgO/Fe2O3> NaCl > Al2O3 > SiO2. NaCl promotes the arsenic adsorption of CaO above 800 °C, and the arsenic removal efficiency of CaO with 5 % NaCl is 52.51 % at 900 °C. NaCl inhibits the arsenic adsorption of MgO and Fe2O3, and promotes arsenic adsorption by Al2O3 and SiO2. Acid gases inhibit arsenic adsorption by the sorbents and the order of the inhibition intensity of acid gases at 700 °C is HCl > SO2 > CO2. The active sites (CaO, FeO, or AlO bonds) in the sorbents are the main reaction sites for arsenic adsorption, and captured arsenic is in the form of AsO21- and AsO43-.

Published

2021

19. Geochemical mechanism of lead vapors over fly ash cenospheres in simulated flue gas

Author

Cheng Zhang, Gang Chen, Qingyan Fang, Tan Peng, Yu Shenghui, and Ma Lun

Subjects

Reaction mechanism, Flue gas, Sorbent, Chemistry, 020209 energy, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, Coal combustion products, 02 engineering and technology, Fuel Technology, Adsorption, 020401 chemical engineering, Chemical engineering, Cenosphere, Fly ash, 0202 electrical engineering, electronic engineering, information engineering, Thermal stability, 0204 chemical engineering

Abstract

Coal combustion is one of the major pathways by which lead (Pb) enters the ecological environment. An effective method to control Pb emissions in a furnace is to transform the Pb from vapors to particles using Si-Al-based sorbents. However, the high price, poor thermal stability, and difficult molding of sorbents limits their application. Fly ash cenospheres (FACs) prepared from the waste of coal-fired power plants, which are mainly composed of SiO2 and Al2O3, are ideal materials for Pb sorbents because of their high strength, light weight and low price. In this study, the adsorption and reaction mechanisms of FACs and several Si-Al-based sorbents for Pb vapors were investigated in a two-stage fixed-bed reaction system, and the thermal stability and regeneration characteristics of FACs were tested. The results indicate that the adsorption capacity for Pb vapors is FAC > kaolin > SiO2 > γ-Al2O3. The acidic sites, such as Si-O and Al-O bonds in FACs, were the main reaction sites for Pb adsorption and captured Pb in the form of stable Pb compounds (Pb2+). As the temperature increased from 700 to 1200 °C, the Pb adsorbed by FACs increased, and 55.21% of the Pb in the simulated flue gas was removed at 1200 °C. Kaolin is an excellent sorbent for Pb vapors. The adsorption capacity of kaolin for Pb first increases and then decreases with increasing temperature, and the maximum removal rate occurs at 1000 °C, reaching 33.46%. In addition, FACs are thermally stable and reusable. Therefore, the high-temperature application of FACs to remove Pb vapors has good prospects.

Published

2021

20. Effect of the separated overfire air location on the combustion optimization and NO reduction of a 600 MW FW down-fired utility boiler with a novel combustion system

Author

Dangzhen Lv, Yiping Chen, Ma Lun, Gang Chen, Qingyan Fang, Tan Peng, Xuenong Duan, and Cheng Zhang

Subjects

Engineering, Waste management, business.industry, 020209 energy, Mechanical Engineering, Nozzle, Boiler (power generation), Combustion system, 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, Combustion, General Energy, Fly ash, 0202 electrical engineering, electronic engineering, information engineering, business, NOx

Abstract

A novel combustion system has been applied to a 600 MWe down-fired boiler to reduce NOx emissions without producing an obvious increase in the carbon content of fly ash. The system mainly includes moving fuel-lean nozzles from the arches to the front/rear walls, and re-arranging the staged air, as well as introducing separated-over-fire air (SOFA). This paper evaluates the effects of the SOFA locations (on the arches, on the throat, and on the upper furnace) on the combustion and NOx emissions characteristics using simulations. The numerical results are in good agreement with the measured results. Compared to the original combustion system, significant NOx reduction (approximately 50%) is found for all three SOFA location settings. Taking economic efficiency and NOx emissions into account, the SOFA on the upper furnace is adopted in the actual modification, and no negative effects are observed.

Published

2016

21. Analysing momentum balance over a large wind farm using a numerical weather prediction model

Author

Ma. Lun, Takafumi Nishino, and Thomas D. Dunstan

Subjects

History, numerical weather prediction (NWP), Meteorology, Momentum balance, Environmental science, Numerical weather prediction, streamwise pressure gradient, Computer Science Applications, Education

Abstract

This study attempts to better understand the mechanisms of wind farm blockage effect by analysing momentum balance in realistic atmospheric flow over an idealised large offshore wind farm. The analysis is performed following the two-scale momentum theory, which predicts the importance of three different terms in the farm-scale momentum balance, namely the streamwise pressure gradient, Coriolis force and acceleration/deceleration terms. A numerical weather prediction (NWP) model is used as a realistic farm-scale flow model in this study to investigate how these three terms tend to change in time. Initial results suggest that the streamwise pressure gradient may be enhanced substantially by the resistance caused by the wind farm, whereas its influence on the other two terms appears to be relatively minor. These results suggest the importance of modelling the farm-induced pressure gradient accurately for various weather conditions in future studies of wind farm blockage.

Published

2020

22. Investigation on the influence of sulfur and chlorine on the initial deposition/fouling characteristics of a high-alkali coal

Author

Gang Chen, Yuan Changle, Qingyan Fang, Yu Shenghui, Ma Lun, Xu Hao, and Cheng Zhang

Subjects

Flue gas, Fouling, business.industry, 020209 energy, General Chemical Engineering, Sodium, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Alkali metal, Sulfur, Fuel Technology, 020401 chemical engineering, chemistry, Chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Chlorine, Coal, 0204 chemical engineering, business, Deposition (chemistry)

Abstract

Sodium, calcium, sulfur and chlorine in the flue gas of coal-fired boilers are the main cause of ash deposition/fouling in heat exchangers. However, there are still many debates on the mechanism of ash deposition/fouling due to the lack of direct micro evidence. This paper aims to clarify the initial deposition/fouling characteristics of a high-alkali coal by computer-controlled scanning electron microscopy (CC-SEM). The results demonstrate that temperature has an influence on the deposition/fouling compounds. The crystalline compounds in the samples at 900 °C were mainly CaSO4 and Ca2Al2SiO7, while the compounds in the samples at 500 °C were mainly NaCl. Sulfur had a significant adsorption effect on sodium and calcium at 900 °C, while chlorine had a significant adsorption effect on sodium at 500 °C. A 3-layer microstructure of deposition/fouling was found after the samples were stripped by molecular force. Additionally, deposition/fouling could be divided into three stages: the formation of sodium salt precursors, the growth of loose structural aluminosilicates and the adhesion of particulates on the surface. Sulfates, especially Na2SO4 and CaSO4 formed a precursor for the initial deposition/fouling of high-alkali coal.

Published

2020

23. Application of Different Combustion Models for Simulating the Co-combustion of Sludge with Coal in a 100 MW Tangentially Coal-Fired Utility Boiler

Author

Cheng Zhang, Gang Chen, Qingyan Fang, Ma Lun, and Tan Peng

Subjects

business.industry, 020209 energy, General Chemical Engineering, Boiler (power generation), Energy Engineering and Power Technology, Coal combustion products, 02 engineering and technology, Computational fluid dynamics, Combustion, law.invention, Ignition system, Fuel Technology, law, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Coal, Char, business, Process engineering, NOx

Abstract

Co-combustion of sludge with coal is a promising sludge disposal approach. In this study, three different combustion models, including different turbulent gas-phase combustion and char surface combustion sub-models, were employed to simulate the combustion and emission characteristics of co-combusting sludge with coal in a 100 MW tangentially coal-fired utility boiler. By comparison of the numerical results from different combustion models to a set of full-scale coal–sludge co-combustion field experiments, a precise and suitable computational fluid dynamic (CFD) model was finally developed. The comparison result demonstrated that the finite-rate/eddy-dissipation model together with the multiple-surface-reaction model, which have carefully considered the effect of high moisture content on the fuel ignition and char combustion processes, were competent in modeling the characteristics of coal–sludge co-combustion. On the basis of the developed numerical model, the ignition, char burnout, and NOx emission cha...

Published

2015

24. Influence of Separated Overfire Air Ratio and Location on Combustion and NOx Emission Characteristics for a 600 MWe Down-Fired Utility Boiler with a Novel Combustion System

Author

Gang Chen, Qingyan Fang, Ma Lun, Yiping Chen, Cheng Zhang, Dangzhen Lv, and Xuenong Duan

Subjects

Fuel Technology, Waste management, General Chemical Engineering, Fly ash, Nozzle, Boiler (power generation), Combustion system, Energy Engineering and Power Technology, Environmental science, Overall performance, Combustion, NOx

Abstract

To reduce NOx emissions without introducing an obvious increase in the carbon content of fly ash, a novel combustion system was applied to a 600 MWe Foster Wheeler (FW) down-fired boiler. This approach mainly consisted of moving fuel-lean nozzles from the arches to the front/rear walls, rearranging staged air, and introducing separated overfire air (SOFA). The aim of this work was to evaluate the overall performance of the novel combustion system relative to different SOFA ratios (i.e., 15, 20, 25, and 30%) and different SOFA locations in the upper furnace (1.0, 2.0, and 3.0 m above the arches) using numerical simulations and experimental measurements. Both numerical and experimental results showed that, with increasing the SOFA ratio from 15 to 20%, NOx emissions were greatly reduced but the carbon content in the fly ash increased slightly. With a further increase from 20 to 30%, NOx emissions slightly decreased but the carbon content in the fly ash increased substantially. Considering both the environme...

Published

2015

25. Influence of vertical burner tilt angle on the gas temperature deviation in a 700 MW low NO x tangentially fired pulverised-coal boiler

Author

Gang Chen, Qingyan Fang, Ma Lun, Dengfeng Tian, Cheng Zhang, Tan Peng, Lijin Zhong, and Dianping Zhang

Subjects

Flue gas, Materials science, Convective heat transfer, Tangential firing, business.industry, General Chemical Engineering, Boiler (power generation), Energy Engineering and Power Technology, Mechanics, Residual, Fuel Technology, Combustor, Fluent, Coal, business

Abstract

In the present paper, computational fluid dynamic modelings were established to research a newly presented re-heat steam temperature deviation solution on the basis of FLUENT 6.3.26 considering a 700 MWe tangentially fired pulverised-coal boiler, which confronted with severe flue gas and re-heat steam temperature deviation. The model was solidly validated by grid independence test and comparison with the experimental data obtained from a series of on-site measurements. Upon reliable validation, the model was further used to investigate the forming mechanism of re-heat steam temperature deviation as well as the influence of burner tilt angle on it. The conclusions mainly include (1) Residual swirling flow in the upper furnace caused the flue gas velocity and temperature deviations in crossover pass. For a typical anticlockwise tangential firing system, the flue gas velocity and temperature were lower in left part of crossover pass. The deviation of flue gas further generated the convective heat transfer imbalance of final re-heater, therefore, the temperature deviation of re-heat steam was severe. (2) Tilting the burner upward can effectively reduce the intensity of residual flow as well as the flue gas deviation degree. The + 11° tilt angle of burner was relatively optimum considering the flue gas deviation and final re-heater overheating potential. Specifically, the intensity of residual swirl flow dropped 44% with burner tilting upward for + 11°. Practical operation of boiler demonstrated that the reheat steam temperature deviation was reduced from 22 °C to 10 °C in this case. (3) When the tilt angle of additional air (AA) was bias set, the flow field of upper furnace was changed. Consequently, the residual swirl flow intensity and the flue gas deviation were reduced considerably. On-site measurements indicated that the combination of tilting burner upward for + 11° and setting the bias of AA tilt angle for 10° can further reduce the re-heat steam temperature deviation to 4 °C.

Published

2015

26. Reduced‐dimension clutter suppression method for airborne multiple‐input multiple‐output radar based on three iterations

Author

Ma Lun, Feng Da-zheng, and He Jie

Subjects

Adaptive filter, Continuous-wave radar, Space-time adaptive processing, Radar tracker, Dimension (vector space), Filter (video), Control theory, Separable filter, Clutter, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Electrical and Electronic Engineering, Mathematics

Abstract

A reduced-dimension space time adaptive processing (STAP) for airborne multiple-input multiple-output (MIMO) radar based on three iterations is proposed. The optimum filter for MIMO-STAP is described as a separable filter, and the optimal weight vector in high dimension can be iteratively solved by three lower dimension weight vectors. Consequently, the quite high sample support and computational complexity in optimal MIMO-STAP can be efficiently reduced. For short data records, the proposed method can achieve better clutter suppression performance. Simulation results demonstrate the effectiveness of the proposed method.

Published

2015

27. A novel flame-anchorage micro-combustor: Effects of flame holder shape and height on premixed CH4/air flame blow-off limit

Author

Xiaoting Wang, Xu Hao, Ma Lun, Gang Chen, Qingyan Fang, and Cheng Zhang

Subjects

Materials science, 020209 energy, Flow (psychology), Heat recirculation, Energy Engineering and Power Technology, 02 engineering and technology, Mechanics, Combustion, Industrial and Manufacturing Engineering, 020401 chemical engineering, Limit (music), 0202 electrical engineering, electronic engineering, information engineering, Fluent, Combustor, 0204 chemical engineering, Microscale chemistry, Flammability

Abstract

Maintaining stable combustion is one of the major challenges for microscale combustors. In this study, a novel premixed CH4/air flame micro-combustor combining a flame holder, backward-facing step and preheating channel is developed to enhance the flame anchorage and extend the blow-off limits. The effects of flame holder shape (triangle and rectangle) and height (H = 0.0, 0.5, 1.0, 1.5 and 2.0 mm) on the combustion stability are studied numerically by FLUENT 16.0. The results show that this micro-combustor not only can considerably anchor the flame root owing to flow recirculation but also can further improve CH4 flammability owing to heat recirculation. Compared with the rectangle flame holder, the triangle flame holder achieves the higher blow-off limits owning to the larger recirculation zone and better preheating effect. As the flame holder height increases, (i) the recirculation zone sizes near the flame root decrease, weakening the flame-root anchorage ability, and (ii) the heat recirculation effect becomes stronger, improving CH4 flammability. Under the combined effects of flow recirculation and heat recirculation, the highest flame blow-off limits are attained when H = 0.5 mm. The flame holder with triangle shape and H = 0.5 mm attains the highest flame blow-off limits (10.3 m/s and 6.2 m/s at Φ = 0.7 and 0.5).

Published

2019

28. Effect of Gallium and Indium Co-Substituting on Upconversion Properties of Er/Yb:Yttrium Aluminum Garnet Powders Prepared by the Co-Precipitation Method

Author

Zhengfa Hu, Qian Liu, Wei Zhang, Jie Luo, Zuyong Feng, Xia Sheng, Ma Lun, Xiu-ping Zhang, and Yunling Liang

Subjects

010302 applied physics, Materials science, Biomedical Engineering, Analytical chemistry, Infrared spectroscopy, chemistry.chemical_element, Bioengineering, Phosphor, General Chemistry, Yttrium, Condensed Matter Physics, 01 natural sciences, Photon upconversion, X-ray photoelectron spectroscopy, chemistry, 0103 physical sciences, General Materials Science, Gallium, Luminescence, Indium

Abstract

Gallium and Indium co-substituted Yb, Er:YAG was fabricated through the chemical co-precipitation method. The formation process and structure of the Ga3+ and In3+ substituted phosphor powders were characterized by the X-ray diffraction, thermo-gravimetry analyzer, infrared spectra, and X-ray photoelectron spectroscopy, and the effects of Ga3+ and In3+ concentration on the luminescence properties were investigated by spectrum. The results showed that the blue shift occurred after the substitution of Ga3+ and In3+ for Al3+ in matrix, and the intensity of emission spectrum was affected by the concentration of Ga3+ and In3+.

Published

2016

29. Maximum Total Variation Autofocus Algorithm for SAR Imaging

Author

Ru Feng, Ma Lun, and WU Xiangdong

Subjects

Autofocus, Variation (linguistics), Computer Networks and Communications, law, Computer science, Algorithm, Software, law.invention

Published

2012

30. A iteration-free multi-channel mismatch estimation method for parallel time-interleaved system

Author

Wang Yuanqing, Ma Lun, and Xiang Yu

Subjects

History, Time interleaved, Computer science, Algorithm, Multi channel, Computer Science Applications, Education

Published

2018

31. A novel autofocus algorithm based on maximum total variation criteria for SAR images

Author

Liao Gui-sheng and Ma Lun

Subjects

Autofocus, Synthetic aperture radar, Computational complexity theory, Computer science, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Phase (waves), Computer Science::Software Engineering, Electronic, Optical and Magnetic Materials, law.invention, Domain (software engineering), Image (mathematics), Azimuth, law, Computer vision, Artificial intelligence, Electrical and Electronic Engineering, Focus (optics), business, Algorithm

Abstract

A novel autofocus algorithm for synthetic aperture radar (SAR) based on total variation is presented in this paper. The method, which starts with a complex phasedegraded SAR image, after the phase errors model is introduced into the range-compressed phase-history domain, carries out phase errors correction by changing the focus till the total variation of the azimuth profile is maximized. Compared with the minimum entropy autofocus algorithm, the autofocus algorithm has less computational complexity and is easier to implement. The simulation and the processing results of the measured data show the validity of the proposed method.

Published

2007

32. Reducing NOx Emissions for a 600 MWe Down-Fired Pulverized-Coal Utility Boiler by Applying a Novel Combustion System

Author

Gang Chen, Qingyan Fang, Xihuan Wang, Yiping Chen, Dangzhen Lv, Ma Lun, Cheng Zhang, and Xuenong Duan

Subjects

Nozzle, Combustion, Environmental Chemistry, Coal, Computer Simulation, Staged combustion, NOx, Environmental Restoration and Remediation, Nitrites, Air Pollutants, Nitrates, Pulverized coal-fired boiler, Waste management, business.industry, Environmental engineering, Boiler (power generation), Temperature, Reproducibility of Results, Numerical Analysis, Computer-Assisted, General Chemistry, Oxygen, Fly ash, Environmental science, business, Power Plants

Abstract

A novel combustion system was applied to a 600 MWe Foster Wheeler (FW) down-fired pulverized-coal utility boiler to solve high NOx emissions, without causing an obvious increase in the carbon content of fly ash. The unit included moving fuel-lean nozzles from the arches to the front/rear walls and rearranging staged air as well as introducing separated overfire air (SOFA). Numerical simulations were carried out under the original and novel combustion systems to evaluate the performance of combustion and NOx emissions in the furnace. The simulated results were found to be in good agreement with the in situ measurements. The novel combustion system enlarged the recirculation zones below the arches, thereby strengthening the combustion stability considerably. The coal/air downward penetration depth was markedly extended, and the pulverized-coal travel path in the lower furnace significantly increased, which contributed to the burnout degree. The introduction of SOFA resulted in a low-oxygen and strong-reducing atmosphere in the lower furnace region to reduce NOx emissions evidently. The industrial measurements showed that NOx emissions at full load decreased significantly by 50%, from 1501 mg/m3 (O2 at 6%) to 751 mg/m3 (O2 at 6%). The carbon content in the fly ash increased only slightly, from 4.13 to 4.30%.

Published

2015

33. Thermal Management Technology of a Liquid Cooling Thin-disk Oscillator

Author

姜彦玲 Jiang Yan-ling, 佘江波 She Jiang-bo, 聂荣志 Nie Rong-zhi, 马仑 Ma Lun, 李伟 Li Wei, 赵朋飞 Zhao Peng-fei, and 杨鹏 Yang Peng

Subjects

Materials science, Computer cooling, Thin disk, business.industry, Optoelectronics, Thermal management of electronic devices and systems, business, Atomic and Molecular Physics, and Optics

Published

2016

34. Elastic material constants for isotropic granular solids with particle rotation

Author

Ma Lun and Ching S. Chang

Subjects

Materials science, Applied Mathematics, Mechanical Engineering, Isotropy, Stiffness, Mechanics, Condensed Matter Physics, Granular material, Microstructure, Finite element method, Classical mechanics, Mechanics of Materials, Modeling and Simulation, medicine, Material constants, General Materials Science, Boundary value problem, medicine.symptom, Elasticity (economics)

Abstract

The granular material perceived as a collection of particles is modelled as a micropolar continua taking account of particle interaction and microstructure of the material. Explicit expressions of constitutive constants in terms of elastic inter-particle stiffness are derived for granular solids with Isotropie random fabric distribution. Based on the derived expressions for Isotropic material, six material constants are identified instead of two constants used in conventional elasticity. The derived constitutive constants in explicit terms of inter-particle contact properties provide a fundamental understanding of these constants and furnish useful inter-relations among these constants. The physical meaning of these material constants is discussed with emphasis on the role of particle spin. Finite element analysis incorporating these material constants is described and used to obtain solutions for boundary value problems. Examples are given for granular solids under boundary pressure to show the effects of inter-particle properties and material constants on the behavior of stress distribution and deformation in granular material.

Published

1992

35. ICOPE-15-C075 Effects of combined application of SOFA and fuel-lean coal/air retrofit on NOx emissions characteristics in a subcritical W-shaped boiler

Author

Jiao Qingfeng, Qingyan Fang, Yiping Chen, Dundun Wang, Xuenong Duan, Dangzhen Lv, and Ma Lun

Subjects

Engineering, Waste management, business.industry, Environmental engineering, Boiler (power generation), Coal, business, Clean coal technology, NOx

Published

2015