Studying some Pollutant Emissions of an Injection Gasoline Engine Using Mixed Fuel of Ethanol, Gasoline and Carbon Nanoparticles

Malek Mohammadi, M.; Rahnama, M.; Abdanan Mehdizadeh, S.; Kazemi, N.

doi:10.22067/jam.v11i2.76903

Document Type : Research Article

Authors

Agricultural Sciences and Natural Resources University of Khuzestan, Mollasani, Iran

https://doi.org/10.22067/jam.v11i2.76903

Abstract

Introduction
Due to the rapid growth in the urban population, the numbers of cars also have increased which resulted in an increase of pollution level in the urban areas of the developing countries. The pollutants emerging from combustion engines may include: carbon monoxide (CO), unburned hydrocarbons (UBHC), oxide of nitrogen (NOx), oxides of sulfur (SOx), particulate matter (PM), soot, hydrogen, oxygen, traces of aldehydes, alcohols, ketons, phenols, acid, lead aerosol, etc., along with normal combustion products i.e. carbon dioxide (CO₂) and water vapors. In order to overcome the problems associated with the bio-fuel, the chemical substances like fuel additives derived from organic, inorganic metals were used. Fuel additives generally improve the combustion efficiency and reduce the pollution. Metallic based compounds, such as manganese, iron, copper, barium, calcium and platinum, etc., which have been used as a combustion catalyst for hydrocarbon fuels. Recent advances in nanoscience and nanotechnology enables production, control and characterization of nanoscale energetic materials. Nano materials are more effective than bulk materials because of its higher surface area. Another important advantage of nanoparticle is its size, because there is no chance for fuel injector and filter clogging as in the case of micron sized particles. Gan and Qiao, (2011) investigated the burning characteristics of fuel droplets containing nano and micron sized aluminum (Al) particles by varying its size, surfactant concentration and type of base fluid. Tyagi et al. (2008) conducted a study to improve the ignition properties of diesel fuel and investigated the influence of size and quantity of Al and Al₂O₃ nanoparticles in a diesel fuel. It was inferred that it shortens the ignition delay and increased the ignition probability of fuel. Finally, it was concluded that, the increase in heat and mass transfer properties of the fuel has the potential of reducing the evaporation time of droplets. In the present investigation, the effect of mixture of ethanol with gasoline and carbon nanotubes on emission characteristics was evaluated using Jatropha biodiesel in a compression in a spark ignition engine.

Materials and Methods
In this study, a mixture of ethanol with gasoline (at five levels, 0, 10, 20, 30 and 40%) as a renewable fuel and carbon nanoparticles (at three levels of 0, 20 and 80 ppm) as catalyst were used in spark ignition engine (in 1000, 2000 and 3000 rpm). Engine pollutants such as sound, carbon monoxide, unburnt hydrocarbons, carbon dioxide and oxygen output were measured. Furthermore, a device was designed and manufactured to measure and display the amount of carbon monoxide in the exhaust outlet; moreover, if the amount of carbon increased air compressor was activated to reduce carbon monoxide in the exhaust outlet.

Results and Discussion
The results showed that with increasing ethanol consumption, the amount of carbon monoxide and unburned hydrocarbons were reduced. Furthermore, the amount of produced oxygen and carbon dioxide increased. Also adding carbon nanoparticles to fuel caused the engine sound level decreased. According to the observation, carbon monoxide decreased while using an electronic device compare to the engine without a carbon monoxide controlling system. This depicts that implementation of carbon monoxide can be control and reduce which is very useful while engine is working under the close environments.

Conclusion
The use of alternative fuel, gasoline as well as the reduction of exhaust emissions in the spark ignition engine is of great importance. Therefore, in the present study five levels of ethanol (0, 10, 20, 30 and 40%) and three levels of carbon nanoparticles (0, 20 and 80 ppm) were mixed with gasoline and used in spark ignition engine at three rotation speed (in 1000, 2000 and 3000 rpm). According to the results, there is a reduction in carbon monoxide and unburned hydrocarbons and increasing carbon dioxide emission by using ethanol, because of its fuel bound O₂. Furthermore, 3.8% dB 54% reduction in sound and CO, respectively at 3000 rpm with E10 were observed.

Keywords

20.1001.1.22286829.1400.11.2.7.2

Open Access

©2021 The author(s). This article is licensed under Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source.

References

1. Abdel-Rahman, A. A., and M. M. Osman. 1997. Experimental Investigation on Varying the Compression Ratio of Si Engine Working Under Different Ethanol-Gasoline Fuel Blends. International Journal of Energy Research 21: 31-40.

2. Al-Hasan, M. 2003. Effect of ethanol–unleaded gasoline blends on engine performance and exhaust emission. Energy Conversion and Management 44 (9): 1547-1561.

3. Anonymous. 2012. Injection vehicles-Advanced Diagnosis methods with the DIAG-Scanners. Mahad Sanat Publication, Print tenth, 135 PP.

4. Bashar, A. M. 2016. Study the performance and emissions of a spark ignition engine works with ethanol and petrol mixture. International Journal of Computation and Applied Sciences IJOCAAS 1 (2): 7-12.

5. Broatch, A., X. Margot, R. Novella, and J. Gomez. 2016. Combustion noise analysis of partially premixed combustion concept using gasoline fuel in a 2-stroke engine. Energy 107: 612-624.

6. Clifford, J., J. Mulrooney, G. Dooly, C. Fitzpatrick, E. Lewis, E. Merlone, and G. Flavia. 2008. On Board Measurement of Carbon Dioxide Exhaust Car Emissions Using A Mid-Infrared Optical Based Fibre, IEEE SENSORS, Conference, 914-918.

7. Dong, W., R. Hong, and T. Hui Lin. 2001. Engine performance and pollutant emission of an SI engine using ethanol–gasoline blended fuels. Atmospheric Environment 36 (3): 403-410.

8. Egúsquiza, J. C., S. L. Braga, and C. V. M. Braga. 2009. Performance and Gaseous Emissions Characteristics of a Natural Gas/Diesel Dual Fuel Turbocharged and Aftercooled Engine. Journal of the Brazilian Society of Mechanical Sciences and Engineering. XXXI (2): 140-150.

9. Elfasakhany, A. 2015. Investigations on the effects of ethanol methanole gasoline blends in a spark-ignition engine: Performance and emissions analysis. Engineering Science and Technology, an International Journal 18: 713-719.

10. Ettefaghi, E., S. S. Mohtasebi, H. Ahmadi, R. Soltani, and A. M. Rashidi. 2012. Effects of Nano-Particles on Properties of Engine Oil and its Functionality Rate on Wear Reduction. The Journal of Engine Research 24 (24): 3-12.

11. Gauch, H. G. 1992. Statistical Analysis of Regional Yield Trials. 1th edition, Elsevier Science. 278 PP.

12. Gershashbi, S. 2012. Introduction and Troubleshooting Injection, Multifunction and Electronics Systems of Peugeot 206, Iran. Kowsar Publications. 49 PP.

13. Ghari, M., B. Ghamari, and N. Bagheri. 2015. Determination of the optimal amount of nitrous oxide injected into the engine in order to reduce emissions. Journal of Agricultural Machinery 5 (2): 381-392. (In Farsi).

14. Han, S. B. A. 2014. Study on the performance and emissions characteristics of spark ignition engine fuelled with ethanol gasoline blended fuel, Journal of Energy Engineering 23 (2):170-174.

15. Kampa, M., and E. Castanas. 2008. Human health effects of air pollution. Environmental Pollution 151: 362-367.

16. Karthikeyan, S., A. Elango, and A. Prathima. 2014. An environmental effect of GSO methyl ester ZnO additive fuelled marine engine. Indian Journal of Geo-Marine Sciences 43 (4): 564-570.

17. Keskin, A. 2010. The Influence of Ethanol-Gasoline Blends on Spark Ignition Engine Vibration Characteristics and Noise Emissions. Energy Sources, Part A, 32: 1851-1860.

18. Kulkarni, A., and T. Ravi Teja. 2014. Automated System for Air Pollution Detection and Control in Vehicles, International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering 3 (9): 12196-12200.

19. Lapuerta, A., M. Jose, A. Herreros, L. Lisbeth, A. Lyons, A. Contreras, and Y. Briceño. 2008. Effect of the alcohol type used in the production of waste cooking oil biodiesel on diesel performance and emissions. Fuel 87 (15): 3161-3169.

20. Lines, M. G. 2008. Nanomaterials for practical functional uses. Journal of Alloys and Compounds 449: 242-245.

21. Mansha, M., E. M. Shahid, and A. H. Qureshi. 2012. Control of Combustion Generated Emissions from Spark Ignition Engines: A Review, Pakistan Journal of Enginering and Applied Sciences 11: 114-128.

22. Mirzadeh, M. 2017. Using bioethanol as energy resource and decreasing the pollution of environment, Journal of Biosafety 2 (10): 53-70. (In Farsi).

23. Ogur, E., and S. Kariuki. 2014. Effect of Car Emissions on HumanHealthndthe Environment .International Journal of Applied Engineering Research 9: 11121-11128.

24. Ommi, F., K. Farhang, and A. Shafiei. 2009. Experimental Investigation of the Combustion of a Spark Ignition Engine, With Gasoline-Ethanol-MTBE Blends as Fuel, to Reduce Fuel Consumption and Pollutants. The Journal of Engine Research 16: 22-28.

25. Pang, X.; Y. Mu, J. Yuan, and H. He. 2008. Carbonyls emission from ethanol-blended gasoline and biodiesel-ethanol-diesel used in engines. Atmos. Environ 42: 1349-1358.

26. Pritchard, J., and C. K. Wai. 2015. The Effects of Secondary Air on the Exhaust Oxidation of Particulate Matters. SAE International Journal of Engines 8 (3):1-10.

27. Rizwanul Fattah, I. M., H. H. Masjuki, A. M. Liaquat, A. M. Ahizar Ramli Kalam, and V. N. Riazuddin. 2013. Impact of various biodiesel fuels obtained from edible and non-edible oils on engine exhaust gas and noise emissions. Renewable and Sustainable Energy Reviews 18: 552-567.

28. Sajith, V., C. B. Sobhan, and G. P. Peterson. 2010. Experimental Investigations on the Effects of Cerium Oxide Nanoparticle Fuel Additives on Biodiesel. Hindawi Publishing Corporation Advances in Mechanical Engineering, Article ID 581407: 1-6.

29. Sarkar, A., A. Chowdhuri, K. Jyoti Bhowal, and B. K. Mandal. 2012. The Performance and Emission Characteristics of SI Engine Running on Different Ethanol-Gasoline Blends. International Journal of Scientific & Engineering Research 3 (6): 2229-5518.

30. Sasongko, M. N., W. Wijayanti, and F. N. Damus. 2017. Exhaust emissions of 4 stroke spark ignition engine with indirect injection system using gasoline-ethanol fuel, Journal of Environmental Engineering & Sustainable Technology 4 (1): 44-49.

31. Sathesh, M., and V. N. Loganathan. 2017. Design of Secondary Air injection System in Lower CC Engines- A Review, International Research Journal of Engineering and Technology 4 (9): 1329-1333.

32. Smagowska, B. 2013. Effects of Ultrasonic Noise on the Human Body-A Bibliographic Review. International Journal of Occupational Safety and Ergonomics (JOSE) 19 (2): 195-202.

33. Sonthalia, A., C. Rameshkumar, U. Sharma, A. Punganur, and S. Abbas. 2015. Combustion and Performance Characteristics of a Small Spark Ignition Engine Fuelled With HCNG, Journal of Engineering Science and Technology 10 (4): 404-419.

34. Taghizadeh Alisaraei, A., and A. Rezaei Asl. 2016. The effect of added ethanol to diesel fuel on performance vibration combustion and knocking of a CI engine. Fuel 185: 718-733.

35. Tewari, P., E. Doijode, N. R. Banapurmath, and C. Yaliwal. 2013. Experimental investigations on a diesel engine fuelled with multiwalled carbon nanoparticles blended biodiesel fuels. International Journal of Emerging Technology and Advanced Engineering 3 (3): 72-76.

36. Thakur, A. K., A. K. Kavitib, R. Mehrac, and K. K. S. Merd. 2017. Progress in performance analysis of ethanol-gasoline blends on SI engine. Renewable and Sustainable Energy Reviews 69: 324-340.

Name *

Email Address *

Affiliation *

Comments *

Security Code *

Journal of Agricultural Machinery

Studying some Pollutant Emissions of an Injection Gasoline Engine Using Mixed Fuel of Ethanol, Gasoline and Carbon Nanoparticles

References

References

Send comment about this article

Volume 11, Issue 2 - Serial Number 22
Fall and Winter
2021
Pages 213-230

Studying some Pollutant Emissions of an Injection Gasoline Engine Using Mixed Fuel of Ethanol, Gasoline and Carbon Nanoparticles

References

References

Send comment about this article

Volume 11, Issue 2 - Serial Number 22Fall and Winter 2021Pages 213-230

Volume 11, Issue 2 - Serial Number 22
Fall and Winter
2021
Pages 213-230