Derleme
BibTex RIS Kaynak Göster

A review of magnetic field assisted combustion

Yıl 2024, Cilt: 9 Sayı: 1, 175 - 198, 22.03.2024
https://doi.org/10.58559/ijes.1412125

Öz

Since the early 1980s, research on magnetically enhanced combustion has garnered significant attention and importance. These studies have primarily focused on investigating the influence of magnetic fields on the combustion process of fuels. During this period, studies that highlighted the potential to alter molecular structures and properties through powerful magnetic fields emerged as significant contributors to the field. Simultaneously, the effects of magnetic fields on flame formation, behavior, and propagation have been thoroughly explored through various combustion models and experiments. The significance of these investigations lies in their contribution to a better understanding of the effects of combustion on energy efficiency and emission profiles. The capability of strong magnetic fields to modify molecular arrangements can enhance fuel atomization, promoting the creation of a more homogeneous fuel-air mixture. Additionally, the potential of magnetic fields to influence the reaction rates and behavior of gas molecules holds promise for achieving improved combustion and reduced emission production. Investigations have also focused on how chemical reactions of fuels are altered under magnetic fields and how these changes translate into motor performance. Specifically, research has highlighted how chain reactions such as gas combustion and explosion can be altered under magnetic fields, potentially reducing the production of harmful emissions like carbon monoxide, hydrocarbons, and nitrogen oxides. In this context, a comprehensive exploration of various aspects such as flame formation, engine performance, emissions, and explosion intensity under the influence of magnetic fields is of paramount importance. Future endeavors can potentially yield a more profound and precise understanding of the effects of magnetic fields on combustion processes and enable the utilization of this knowledge for more efficient and cleaner energy production across different industrial applications.

Kaynakça

  • [1] Sevim C. Küresel enerji jeopolitiği ve enerji güvenliği. Yaşar Üniversitesi E-Dergisi 2012; 7(26): 4378-4391.
  • [2] The World Bank (N.D.) World Bank Open Data: Population, Total 2022; Https://Data.Worldbank.Org/Indicator/SP.POP.TOTL
  • [3] International Energy Agency (N.D.) World Oil Supply And Demand, 1971-2020. IEA, Paris. 2021; Https://Www.Iea.Org/Data-And-Statistics/Charts/World-Oil-Supply-And-Demand-1971-2020
  • [4] İlbaş M, Yılmaz İ. Farklı ısıl güçlerdeki kazanlarda yanma ve emisyon davranışının araştırılması. Erciyes Üniversitesi Fen Bilimleri Enstitüsü Fen Bilimleri Dergisi 2002; 18(1): 18-27.
  • [5] Yılmaz İ, İlbaş M. Hidrojen-metan karışım yanmasında yanma model sabitinin değerlendirilmesi. Isı Bilimi ve Tekniği Dergisi 2010; 30(1): 45-57.
  • [6] Saksono N. Magnetizing kerosene for increasing combustion efficiency. Jurnal Teknologi 2005; Edisi No. 2, Tahun XIX, 155-162.
  • [7] Bian YC, Ding W, Hu L, Et Al. Magneto-revealing and acceleration of hidden kirkendall effect in galvanic replacement reaction. Phys. Chem. Lett 2021; 12(22): 5294–5300.
  • [8] Alnaimat, Dagher S, Mathew B, Et Al. Microfluidics based magnetophoresis: A review. The Chemical Record 2018; 18(11): 1596-1612.
  • [9] Li JQ, Ma TB, Ning JG. Mechanism of explosion-induced disturbance in natural magnetic field. Chinese Journal Of Theoretical And Applied Mechanics 2018; 50(05): 1206-1218.
  • [10] Gilart RA, Ungaro MRB, Rodríguez CEA, Et Al. Performance and exhaust gases of a diesel engine using different magnetic treatments of the fuel. Journal of Mechanical Engineering and Sciences 2020; 14(1): 6285- 6294.
  • [11] Chen CY, Lee WJ, Mwangi JK, Et Al. Impact of magnetic tube on pollutant emissions from the diesel engine. Aerosol and Air Quality Research 2017; 17(4): 1097-1104.
  • [12] Al-Rawaf MA. Magnetic field effects on spark ignition engine performance and its emissions at high engine speeds. Journal of Engineering and Development 2015; 19(4): 37-48.
  • [13] Kumar V, Rastogi V, Agarwal S, Et Al. Investigation of temperature profile and temperature stability of micro diffusion flame under the influence of magnetic field by use of a holo-shear lens-based interferometer. Optical Engineering 2020; 59(6): 064107.
  • [14] Ueno S, Harada K. Experimental difficulties in observing the effects of magnetic fields on biological and chemical processes. IEEE Transactions on Magnetics 1986; 22(5): 868-873.
  • [15] Ueno S, Harada K. Effect of magnetic fields on flames and gas flow. IEEE Transactions on Magnetics 1985;21(5).
  • [16] Ueno S, Harada K. Combustion process under strong DC magnetic fields. IEEE Transactions On Magnetics 1987; 23(5): 2752-2754.
  • [17] Ueno S, Esaki H, Harada R. Magnetic field effect on combustion. IEEE Translation Journal on Magnetics in Japantjmj1987; 2(9).
  • [18] Guo H, Chen Y, Yao R. A study of magnetic effects on the physicochemical properties of individual hydrocarbons. IEEE Transactions on Magnetics 1986.
  • [19] Wakayama N. Behavior of gas flow under gradient magnetic fields. Journal of Applied Physics 1991; 69: 2734–2736.
  • [20] Wakayama N. Effect of a gradient magnetic field on the combustion of methane in air. Chemical Physics Letters 1992; 188: 279-281.
  • [21] Wakayama N. Magnetic promotion of combustion in diffusion flames. Combustion and Flame 1993; 93: 207-214.
  • [22] Wakayama N, Ito H, Kuroda Y, Fujıta O, Ito K. Magnetic support of combustion in diffusion flames under microgravity. Combustion and Flame 1996; 107: 187-192.
  • [23] Fujita O, Ito K, Chida T, Nagai S, Takeshita Y. Determination of magnetic field effects on a jet diffusion flame in a microgravity environment. Twenty-Seventh Symposium (International) on Combustion/The Combustion Institute 1998; 2573–2578.
  • [24] Morozov YG, Kuznetsov MV. Effect of magnetic fields on combustion electromotive force. Combustion, Explosion and Shock Waves 1999; 35(1): 18-22.
  • [25] Baker J, Varagani R. Models and experiments on laminar diffusion flames in non-uniform magnetic fields. Seventh International Workshop on Microgravity Combustion and Chemically Reacting Systems 2003; 317-320.
  • [26] Iwata N, Tsubuki S, Takaki Y, Watanabe K, Sekiguchi, M, Hosoki E, Saido TC. Identification of the major aβ 1– 42-degrading catabolic pathway in brain parenchyma: suppression leads to biochemical and pathological deposition. Nature Medicine 2000; 6(2): 143-150.
  • [27] Tung H, Cédric D, Anne V, Agnès J, Gilles L. A global tool for environmental assessment of roads– application to transport for road building. In European Conference of Transport Research Institutes The Hague 2010.
  • [28] Loskutova O, Walker TR, Crittenden PD, Dauvalter VA, Jones V, Kuhry P, Pystina T. Multiple indicators of human impacts on the environmentin the pechora basin. North-Eastern European Russia. Ecological Indicators 2009; 9(4): 765-779.
  • [29] Tao R. Investigate effects of magnetic fields on fuels. Department of Physics, Temple University, Philadelphia 2004.
  • [30] Tao R, Xu X. Reducing the viscosity of crude oil by pulsed electric or magnetic field. Energy & Fuels 2006; 20: 2046-2051.
  • [31] Saksono N. Magnetising kerosene for increasing combustion efficiency. Jurnal Teknologi 2005; 2: 155-162.
  • [32] Chang KT, Weng CI. The effect of an external magnetic field on the structure of liquid water using molecular dynamics simulation. Journal of Applied Physics 2006; 100: 043917.
  • [33] Gilard V, Gillon P, Blanchard JN, Sarh B. Influence of a horizontal magnetic field on a co-flow methane/air diffusion flame. Combustion Science and Technology 2018; 180(10-11): 1920-1935.
  • [34] Evdokimov IN, Kornishin KA. Apparent disaggregation of colloids in a magnetically treated crude oil. Energy & Fuels 2009; 23(8): 4016-4020.
  • [35] Legros G, Gomez T, Fessard M, Guibert P, Torero J. Magnetically induced flame flickering. Proceedings of the Combustion Institute 2010; 33: 1095-1103.
  • [36] Jalali M, Ahmadi M, Yadaei F, Azimi M, Hoseini H. Enhancement of benzine combustion behaviour in exposure to the magnetic field. Journal of Clean Energy Technologies 2013; 1: 224-227.
  • [37] Ugare V, Dhoble A, Lutade S, Mudafale K. Performance of internal combustion (CI) engine under the influence of strong permanent magnetic field. Journal of Mechanical and Civil Engineering 2014; 3: 11-17.
  • [38] Kumar M, Agarwal S, Kumar V, Khan G, Shakher C. Experimental investigation on butane diffusion flame under the influence of magnetic field by using digital speckle pattern interferometry. Applied Optics 2015; 54(9): 2450-2460.
  • [39] Agarwal AK, Gupta T, Shukla PC, Dhar A. Particulate emissions from biodiesel fuelled CI engines. Energy Conversion and Management 2015; 94: 311-330.
  • [40] Elamin AA, Ezeldin M, Masaad AM, Suleman NM. Effect of magnetic field on some physical characteristics and cetane number of diesel fuel. American Journal of Applied Chemistry 2015; 3(6): 212-216.
  • [41] Singh A. Measurement of fuel flow behaviour of propane diffusion flame by dimensionless numbers under magnetic field application. International Journal of Combined Research and Development 2015; 4: 585-586.
  • [42] Wu W, Qu J, Zhang K, Chen W. Experimental studies of magnetic effect on methane laminar combustion characteristics. Combustion Science and Technology 2016.
  • [43] Barmina I, Zake M. Effects of magnetic field on swirling flame dynamics. Engineering for rural development, Jelgava 2016.
  • [44] Barmina I, Zake M. Magnetic field control of combustion dynamics. Latvian Journal of Physics and Technical Sciences 2017; 53(4): 36-46.
  • [45] Barmina I, Zake M, Strautins U, Marinaki U. Effects of gradient magnetic field on swirling flame dynamics. Engineering For Rural Development Jelgava 2017; 24.
  • [46] Morsi K. Combustion synthesis and the electric field: A review. International Journal of Self-Propagating High-Temperature Synthesis 2017; 26(3): 199–209.
  • [47] Boben RR, RamnathV, Lyons KM. Effect of moderate-strength magnetic field on local temperature in diffusion flames. Aeronautics and Aerospace Open Access Journal 2018; 2(4): 250–257.
  • [48] Agarwal S, Shakher C. Effect of magnetic field on temperature profile and flame flow characteristics of micro flame using talbot interferometer. Optic - International Journal for Light and Electron Optics 2018; 168: 817–826.
  • [49] Di Renzo M, Urzay J, De Palma P, De Tullio MD, Pascazio G. The effects of incident electric fields on counterflow diffusion flames. Combustion and Flame 2018; 193: 177–191.
  • [50] Ramnath V, Lyons KM. The potential of simple, low-cost permanent magnets for flame manipulation in flow fields. Aeronautics and Aerospace Open Access Journal 2018; 2(1).
  • [51] Marouf HH, Elsemary IM, Abdel Rahim AA, Abd Rabo MF. Effect of electromagnetic field on combustion of candle flame. Engineering Research Journal 2019; 1(39): 18–22.
  • [52] Perdana D, Adiwidodo S, Choifin M, Winarko WA. The effect of magnetic field variations in a mixture of coconut oil and jatropha on flame stability and characteristics on the premixed combustion. EUREKA: Physics and Engineering 2021; (5): 13–22.
  • [53] Perdana D. The experimental of impact of additional magnetic fields and nitrogen pressure on olive oil droplet combustion. Indonesian Journal of Applied Research (IJAR) 2023; 4(1): 1–10.
  • [54] Perdana D, Adiwidodo S, Winarko WA. The role of perforated plate and orientation of the magnetic fields on coconut oil premixed combustion. Energy 2022; 67(2): 77–84.
  • [55] Perdana D, Yuliati L, Hamidi N, Wardana ING. The role of magnetic field orientation in vegetable oil premixed combustion. Journal of Combustion 2020; 2020: 11.
  • [56] Perdana D, Setiyawan DG, Choifin M. Experimental study on flame characteristics of premixed combustion of kapok oil with various magnetic field. Orientations 2020; 8(1). Sjme Kinematika Juni 2023.
  • [57] Zharfa M, Karimi N. Intensification of MILD combustion of methane and hydrogen blend by the application of a magnetic field- a numerical study. Acta Astronautica 2021; 184: 259–268.
  • [58] Zhang Z, Wei Z. Experiment and simulation of the effects of non-uniform magnetic field on the regression rate of PMMA. Combustion and Flame 2021; 223: 337–348.
  • [59] Xie Y, Wei Z, Zhou, T, Zhen H, Liu Z, Huang Z. Combustion characteristics of small laminar flames in an upward decreasing magnetic field. Energies 2021; 14: 1969.
  • [60] Gao JC, Yang XG, Hu ST, Hong ZJ, Et Al. Effect of external magnetic field on acetylene explosion reaction. Explos. Shock Waves 2022; 42(07): 150-160.
  • [61] Zhou S, Gao J, Luo Z, Hu S, Wang L, Wang T. Role of ferromagnetic metal velvet and DC magnetic field on the explosion of a C3H8/air mixture-effect on reaction mechanism. Energy 2021; 239(21): 122218.
  • [62] Govindasamy P, Dhandapani S. Performance and emissions achievements by magnetic energizer with a single cylinder two-stroke catalytic coated spark ignition engine 2007.
  • [63] Govindasamy P, Dhandapani S. Experimental investigation on the effect of magnetic flux to reduce emissions and improve combustion performance in a two-stroke, catalytic-coated, spark-ignition engine. International Journal of Automotive Technology 2007; 8(5): 533-542.
  • [64] Govindasamy P, Dhandapani S. Reduction of NOX emission in bio diesel engine with exhaust gas recirculation and magnetic fuel conditioning. In GMSARN International Conference on Sustainable Development: Challenges and Opportunities for GMS 2007; 14.
  • [65] Fatih F, Saber G. Effect of fuel magnetism on engine performance and emissions. Australian Journal of Basic and Applied Sciences 2010; 4: 6354-6358.
  • [66] Faris AS, Al-Naseri SK, Jamal N, Isse R, Abed M, Fouad Z, Jasim H. Effects of magnetic field on fuel consumption and exhaust emissions in two-stroke engine. Energy Procedia 2012; 18: 327-338.
  • [67] Habbo ARA, A Khalil R, S Hammoodi H. Effect of magnetizing the fuel on the performance of an si engine. AL-Rafdain Engineering Journal (AREJ) 2011; 19(6): 84-90.
  • [68] Jain S, Deshmukh S. Experimental investigation of magnetic fuel conditioner in ic engine. IOSR Journal of Engineering, 2012; 2: 27-31.
  • [69] Siregar H, Nainggolan R. Electromagnetic fuel saver for enhancing the performance of the diesel engine. Global Journal of Researches in Engineering, Mechanical and Mechanics Engineering 2012; 12.
  • [70] Attar AR, Tipole P, Bhojwani V, Deshmukh S. Effect of magnetic field strength on hydrocarbon fuel viscosity and engine performance. International Journal of Mechanical Engineering and Computer Applications 2013; 1(7): 94-98.
  • [71] Garg R, Agarwal A. Fuel energizer: the magnetizer (a concept of liquid engineering). International Journal of Innovative Research & Development 2013; 2: 617-627.
  • [72] Vijayakumar P, Patro S, Pudi V. Experimental study of a novel magnetic fuel ionization method in four stroke diesel engines. International Journal of Mechanical Engineering and Robotics Research 2014; 3: 151-159.
  • [73] Abd-Allah GH. Using exhaust gas recirculation in internal combustion engines: A review. Energy Conversion and Management 2001; 43: 1027–1042.
  • [74] Patel PM, Rathod GP, Patel TM. Effect of magnetic field on performance and emission of single cylinder four stroke diesel engine. IOSR Journal of Engineering 2014; 4(5): 28-34.
  • [75] Sala A, Notti E. Preliminary tests of new magnetic device for fuel saving and emission reduction in fisheries. Third International Symposium on Fishing Vessel Energy Efficiency 2014; 1-5.
  • [76] Khedvan A, Gaikwad V. Review on effect of magnetic field on hydrocarbon refrigerant in vapour compression cycle. International Journal of Scientific Engineering and Technology Research 2015; 4: 1374-1378.
  • [77] Kacem SA, Ferdaouss L, Abrerrahim L, Mohammed B. Evaluation de l'impact de la pollution agricole sur la qualite des eaux souterraines de la nappe du gharb. European Scientific Journal 2016; 12(11).
  • [78] Gabiña G, Basurko OC, Notti E, Sala A, Aldekoa S, Clemente M, Uriondo Z. Energy efficiency in fishing: are magnetic devices useful for use in fishing vessels. Applied Thermal Engineering 2016; 94: 670-678.
  • [79] Gad MS. Assessment of biodiesel derived from waste cooking oil as an alternative fuel for diesel engines. International J. of Chem. Tech. Research 2016; 9(3): 140-146.
  • [80] Chen C, Lee W, Mwangi J, Wang L, Lu J. Impact of magnetic tube on pollutant emissions from the diesel engine. Aerosol and Air Quality Research 2017; 17: 1097-1104.
  • [81] Attar AR, Tipole P, Bhojwani V, Deshmukh S. Effect of magnetic field strength on hydrocarbon fuel viscosity and engine performance. International Journal of Mechanical Engineering and Computer Applications 2013; 1(7): 94-98.
  • [82] Kurji HJ, Imran MS. Magnetic field effect on compression ignition engine performance. ARPN Journal of Engineering and Applied Sciences 2018; 13(12): 3943-3949.
  • [83] Sahoo RR, Jain A. Experimental analysis of nanofuel additives with magnetic fuel conditioning for diesel engine performance and emissions. Fuel 2019; 236: 365-372.
  • [84] Niaki SOD, Khatamnejad H, Khalilarya S, Jafarmadar S, Mirsalim M, Gharehghani A. Experimental investigation on the effect of natural gas premixed ratio on combustion and emissions in an idi engine. Journal of Thermal Analysis and Calorimetry 2019; 138(6): 3977-3986.
  • [85] Oommen LP, Narayanappa KG. Assimilative capacity approach for air pollution control in automotive engines through magnetic field-assisted combustion of hydrocarbons. Environ Sci Pollut Res 2021; 28: 63661– 63671.
  • [86] Oommen LP, Narayanappa KG, Vijayalakshmi SK. Experimental analysis of synergetic effect of part-cooled exhaust gas recirculation on magnetic field-assisted combustion of liquefied petroleum gas. Arab J Sci Eng 2020; 45: 9187–9196.
  • [87] Oommen LP, Kumar GN. Influence of magneto-combustion on regulated emissions of an automotive engine under variable speed operation. Int. J. Vehicle Structures & Systems 2020; 12(1): 109-112.
  • [88] Oommen LP, Kumar GN. Analysis of cyclic variations and combustion behavior of liquid phase hydrocarbons under uniform axial and radial magnetic fields. In: Edwin Geo, V., Aloui, F. (eds) Energy and Exergy for Sustainable and Clean Environment 2023; 2. Green Energy and Technology. Springer, Singapore.
  • [89] Oommen LP, Kumar GN. Experimental analysis of conjoint effect of semi-cooled exhaust recirculation on combustion of liquid phase hydrocarbons under uniform magnetic fields. Arab J Sci Eng 2022; 47: 16049–16057.
  • [90] Pawar NR, Hudgikar SRK. Performance enhancement of multi-cylinder four stroke SI engine under the effect of magnetic field. In; (eds) Techno-Societal Springer Cham 2021;
  • [91] Brunekreef B, Holgate ST. Air pollution and health. Lancet 2002; 360(9341): 1233-1242.
  • [92] Mazaheri M, Johnson GR, Morawska L. An inventory of particle and gaseous emissions from large aircraft thrust engine operations at an airport. Atmos Environ 2011; 45(20): 3500–3507.
  • [93] Masiol M, Harrison RM. Aircraft engine exhaust emissions and other airport-related contributions to ambient air pollution: A review. Atmos Environ 2014; 95: 409–455.
  • [94] Sugara IR, Ilminnafik N, Junus S, Kustanto MN, Hermawan Y. Experimental study on the effect of magnetic fields on combustion characteristics of biodiesel from nyamplung (calophyllum ınophyllum). Automotive Experiences 2023; 6(1): 122-132.
  • [95] Mohamad Nor AF, Wan Mahmood WMF, Md Jedi MA. Magnetic field ability to treat hydrocarbon fuel in ınternal combustion engine. Jurnal Kejuruteraan 2023; 35(1): 105-115.
  • [96] Santos LO, Silva PGP, Costa SS, Machado TB. Magnetic field application to ıncrease yield of microalgal biomass in biofuel production. International Journal of Environmental Science and Development 2020.
  • [97] Andrianto DT, Kustanto MN, Hermawan Y, Ilminnafik N, Junus S. Characterization of premixed flames with ethanol fuel affected by magnetic field ınduction. International Journal of Emerging Trends in Engineering Research 2023; 11(2): 47–50.
  • [98] Nufus TH, Ulfiana A, Hidayati N, Nuriskasari I, Ridwan E, Kusumastuti SL, Permana S, Susanto I. Magnetization of bioethanol-gasoline fuel blends for development combustion energy and reducing exhaust gas emissions . Eastern-European Journal of Enterprise Technologies 2022; 3(6): 32–40.
  • [99] Nurkoyim M, Ilminnafik N, Junus S, Kustanto MN, Hermawan Y. Experimental study on the effect of magnetic fields on combustion characteristics of biodiesel from nyamplung (calophyllum ınophyllum). Automotive Experiences 2023; 6(1).
  • [100] Gonzalez DF. Magnetic field effects on diffusion flames. LSU Master's Theses 2008; 2936.
  • [101] Komuravelli N. Study of the effects of magnetic field on the properties of combustion synthesized iron oxide nanoparticles. Master's Thesis, LSU, 2005; 2812.
  • [102] Elias D. Influence of magnetic fields on the evaporation and combustion of a single droplet. Master's Thesis, LSU, 2014; 365.
Yıl 2024, Cilt: 9 Sayı: 1, 175 - 198, 22.03.2024
https://doi.org/10.58559/ijes.1412125

Öz

Kaynakça

  • [1] Sevim C. Küresel enerji jeopolitiği ve enerji güvenliği. Yaşar Üniversitesi E-Dergisi 2012; 7(26): 4378-4391.
  • [2] The World Bank (N.D.) World Bank Open Data: Population, Total 2022; Https://Data.Worldbank.Org/Indicator/SP.POP.TOTL
  • [3] International Energy Agency (N.D.) World Oil Supply And Demand, 1971-2020. IEA, Paris. 2021; Https://Www.Iea.Org/Data-And-Statistics/Charts/World-Oil-Supply-And-Demand-1971-2020
  • [4] İlbaş M, Yılmaz İ. Farklı ısıl güçlerdeki kazanlarda yanma ve emisyon davranışının araştırılması. Erciyes Üniversitesi Fen Bilimleri Enstitüsü Fen Bilimleri Dergisi 2002; 18(1): 18-27.
  • [5] Yılmaz İ, İlbaş M. Hidrojen-metan karışım yanmasında yanma model sabitinin değerlendirilmesi. Isı Bilimi ve Tekniği Dergisi 2010; 30(1): 45-57.
  • [6] Saksono N. Magnetizing kerosene for increasing combustion efficiency. Jurnal Teknologi 2005; Edisi No. 2, Tahun XIX, 155-162.
  • [7] Bian YC, Ding W, Hu L, Et Al. Magneto-revealing and acceleration of hidden kirkendall effect in galvanic replacement reaction. Phys. Chem. Lett 2021; 12(22): 5294–5300.
  • [8] Alnaimat, Dagher S, Mathew B, Et Al. Microfluidics based magnetophoresis: A review. The Chemical Record 2018; 18(11): 1596-1612.
  • [9] Li JQ, Ma TB, Ning JG. Mechanism of explosion-induced disturbance in natural magnetic field. Chinese Journal Of Theoretical And Applied Mechanics 2018; 50(05): 1206-1218.
  • [10] Gilart RA, Ungaro MRB, Rodríguez CEA, Et Al. Performance and exhaust gases of a diesel engine using different magnetic treatments of the fuel. Journal of Mechanical Engineering and Sciences 2020; 14(1): 6285- 6294.
  • [11] Chen CY, Lee WJ, Mwangi JK, Et Al. Impact of magnetic tube on pollutant emissions from the diesel engine. Aerosol and Air Quality Research 2017; 17(4): 1097-1104.
  • [12] Al-Rawaf MA. Magnetic field effects on spark ignition engine performance and its emissions at high engine speeds. Journal of Engineering and Development 2015; 19(4): 37-48.
  • [13] Kumar V, Rastogi V, Agarwal S, Et Al. Investigation of temperature profile and temperature stability of micro diffusion flame under the influence of magnetic field by use of a holo-shear lens-based interferometer. Optical Engineering 2020; 59(6): 064107.
  • [14] Ueno S, Harada K. Experimental difficulties in observing the effects of magnetic fields on biological and chemical processes. IEEE Transactions on Magnetics 1986; 22(5): 868-873.
  • [15] Ueno S, Harada K. Effect of magnetic fields on flames and gas flow. IEEE Transactions on Magnetics 1985;21(5).
  • [16] Ueno S, Harada K. Combustion process under strong DC magnetic fields. IEEE Transactions On Magnetics 1987; 23(5): 2752-2754.
  • [17] Ueno S, Esaki H, Harada R. Magnetic field effect on combustion. IEEE Translation Journal on Magnetics in Japantjmj1987; 2(9).
  • [18] Guo H, Chen Y, Yao R. A study of magnetic effects on the physicochemical properties of individual hydrocarbons. IEEE Transactions on Magnetics 1986.
  • [19] Wakayama N. Behavior of gas flow under gradient magnetic fields. Journal of Applied Physics 1991; 69: 2734–2736.
  • [20] Wakayama N. Effect of a gradient magnetic field on the combustion of methane in air. Chemical Physics Letters 1992; 188: 279-281.
  • [21] Wakayama N. Magnetic promotion of combustion in diffusion flames. Combustion and Flame 1993; 93: 207-214.
  • [22] Wakayama N, Ito H, Kuroda Y, Fujıta O, Ito K. Magnetic support of combustion in diffusion flames under microgravity. Combustion and Flame 1996; 107: 187-192.
  • [23] Fujita O, Ito K, Chida T, Nagai S, Takeshita Y. Determination of magnetic field effects on a jet diffusion flame in a microgravity environment. Twenty-Seventh Symposium (International) on Combustion/The Combustion Institute 1998; 2573–2578.
  • [24] Morozov YG, Kuznetsov MV. Effect of magnetic fields on combustion electromotive force. Combustion, Explosion and Shock Waves 1999; 35(1): 18-22.
  • [25] Baker J, Varagani R. Models and experiments on laminar diffusion flames in non-uniform magnetic fields. Seventh International Workshop on Microgravity Combustion and Chemically Reacting Systems 2003; 317-320.
  • [26] Iwata N, Tsubuki S, Takaki Y, Watanabe K, Sekiguchi, M, Hosoki E, Saido TC. Identification of the major aβ 1– 42-degrading catabolic pathway in brain parenchyma: suppression leads to biochemical and pathological deposition. Nature Medicine 2000; 6(2): 143-150.
  • [27] Tung H, Cédric D, Anne V, Agnès J, Gilles L. A global tool for environmental assessment of roads– application to transport for road building. In European Conference of Transport Research Institutes The Hague 2010.
  • [28] Loskutova O, Walker TR, Crittenden PD, Dauvalter VA, Jones V, Kuhry P, Pystina T. Multiple indicators of human impacts on the environmentin the pechora basin. North-Eastern European Russia. Ecological Indicators 2009; 9(4): 765-779.
  • [29] Tao R. Investigate effects of magnetic fields on fuels. Department of Physics, Temple University, Philadelphia 2004.
  • [30] Tao R, Xu X. Reducing the viscosity of crude oil by pulsed electric or magnetic field. Energy & Fuels 2006; 20: 2046-2051.
  • [31] Saksono N. Magnetising kerosene for increasing combustion efficiency. Jurnal Teknologi 2005; 2: 155-162.
  • [32] Chang KT, Weng CI. The effect of an external magnetic field on the structure of liquid water using molecular dynamics simulation. Journal of Applied Physics 2006; 100: 043917.
  • [33] Gilard V, Gillon P, Blanchard JN, Sarh B. Influence of a horizontal magnetic field on a co-flow methane/air diffusion flame. Combustion Science and Technology 2018; 180(10-11): 1920-1935.
  • [34] Evdokimov IN, Kornishin KA. Apparent disaggregation of colloids in a magnetically treated crude oil. Energy & Fuels 2009; 23(8): 4016-4020.
  • [35] Legros G, Gomez T, Fessard M, Guibert P, Torero J. Magnetically induced flame flickering. Proceedings of the Combustion Institute 2010; 33: 1095-1103.
  • [36] Jalali M, Ahmadi M, Yadaei F, Azimi M, Hoseini H. Enhancement of benzine combustion behaviour in exposure to the magnetic field. Journal of Clean Energy Technologies 2013; 1: 224-227.
  • [37] Ugare V, Dhoble A, Lutade S, Mudafale K. Performance of internal combustion (CI) engine under the influence of strong permanent magnetic field. Journal of Mechanical and Civil Engineering 2014; 3: 11-17.
  • [38] Kumar M, Agarwal S, Kumar V, Khan G, Shakher C. Experimental investigation on butane diffusion flame under the influence of magnetic field by using digital speckle pattern interferometry. Applied Optics 2015; 54(9): 2450-2460.
  • [39] Agarwal AK, Gupta T, Shukla PC, Dhar A. Particulate emissions from biodiesel fuelled CI engines. Energy Conversion and Management 2015; 94: 311-330.
  • [40] Elamin AA, Ezeldin M, Masaad AM, Suleman NM. Effect of magnetic field on some physical characteristics and cetane number of diesel fuel. American Journal of Applied Chemistry 2015; 3(6): 212-216.
  • [41] Singh A. Measurement of fuel flow behaviour of propane diffusion flame by dimensionless numbers under magnetic field application. International Journal of Combined Research and Development 2015; 4: 585-586.
  • [42] Wu W, Qu J, Zhang K, Chen W. Experimental studies of magnetic effect on methane laminar combustion characteristics. Combustion Science and Technology 2016.
  • [43] Barmina I, Zake M. Effects of magnetic field on swirling flame dynamics. Engineering for rural development, Jelgava 2016.
  • [44] Barmina I, Zake M. Magnetic field control of combustion dynamics. Latvian Journal of Physics and Technical Sciences 2017; 53(4): 36-46.
  • [45] Barmina I, Zake M, Strautins U, Marinaki U. Effects of gradient magnetic field on swirling flame dynamics. Engineering For Rural Development Jelgava 2017; 24.
  • [46] Morsi K. Combustion synthesis and the electric field: A review. International Journal of Self-Propagating High-Temperature Synthesis 2017; 26(3): 199–209.
  • [47] Boben RR, RamnathV, Lyons KM. Effect of moderate-strength magnetic field on local temperature in diffusion flames. Aeronautics and Aerospace Open Access Journal 2018; 2(4): 250–257.
  • [48] Agarwal S, Shakher C. Effect of magnetic field on temperature profile and flame flow characteristics of micro flame using talbot interferometer. Optic - International Journal for Light and Electron Optics 2018; 168: 817–826.
  • [49] Di Renzo M, Urzay J, De Palma P, De Tullio MD, Pascazio G. The effects of incident electric fields on counterflow diffusion flames. Combustion and Flame 2018; 193: 177–191.
  • [50] Ramnath V, Lyons KM. The potential of simple, low-cost permanent magnets for flame manipulation in flow fields. Aeronautics and Aerospace Open Access Journal 2018; 2(1).
  • [51] Marouf HH, Elsemary IM, Abdel Rahim AA, Abd Rabo MF. Effect of electromagnetic field on combustion of candle flame. Engineering Research Journal 2019; 1(39): 18–22.
  • [52] Perdana D, Adiwidodo S, Choifin M, Winarko WA. The effect of magnetic field variations in a mixture of coconut oil and jatropha on flame stability and characteristics on the premixed combustion. EUREKA: Physics and Engineering 2021; (5): 13–22.
  • [53] Perdana D. The experimental of impact of additional magnetic fields and nitrogen pressure on olive oil droplet combustion. Indonesian Journal of Applied Research (IJAR) 2023; 4(1): 1–10.
  • [54] Perdana D, Adiwidodo S, Winarko WA. The role of perforated plate and orientation of the magnetic fields on coconut oil premixed combustion. Energy 2022; 67(2): 77–84.
  • [55] Perdana D, Yuliati L, Hamidi N, Wardana ING. The role of magnetic field orientation in vegetable oil premixed combustion. Journal of Combustion 2020; 2020: 11.
  • [56] Perdana D, Setiyawan DG, Choifin M. Experimental study on flame characteristics of premixed combustion of kapok oil with various magnetic field. Orientations 2020; 8(1). Sjme Kinematika Juni 2023.
  • [57] Zharfa M, Karimi N. Intensification of MILD combustion of methane and hydrogen blend by the application of a magnetic field- a numerical study. Acta Astronautica 2021; 184: 259–268.
  • [58] Zhang Z, Wei Z. Experiment and simulation of the effects of non-uniform magnetic field on the regression rate of PMMA. Combustion and Flame 2021; 223: 337–348.
  • [59] Xie Y, Wei Z, Zhou, T, Zhen H, Liu Z, Huang Z. Combustion characteristics of small laminar flames in an upward decreasing magnetic field. Energies 2021; 14: 1969.
  • [60] Gao JC, Yang XG, Hu ST, Hong ZJ, Et Al. Effect of external magnetic field on acetylene explosion reaction. Explos. Shock Waves 2022; 42(07): 150-160.
  • [61] Zhou S, Gao J, Luo Z, Hu S, Wang L, Wang T. Role of ferromagnetic metal velvet and DC magnetic field on the explosion of a C3H8/air mixture-effect on reaction mechanism. Energy 2021; 239(21): 122218.
  • [62] Govindasamy P, Dhandapani S. Performance and emissions achievements by magnetic energizer with a single cylinder two-stroke catalytic coated spark ignition engine 2007.
  • [63] Govindasamy P, Dhandapani S. Experimental investigation on the effect of magnetic flux to reduce emissions and improve combustion performance in a two-stroke, catalytic-coated, spark-ignition engine. International Journal of Automotive Technology 2007; 8(5): 533-542.
  • [64] Govindasamy P, Dhandapani S. Reduction of NOX emission in bio diesel engine with exhaust gas recirculation and magnetic fuel conditioning. In GMSARN International Conference on Sustainable Development: Challenges and Opportunities for GMS 2007; 14.
  • [65] Fatih F, Saber G. Effect of fuel magnetism on engine performance and emissions. Australian Journal of Basic and Applied Sciences 2010; 4: 6354-6358.
  • [66] Faris AS, Al-Naseri SK, Jamal N, Isse R, Abed M, Fouad Z, Jasim H. Effects of magnetic field on fuel consumption and exhaust emissions in two-stroke engine. Energy Procedia 2012; 18: 327-338.
  • [67] Habbo ARA, A Khalil R, S Hammoodi H. Effect of magnetizing the fuel on the performance of an si engine. AL-Rafdain Engineering Journal (AREJ) 2011; 19(6): 84-90.
  • [68] Jain S, Deshmukh S. Experimental investigation of magnetic fuel conditioner in ic engine. IOSR Journal of Engineering, 2012; 2: 27-31.
  • [69] Siregar H, Nainggolan R. Electromagnetic fuel saver for enhancing the performance of the diesel engine. Global Journal of Researches in Engineering, Mechanical and Mechanics Engineering 2012; 12.
  • [70] Attar AR, Tipole P, Bhojwani V, Deshmukh S. Effect of magnetic field strength on hydrocarbon fuel viscosity and engine performance. International Journal of Mechanical Engineering and Computer Applications 2013; 1(7): 94-98.
  • [71] Garg R, Agarwal A. Fuel energizer: the magnetizer (a concept of liquid engineering). International Journal of Innovative Research & Development 2013; 2: 617-627.
  • [72] Vijayakumar P, Patro S, Pudi V. Experimental study of a novel magnetic fuel ionization method in four stroke diesel engines. International Journal of Mechanical Engineering and Robotics Research 2014; 3: 151-159.
  • [73] Abd-Allah GH. Using exhaust gas recirculation in internal combustion engines: A review. Energy Conversion and Management 2001; 43: 1027–1042.
  • [74] Patel PM, Rathod GP, Patel TM. Effect of magnetic field on performance and emission of single cylinder four stroke diesel engine. IOSR Journal of Engineering 2014; 4(5): 28-34.
  • [75] Sala A, Notti E. Preliminary tests of new magnetic device for fuel saving and emission reduction in fisheries. Third International Symposium on Fishing Vessel Energy Efficiency 2014; 1-5.
  • [76] Khedvan A, Gaikwad V. Review on effect of magnetic field on hydrocarbon refrigerant in vapour compression cycle. International Journal of Scientific Engineering and Technology Research 2015; 4: 1374-1378.
  • [77] Kacem SA, Ferdaouss L, Abrerrahim L, Mohammed B. Evaluation de l'impact de la pollution agricole sur la qualite des eaux souterraines de la nappe du gharb. European Scientific Journal 2016; 12(11).
  • [78] Gabiña G, Basurko OC, Notti E, Sala A, Aldekoa S, Clemente M, Uriondo Z. Energy efficiency in fishing: are magnetic devices useful for use in fishing vessels. Applied Thermal Engineering 2016; 94: 670-678.
  • [79] Gad MS. Assessment of biodiesel derived from waste cooking oil as an alternative fuel for diesel engines. International J. of Chem. Tech. Research 2016; 9(3): 140-146.
  • [80] Chen C, Lee W, Mwangi J, Wang L, Lu J. Impact of magnetic tube on pollutant emissions from the diesel engine. Aerosol and Air Quality Research 2017; 17: 1097-1104.
  • [81] Attar AR, Tipole P, Bhojwani V, Deshmukh S. Effect of magnetic field strength on hydrocarbon fuel viscosity and engine performance. International Journal of Mechanical Engineering and Computer Applications 2013; 1(7): 94-98.
  • [82] Kurji HJ, Imran MS. Magnetic field effect on compression ignition engine performance. ARPN Journal of Engineering and Applied Sciences 2018; 13(12): 3943-3949.
  • [83] Sahoo RR, Jain A. Experimental analysis of nanofuel additives with magnetic fuel conditioning for diesel engine performance and emissions. Fuel 2019; 236: 365-372.
  • [84] Niaki SOD, Khatamnejad H, Khalilarya S, Jafarmadar S, Mirsalim M, Gharehghani A. Experimental investigation on the effect of natural gas premixed ratio on combustion and emissions in an idi engine. Journal of Thermal Analysis and Calorimetry 2019; 138(6): 3977-3986.
  • [85] Oommen LP, Narayanappa KG. Assimilative capacity approach for air pollution control in automotive engines through magnetic field-assisted combustion of hydrocarbons. Environ Sci Pollut Res 2021; 28: 63661– 63671.
  • [86] Oommen LP, Narayanappa KG, Vijayalakshmi SK. Experimental analysis of synergetic effect of part-cooled exhaust gas recirculation on magnetic field-assisted combustion of liquefied petroleum gas. Arab J Sci Eng 2020; 45: 9187–9196.
  • [87] Oommen LP, Kumar GN. Influence of magneto-combustion on regulated emissions of an automotive engine under variable speed operation. Int. J. Vehicle Structures & Systems 2020; 12(1): 109-112.
  • [88] Oommen LP, Kumar GN. Analysis of cyclic variations and combustion behavior of liquid phase hydrocarbons under uniform axial and radial magnetic fields. In: Edwin Geo, V., Aloui, F. (eds) Energy and Exergy for Sustainable and Clean Environment 2023; 2. Green Energy and Technology. Springer, Singapore.
  • [89] Oommen LP, Kumar GN. Experimental analysis of conjoint effect of semi-cooled exhaust recirculation on combustion of liquid phase hydrocarbons under uniform magnetic fields. Arab J Sci Eng 2022; 47: 16049–16057.
  • [90] Pawar NR, Hudgikar SRK. Performance enhancement of multi-cylinder four stroke SI engine under the effect of magnetic field. In; (eds) Techno-Societal Springer Cham 2021;
  • [91] Brunekreef B, Holgate ST. Air pollution and health. Lancet 2002; 360(9341): 1233-1242.
  • [92] Mazaheri M, Johnson GR, Morawska L. An inventory of particle and gaseous emissions from large aircraft thrust engine operations at an airport. Atmos Environ 2011; 45(20): 3500–3507.
  • [93] Masiol M, Harrison RM. Aircraft engine exhaust emissions and other airport-related contributions to ambient air pollution: A review. Atmos Environ 2014; 95: 409–455.
  • [94] Sugara IR, Ilminnafik N, Junus S, Kustanto MN, Hermawan Y. Experimental study on the effect of magnetic fields on combustion characteristics of biodiesel from nyamplung (calophyllum ınophyllum). Automotive Experiences 2023; 6(1): 122-132.
  • [95] Mohamad Nor AF, Wan Mahmood WMF, Md Jedi MA. Magnetic field ability to treat hydrocarbon fuel in ınternal combustion engine. Jurnal Kejuruteraan 2023; 35(1): 105-115.
  • [96] Santos LO, Silva PGP, Costa SS, Machado TB. Magnetic field application to ıncrease yield of microalgal biomass in biofuel production. International Journal of Environmental Science and Development 2020.
  • [97] Andrianto DT, Kustanto MN, Hermawan Y, Ilminnafik N, Junus S. Characterization of premixed flames with ethanol fuel affected by magnetic field ınduction. International Journal of Emerging Trends in Engineering Research 2023; 11(2): 47–50.
  • [98] Nufus TH, Ulfiana A, Hidayati N, Nuriskasari I, Ridwan E, Kusumastuti SL, Permana S, Susanto I. Magnetization of bioethanol-gasoline fuel blends for development combustion energy and reducing exhaust gas emissions . Eastern-European Journal of Enterprise Technologies 2022; 3(6): 32–40.
  • [99] Nurkoyim M, Ilminnafik N, Junus S, Kustanto MN, Hermawan Y. Experimental study on the effect of magnetic fields on combustion characteristics of biodiesel from nyamplung (calophyllum ınophyllum). Automotive Experiences 2023; 6(1).
  • [100] Gonzalez DF. Magnetic field effects on diffusion flames. LSU Master's Theses 2008; 2936.
  • [101] Komuravelli N. Study of the effects of magnetic field on the properties of combustion synthesized iron oxide nanoparticles. Master's Thesis, LSU, 2005; 2812.
  • [102] Elias D. Influence of magnetic fields on the evaporation and combustion of a single droplet. Master's Thesis, LSU, 2014; 365.
Toplam 102 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Enerji ve Yakmada Kimyasal ve Termal Süreçler, İçten Yanmalı Motorlar
Bölüm Review Article
Yazarlar

Ozan Öztürk 0000-0002-4959-6808

Murat Taştan 0000-0001-9988-2397

Yayımlanma Tarihi 22 Mart 2024
Gönderilme Tarihi 30 Aralık 2023
Kabul Tarihi 5 Şubat 2024
Yayımlandığı Sayı Yıl 2024 Cilt: 9 Sayı: 1

Kaynak Göster

APA Öztürk, O., & Taştan, M. (2024). A review of magnetic field assisted combustion. International Journal of Energy Studies, 9(1), 175-198. https://doi.org/10.58559/ijes.1412125
AMA Öztürk O, Taştan M. A review of magnetic field assisted combustion. Int J Energy Studies. Mart 2024;9(1):175-198. doi:10.58559/ijes.1412125
Chicago Öztürk, Ozan, ve Murat Taştan. “A Review of Magnetic Field Assisted Combustion”. International Journal of Energy Studies 9, sy. 1 (Mart 2024): 175-98. https://doi.org/10.58559/ijes.1412125.
EndNote Öztürk O, Taştan M (01 Mart 2024) A review of magnetic field assisted combustion. International Journal of Energy Studies 9 1 175–198.
IEEE O. Öztürk ve M. Taştan, “A review of magnetic field assisted combustion”, Int J Energy Studies, c. 9, sy. 1, ss. 175–198, 2024, doi: 10.58559/ijes.1412125.
ISNAD Öztürk, Ozan - Taştan, Murat. “A Review of Magnetic Field Assisted Combustion”. International Journal of Energy Studies 9/1 (Mart 2024), 175-198. https://doi.org/10.58559/ijes.1412125.
JAMA Öztürk O, Taştan M. A review of magnetic field assisted combustion. Int J Energy Studies. 2024;9:175–198.
MLA Öztürk, Ozan ve Murat Taştan. “A Review of Magnetic Field Assisted Combustion”. International Journal of Energy Studies, c. 9, sy. 1, 2024, ss. 175-98, doi:10.58559/ijes.1412125.
Vancouver Öztürk O, Taştan M. A review of magnetic field assisted combustion. Int J Energy Studies. 2024;9(1):175-98.