Analitik Hiyerarşi Proses Kullanarak Farklı Biyodizellerin Alternatif Yakıt Olarak Değerlendirilmesi
Artan nüfusla birlikte gelişen sanayileşme, dünyadaki fosil yakıtlara olan talebin artmasına neden olarak arz talep dengesini etkilemektedir. Bu dengesizlik fiyatlarda da artışa neden olmaktadır. Bu nedenle, artan petrol fiyatları ve petrol bağımlılığı, ülkeleri yeni enerji kaynaklarının üretimine ve kullanımına yönlendirmektedir. Bu noktada, ülkeler, biyoyakıt üretimi için biyokütleyi enerji üretecek şekilde değerlendirmekte ve böylece biyoyakıtların toplam enerji tüketimindeki payını arttırmaktadır. Bu çalışmada Analitik Hiyerarşi Süreci (AHP) karar problemini yapılandırmak ve ağırlıkları kriterlere atfetmek için kullanılmıştır. Değerlendirilen fizikokimyasal yakıt özellikleri arasında en önemlisi ısıl değer olarak hesaplanmış ve aynı zamanda pamuk yağı metil esterinin değerlendirilen biyodizeller arasında yakıt özellikleri açısından en uygun biyodizel olduğu tespit edilmiştir.
Using Analytic Hierarchy Process for Evaluating Different Biodiesels as an Alternative Fuel
The industrialization that develops with the increasing population causes an increase in demand for fossil fuels in the world, which affects the supply-demand balance. This imbalance also causes a rise in prices. Therefore, increased oil prices and oil dependency lead the countries to the production and use of new energy resources. At this point, countries are evaluating biomass for biofuel production to generate energy, thus increasing the share of biofuels in total energy consumption. In this study, Analytic Hierarchy Process (AHP) is used to structure the decision problem and to attribute weights to criteria. Among the evaluated physicochemical fuel properties, the most important one is calculated as heating value and also the Cottonseed Fame is determined as the most suitable biodiesel in terms of fuel properties among the evaluated biodiesels.
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- 1. Mofijur M., Atabani A.E., Masjuki H.H.,
Kalam M.A., Masum B.M., 2013. A Study on
the Effects of Promising Edible and Non-edible Biodiesel Feedstocks on Engine Performance
and Emissions Production: A Comparative
Evaluation, Renewable and Sustainable Energy
Reviews 23, 391–404.
- 2. Xue J., Grift T.E., Hansen A.C., 2011. Effect
of Biodiesel on Engine Performances and
Emissions, Renewable and Sustainable Energy
Reviews, 15, 1098–1116.
- 3. Sakthivel G., Sivakumar R., Saravanan N.,
Ikua W.B., 2017. A Decision Support System
to Evaluate the Optimum Fuel Blend in an IC
Engine to Enhance the Energy Efficiency and
Energy Management. Energy, 140, 566-583.
- 4. Knothe G., Razon L.F., 2017. Biodiesel Fuels
Progress in Energy and Combustion Science,
58, 36–59.
- 5. Thapa S., Natarianto I., Prakashbhai R.B.,
2018. An Overview on Fuel Properties and
Prospects of Jatropha Biodiesel as Fuel for
Engines. Environmental Technology &
Innovation, 9, 210–219.
- 6. Freedman, B., Pryde, E., Mounts, T. 1984.
Variables Affecting the Yields of Fatty Esters
from Transesterified Vegetable Oils. Journal of
the American Oil Chemists Society, 61,
1638–1643.
- 7. Van Gerpen, J., 2005. Biodiesel Processing and
Production. Fuel Processing Technology, 86
1097–1107.
- 8. Al-Zuhair, S., 2007. Production of Biodiesel:
Possibilities and Challenges. Biofuels,
Bioproducts and Biorefining, 1, 57–66.
- 9. Bozbas, K., 2008. Biodiesel as an Alternative
Motor Fuel: Production and Policies in the
European Union. Renewable and Sustainable
Energy Reviews, 12, 542–552.
- 10. Knothe, G., Sharp, C.A., Ryan, T.W., 2006.
Exhaust Emissions of Biodiesel, Petrodiesel,
Neat Methyl Esters, and Alkanes in a New
Technology Engine. Energy & Fuels, 20,
403–408.
- 11. Tiwari A., Rajesh V.M., Yadav S., 2018.
Biodiesel Production in Micro-reactors: A
Review Energy for Sustainable Development
43, 143–161.
- 12. Meher, L., Vidyasagar, D., Naik, S., 2006.
Technical Aspects of Biodiesel Production by
Transesterification-A Review. Renewable and
Sustainable Energy Reviews, 10, 248–268.
- 13. Canakci M., Erdil A., Arcaklioğlu E., 2006.
Performance and Exhaust Emissions of a
Biodiesel Engine. Applied Energy, 83,
594–605.
- 14. Sharma, Y.C., Singh, B., Upadhyay, S.N.,
2008. Advancements in Development and
Characterization of Biodiesel: A Review. Fuel,
87, 2355–2373.
- 15. Van Gerpen, J., 2005. The Basics of Diesel
Engines and Diesel Fuels. In The Biodiesel
Handbook; Knothe, G., Van Gerpen, J., Krahl,
J., Eds; AOCS Press: Urbana, IL, 17–25.
- 16. Xue J., Grift T.E., Hansen, A.C., 2011. Effect
of Biodiesel on Engine Performances and
Emissions. Renewable and Sustainable Energy
Reviews, 15, 1098–1116.
- 17. Demirbaş, A., 2003. Biodiesel Fuels from
Vegetable Oils Via Catalytic and Non-catalytic
Supercritical Alcohol Transesterifications and
Other Methods: A Survey. Energy Conversion
and Management, 44, 2093–2109.
- 18. Sakthivela, R., Ramesh, K., Purnachandrana,
R., Shameera, P.M., 2018. A Review on the
Properties, Performance and Emission Aspects
of the Third Generation Biodiesels. Renewable
and Sustainable Energy Reviews, 82,
2970–2992.
- 19.www.tuik.gov.tr cited 11.9.2018.
- 20. Ishizaka, A., Labib, A., 2011 Review of the
Main Developments in the Analytic Hierarchy
Process. Expert Systems with Applications, 38,
14336–14345.
- 21. Sehatpoura, M., Kazemia, A., Sehatpourb, H.,
2017. Evaluation of Alternative Fuels for
Light-duty Vehicles in Iran using a
Multicriteria Approach. Renewable and
Sustainable Energy Reviews, 72, 295–310.
- 22. Grasman, S.E., Sundaresan, S., 2012.
Implementation Policy Considerations for
Achieving Year Round Operability of
Biodiesel Programs Biomass and Bioenergy,
39, 439-448.
- 23. Çolak, M., Kaya, İ., 2017. Prioritization of
Renewable Energy Alternatives by using an
Integrated Fuzzy MCDM Model: A Real Case
Application for Turkey, Renewable and
Sustainable Energy Reviews, 80, 840–853.
- 24. Tasri A., Susilawati A., 2014. Selection
Among Renewable Energy Alternatives Based on a Fuzzy Analytic Hierarchy Process in
Indonesia. Sustainable Energy Technologies
and Assessments, 7, 34–44.
- 25. Atabani, A.E., Silitonga, A.S., Badruddin, I.A.,
Mahlia, T.M.I., Masjuki, H.H., Mekhile, S.,
2012. A Comprehensive Review on Biodiesel
as an Alternative Energy Resource and its
Characteristics. Renewable and Sustainable
Energy Reviews, 16, 2070– 2093.
- 26. Rashid, U., Anwar, F., Knothe, G., 2009.
Evaluation of Biodiesel Obtained from
Cottonseed Oil. Fuel Process Technology; 90
(9), 1157–1163.
- 27. Yaşar, A., Keskin, A., Yıldızhan, Ş., 2016.
Evaluation of Performance and Emission
Characteristics of a VCR Diesel Engine
Fuelled with Diesel Fuel and Diesel-Biodiesel-
Alcohol Blends. Çukurova University Journal
of the Faculty of Engineering and Architecture
31(1), 263-271.
- 28. Ramos, M.J., Fernández, C.M., Casas, A.,
Lourdes, R., Pérez, Á., 2009. Influence of Fatty
Acid Composition of Raw Materials on
Biodiesel Properties, Bioresource Technology
100, 261–268.
- 29. Ashraful, A.M., Masjuki, H.H., Kalam, M.A.,
Rizwanul Fattah, I.M., Imtenan, S., Shahir,
S.A., Mobarak H.M., 2014. Production and
Comparison of Fuel Properties, Engine
Performance and Emission Characteristics of
Biodiesel from Various Non-edible Vegetable
Oils: A Review Energy Conversion and
Management 80, 202–228.
- 30. Raheman, H., Ghadge, S.V., 2007.
Performance of Compression Ignition Engine
with Mahua (Madhuca Indica) Biodiesel Fuel
86, 2568–2573.
- 31. Kaya, C., Hamamci, C., Baysal, A., Akba, O.,
Erdogan, S., Saydut, A., 2009. Methyl Ester of
Peanut (Arachis hypogea L.) Seed Oil as a
Potential Feedstock for Biodiesel Production
Renewable Energy 34, 1257–1260.
- 32. Thapa, S., Indrawan, N., Bhoi Pr. R., 2018. An
Overview on Fuel Properties and Prospects of
Jatropha Biodiesel as Fuel for Engines
Environmental Technology & Innovation 9,
210–219.
- 33. Alonso, J.A., Lamata, M.T., 2006. Consistency
in the Analytic Hierarchy Process: A New
Approach. Journal of Uncertainty, Fuzziness
and Knowledge-Based Systems, 14(4),
445-459.
- 34. Davras, G.M., Karaatlı, M., 2014. Otel
İşletmelerinde Tedarikçi Seçimi Sürecinde
AHP ve BAHP Yöntemlerinin Uygulaması
H.Ü. İktisadi ve İdari Bilimler Fakültesi
Dergisi, 32(1), 87-112.
- 35. Awasthi, A., Satyaveer S. Chauhan., 2011.
Using AHP and Dempster Shafer Theory for
Evaluating Sustainable Transport Solutions
Environmental Modelling & Software 26,
787-796.
- 36.Göksu, A., 2008. Bulanık Analitik Hiyerarşik
Proses ve Üniversite Tercih Sıralanmasında
Uygulanması. Süleyman Demirel Üniversitesi,
Sosyal Bilimler Enstitüsü, İşletme Ana Bilim
Dalı, Doktora Tezi, 128.
- 37. Filemon, J., 2010. Biofuels from Plant Oils.
http://www.aseanfoundation.org/documents/bo
oks/biofuel. pdf; [cited 16.04.2018].
- 38. Atadashi, I.M., Aroua, M.K., Abdul Aziz, A.,
2010. High Quality Biodiesel and its Diesel
Engine Application: A Review. Renewable and
Sustainable Energy Reviews;14(7), 1999-2008.
- 39. https://www.nrel.gov/docs/fy04osti/36244.pdf
cited 14.8.2018
- 40. Lapuerta, M., Armas, O., Rodriguez-
Fernandez, J., 2008. Effect of Biodiesel Fuels
on Diesel Engine Emissions. Progress in
Energy and Combustion Science; 34(2),
198-223.
- 41. Kilic, M., Ali, H.M., 2018. Numerical
Investigation of Combined Effect of
Nanofluids and Multiple Impinging Jets on
Heat Transfer, Thermal Science 2018 On Line-
First Issue 00, Pages: 94-94
doi.org/10.2298/TSCI171204094K.
- 42. Kilic, M., 2018. Askeri Sistemlerde
Nanoakışkan Uygulamalarının Sayısal
İncelemesi, The Journal of Defense Sciences,
17, 101-130, 10.17134/khosbd.427050.