Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2019, , 251 - 256, 30.09.2019
https://doi.org/10.18466/cbayarfbe.453763

Öz

Kaynakça

  • 1. Lee, K, Hwang, Y, Cheong, S, Choi, Y, Kwon, L, Lee, J, Kim, S.H. 2009. Understanding the role of nanoparticles in nano-oil lubrication. Tribology Letters; 35(2): 127–131.
  • 2. Liu, G, Li, X, Qin, B, Xing, D, Guo, Y, Fan, R. 2004. Investigation of the mending effect and mechanism of copper nano-particles on a tribologically stressed surface. Tribology Letters; 17(4): 961–966.
  • 3. Tao, X, Jiazheng, Z, Kang, X. 1996. The ball-bearing effect of diamond nanoparticles as an oil additive. Journal of Physics D: Applied Physics; 29(11): 2932–2937.
  • 4. Padgurskas, J, Rukuiza, R, Prosyčevas, I, Kreivaitis, R. 2013. Tribological properties of lubricant additives of Fe, Cu and Co nanoparticles. Tribology International; 60: 224–232.
  • 5. Tarasov, S, Kolubaev, A, Belyaev, S, Lerner, M, Tepper, F. 2012. Study of friction reduction by nanocopper additives to motor oil. Wear; 252(1–2): 63–69.
  • 6. Yu, H, Xu, Y, Shi, P.J, Xu, B.S, Wang, X.L, Liu, Q, Wang, H.M. 2008. Characterization and nano-mechanical properties of tribofilms using Cu nanoparticles as additives. Surface and Coatings Technology; 203(1–2): 28–34.
  • 7. Choi, Y, Lee, C, Hwang, Y, Park, M, Lee, J, Choi, C, Jung, M. 2009. Tribological behavior of copper nanoparticles as additives in oil. Current Applied Physics; 9(2): 124–127.
  • 8. Ali, M.K.A, Xianjun, H, Mai, L, Bicheng, C, Turkson, R.F, Qingping, C. 2016. Reducing frictional power losses and improving the scuffing resistance in automotive engines using hybrid nanomaterials as nano-lubricant additives. Wear; 365, 270–281.
  • 9. Padgurskas, J, Rukuiza, R, Prosyčevas, I, Kreivaitis, R. 2013. Tribological properties of lubricant additives of Fe, Cu and Co nanoparticles. Tribology International; 60: 224–232.
  • 10. Ali, MKA, Fuming, P, Younus, HA, Abdelkareem, MAA, Essa, FA, Elagouz, A, Xianjun, H. 2018. Fuel economy in gasoline engines using Al2O3/TiO2 nanomaterials as nanolubricant additives. Applied Energy; 211: 461-478.
  • 11. Suryawanshi, SR, Pattiwar, JT. 2018. Effect of TiO2 nanoparticles blended with lubricating oil on the tribological performance of the journal bearing. Tribology in Industry; 40(3): 370-391.
  • 12. Zin, V, Agresti, F, Barison, S, Colla, L, Gondolini, A, Fabrizio, M. 2013. The synthesis and effect of copper nanoparticles on the tribological properties of lubricant oils. Nanotechnology; 12: 751–759.
  • 13. Bi, S, Guo, K, Liu, Z, Wu, J. 2011. Performance of a domestic refrigerator using TiO2-R600a nano-refrigerant as working fluid. Energy Conversion Management; 52: 733–737.
  • 14. Xing, M, Wang, R, Yu, J. 2014. Application of fullerene C60 nano-oil for performance enhancement of domestic refrigerator compressors, International Journal of Refrigeration; 40: 398–403.
  • 15. Podgornika, B, Vizintina, J, Jacobsonb, S, Hogmarkb, S. 2004. Tribological behaviour of WCyC coatings operating under different lubrication regimes. Surface and Coatings Technology; 177–178: 558-565.
  • 16. Ali, MKA, Fuming, P, Younus, HA, Abdelkareem, MAA, Essa, FA, Elagouz, A, Xianjun, H. 2018. Fuel economy in gasoline engines using Al2O3/TiO2 nanomaterials as nanolubricant additives. Applied Energy; 211: 461-478.
  • 17. Ali, MKA, Xianjun, H, Abdelkareem, MAA, Gulzar, M, Elsheikh, AH. 2018. Novel approach of the graphene nanolubricant for energy saving via antifriction/ wear in automobile engines. Tribology International; 124: 209-229.
  • 18. ASTM D-445, Standard test method for kinematic viscosity of transparent and opaque liquids, American Society for Testing and Materials. https://www.astm.org/Standards/D445 (accessed at 15.04.2018).
  • 19. Zhang, S, Hu, L, Feng, D, Wang, H. 2013. Anti-wear and friction-reduction mechanism of Sn and Fe nanoparticles as additives of multialkylated cyclopentanes under vacuum condition. Vacuum; 87: 75–80.
  • 20. Arumugam, S, Sriram, G. 2013. Preliminary study of nano- and microscale TiO2 additives on tribological behavior of chemically modified rapeseed oil. Tribology Transactions; 56(5): 797–805.
  • 21. Krishna Sabareesh, R, Gobinath, N, Sajith, V, Das, S, Sobhan, C. B. 2012. Application of TiO2 nanoparticles as a lubricant-additive for vapor compression refrigeration systems: an experimental investigation. International Journal of Refrigeration; 35(7): 1989–1996.
  • 22. Ali, M.K.A, Xianjun, H. 2015. Improving the tribological behavior of internal combustion engines via the addition of nanoparticles to engine oils. Nanotechnology Reviews; 4(4): 347–358.
  • 23. Ali, M.K.A, Xianjun, H, Turkson, R.F, Ezzat, M. 2015. Analytical study of tribological parameters between piston ring and cylinder liner in internal combustion engines. Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics; 230(4): 329-349.
  • 24. Blau, P.J. 2001. A review of sub-scale test methods to evaluate the friction and wear of ring and liner materials for spark and compression ignition engines. National Laboratory Technical Report, Tennessee, USA.

Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation

Yıl 2019, , 251 - 256, 30.09.2019
https://doi.org/10.18466/cbayarfbe.453763

Öz

In this study, it was aimed to investigate the effects of copper (II)
oxide (CuO), copper zinc iron oxide (CuZnFe
2O4) and
copper iron oxide (CuFe
2O4) nanoparticle additives in
synthetic diesel engine oil (5W-40) at the fraction of 0.08 wt% on friction and
wear in piston ring-cylinder liner mechanism of the engine. In this regard,
Scanning Electron Microscope (SEM) analyses of the nanoparticles were first
carried out and via a linear reciprocating tribometer, friction coefficients
were determined on specimens comprised of the same material with real engine
piston ring. Subsequently, SEM analyses of the samples exposed to abrasion were
carried out to investigate the wear characteristics. In the second stage of the
experimental study, oil sump of the diesel test engine was filled with raw oil
(oil without nano additives) and prepared nano oils (oil+nano additives)
separately to unravel the effects of the lubricants on engine power and carbon
monoxide (CO) emissions. According to the results, it was determined that
CuZnFe
2O4 nano lubricant was the most pronounced of all
in terms of tribological performance, engine power and CO emissions. The
results depicted that, in the best case, an average increment of 15% in engine
power and an average reduction of 18% in CO emissions with CuZnFe2O4 nano oil
were provided compared to that of the raw oil.

Kaynakça

  • 1. Lee, K, Hwang, Y, Cheong, S, Choi, Y, Kwon, L, Lee, J, Kim, S.H. 2009. Understanding the role of nanoparticles in nano-oil lubrication. Tribology Letters; 35(2): 127–131.
  • 2. Liu, G, Li, X, Qin, B, Xing, D, Guo, Y, Fan, R. 2004. Investigation of the mending effect and mechanism of copper nano-particles on a tribologically stressed surface. Tribology Letters; 17(4): 961–966.
  • 3. Tao, X, Jiazheng, Z, Kang, X. 1996. The ball-bearing effect of diamond nanoparticles as an oil additive. Journal of Physics D: Applied Physics; 29(11): 2932–2937.
  • 4. Padgurskas, J, Rukuiza, R, Prosyčevas, I, Kreivaitis, R. 2013. Tribological properties of lubricant additives of Fe, Cu and Co nanoparticles. Tribology International; 60: 224–232.
  • 5. Tarasov, S, Kolubaev, A, Belyaev, S, Lerner, M, Tepper, F. 2012. Study of friction reduction by nanocopper additives to motor oil. Wear; 252(1–2): 63–69.
  • 6. Yu, H, Xu, Y, Shi, P.J, Xu, B.S, Wang, X.L, Liu, Q, Wang, H.M. 2008. Characterization and nano-mechanical properties of tribofilms using Cu nanoparticles as additives. Surface and Coatings Technology; 203(1–2): 28–34.
  • 7. Choi, Y, Lee, C, Hwang, Y, Park, M, Lee, J, Choi, C, Jung, M. 2009. Tribological behavior of copper nanoparticles as additives in oil. Current Applied Physics; 9(2): 124–127.
  • 8. Ali, M.K.A, Xianjun, H, Mai, L, Bicheng, C, Turkson, R.F, Qingping, C. 2016. Reducing frictional power losses and improving the scuffing resistance in automotive engines using hybrid nanomaterials as nano-lubricant additives. Wear; 365, 270–281.
  • 9. Padgurskas, J, Rukuiza, R, Prosyčevas, I, Kreivaitis, R. 2013. Tribological properties of lubricant additives of Fe, Cu and Co nanoparticles. Tribology International; 60: 224–232.
  • 10. Ali, MKA, Fuming, P, Younus, HA, Abdelkareem, MAA, Essa, FA, Elagouz, A, Xianjun, H. 2018. Fuel economy in gasoline engines using Al2O3/TiO2 nanomaterials as nanolubricant additives. Applied Energy; 211: 461-478.
  • 11. Suryawanshi, SR, Pattiwar, JT. 2018. Effect of TiO2 nanoparticles blended with lubricating oil on the tribological performance of the journal bearing. Tribology in Industry; 40(3): 370-391.
  • 12. Zin, V, Agresti, F, Barison, S, Colla, L, Gondolini, A, Fabrizio, M. 2013. The synthesis and effect of copper nanoparticles on the tribological properties of lubricant oils. Nanotechnology; 12: 751–759.
  • 13. Bi, S, Guo, K, Liu, Z, Wu, J. 2011. Performance of a domestic refrigerator using TiO2-R600a nano-refrigerant as working fluid. Energy Conversion Management; 52: 733–737.
  • 14. Xing, M, Wang, R, Yu, J. 2014. Application of fullerene C60 nano-oil for performance enhancement of domestic refrigerator compressors, International Journal of Refrigeration; 40: 398–403.
  • 15. Podgornika, B, Vizintina, J, Jacobsonb, S, Hogmarkb, S. 2004. Tribological behaviour of WCyC coatings operating under different lubrication regimes. Surface and Coatings Technology; 177–178: 558-565.
  • 16. Ali, MKA, Fuming, P, Younus, HA, Abdelkareem, MAA, Essa, FA, Elagouz, A, Xianjun, H. 2018. Fuel economy in gasoline engines using Al2O3/TiO2 nanomaterials as nanolubricant additives. Applied Energy; 211: 461-478.
  • 17. Ali, MKA, Xianjun, H, Abdelkareem, MAA, Gulzar, M, Elsheikh, AH. 2018. Novel approach of the graphene nanolubricant for energy saving via antifriction/ wear in automobile engines. Tribology International; 124: 209-229.
  • 18. ASTM D-445, Standard test method for kinematic viscosity of transparent and opaque liquids, American Society for Testing and Materials. https://www.astm.org/Standards/D445 (accessed at 15.04.2018).
  • 19. Zhang, S, Hu, L, Feng, D, Wang, H. 2013. Anti-wear and friction-reduction mechanism of Sn and Fe nanoparticles as additives of multialkylated cyclopentanes under vacuum condition. Vacuum; 87: 75–80.
  • 20. Arumugam, S, Sriram, G. 2013. Preliminary study of nano- and microscale TiO2 additives on tribological behavior of chemically modified rapeseed oil. Tribology Transactions; 56(5): 797–805.
  • 21. Krishna Sabareesh, R, Gobinath, N, Sajith, V, Das, S, Sobhan, C. B. 2012. Application of TiO2 nanoparticles as a lubricant-additive for vapor compression refrigeration systems: an experimental investigation. International Journal of Refrigeration; 35(7): 1989–1996.
  • 22. Ali, M.K.A, Xianjun, H. 2015. Improving the tribological behavior of internal combustion engines via the addition of nanoparticles to engine oils. Nanotechnology Reviews; 4(4): 347–358.
  • 23. Ali, M.K.A, Xianjun, H, Turkson, R.F, Ezzat, M. 2015. Analytical study of tribological parameters between piston ring and cylinder liner in internal combustion engines. Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics; 230(4): 329-349.
  • 24. Blau, P.J. 2001. A review of sub-scale test methods to evaluate the friction and wear of ring and liner materials for spark and compression ignition engines. National Laboratory Technical Report, Tennessee, USA.
Toplam 24 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Ali Can Yılmaz

Yayımlanma Tarihi 30 Eylül 2019
Yayımlandığı Sayı Yıl 2019

Kaynak Göster

APA Yılmaz, A. C. (2019). Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation. Celal Bayar Üniversitesi Fen Bilimleri Dergisi, 15(3), 251-256. https://doi.org/10.18466/cbayarfbe.453763
AMA Yılmaz AC. Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation. CBUJOS. Eylül 2019;15(3):251-256. doi:10.18466/cbayarfbe.453763
Chicago Yılmaz, Ali Can. “Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 15, sy. 3 (Eylül 2019): 251-56. https://doi.org/10.18466/cbayarfbe.453763.
EndNote Yılmaz AC (01 Eylül 2019) Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 15 3 251–256.
IEEE A. C. Yılmaz, “Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation”, CBUJOS, c. 15, sy. 3, ss. 251–256, 2019, doi: 10.18466/cbayarfbe.453763.
ISNAD Yılmaz, Ali Can. “Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 15/3 (Eylül 2019), 251-256. https://doi.org/10.18466/cbayarfbe.453763.
JAMA Yılmaz AC. Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation. CBUJOS. 2019;15:251–256.
MLA Yılmaz, Ali Can. “Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi, c. 15, sy. 3, 2019, ss. 251-6, doi:10.18466/cbayarfbe.453763.
Vancouver Yılmaz AC. Effects of Nano-Lubricants on Power and CO Emission of a Diesel Engine: An Experimental Investigation. CBUJOS. 2019;15(3):251-6.