|
Хулоса
Фойдаланилган адабиётлар рўйхати
1. Abdiyev U.B. “Fizika taʼlimida noanʼanaviy energiya manbalariga doir bilim, koʻnikma va malakalarni shakllantirish imkoniyatlari”. O’quv qo’llanma. -Zamonaviy taʼlim. - Toshkent – 2016. - 31-38 b.
2. Abdiyev U.B., Ismoilov E. “Fizika taʼlimida Quyosh fotoelementlarini tayyorlash va ularning samaradorligini oshirish imkoniyatlarini oʻrganish”. O’quv qo’llanma. - Fizika, matematika va informatika. - Toshkent – 2015. - 32-36 b.
3. Arenas L, de Leon CP, Walsh F. Engineering aspects of the design, construction and performance of modular redox flow batteries for energy storage. J Storage Mater 2017. P–53.
4. Barsali S, Giglioli R, Lutzemberger G, Poli D, Valenti G. Optimised operation of storage systems integrated with MV photovoltaic plants, considering the impact on the battery lifetime. J Storage Mater 2017. P-178–85.
5. Blanc C, Rufer A. Understanding the vanadium redox flow batteries. Paths to Sustainable Energy. InTech; 2010. P-45.
6. Chahwan J, Abbey C, Joos G. VRB modelling for the study of output terminal voltages, internal losses and performance. Electrical Power Conference, 2007 EPC 2007 IEEE Canada. IEEE; 2007. p. 387–92
7. Choudar A, Boukhetala D, Barkat S, Brucker J-M. A local energy management of a hybrid PV-storage based distributed generation for microgrids. Energy Convers Manage 2015. P-21–33.
8. De Leon CP, Frías-Ferrer A, González-García J, Szánto D, Walsh FC. Redox flow cells for energy conversion. J Power Sources 2006. P–32.
9. David O, Percin K, Luo T, Gendel Y, Wessling M. Proton-exchange membranes based on sulfonated poly (ether ether ketone)/polyaniline blends for all-and air-vanadium redox flow battery applications. J Storage Mater 2015. P - 65–71.
10. Fathabadi H. Novel high efficiency DC/DC boost converter for using in photovoltaic systems. Sol Energy 2016. P - 22–31.
11. Fathabadi H. Novel photovoltaic based battery charger including novel high efficiency step-up DC/DC converter and novel high accurate fast maximum power point tracking controller. Energy Convers Manage 2016. P–11.
12. Gattrell M, Park J, MacDougall B, Apte J, McCarthy S, Wu C. Study of the mechanism of the vanadium 4+/5+ redox reaction in acidic solutions. J Electrochem Soc 2004. P–30.
13. Geckler R.D., Transient, radial heat conduction in hollow circular cylinders, J. Jet Propuls. 25 (1955) P-31-35, https://doi.org/10.2514/8.6581.
2.14. P.S. Ghahfarokhi, A. Kallaste, A. Belahcen, T. Vaimann, Thermal analysis of electromagnetic levitation coil, in: 2016 17th Int. Sci. Conf. Electr. Power Eng., IEEE, 2016, pp. 1-5, https://doi.org/10.1109/EPE.2016.7521725.
15. Ishaque, K., Salam, Z., Syafaruddin, 2011. A comprehensive MATLAB simulink PV system simulator with partial shading capability based on two-diode model. Sol. Energy, 85(9), pp. 2217–2227, doi: 10.1016/j.solener.2011.06.008.
16. IRENA, 2005. HelioClim3v4-MC Yearly Global Horizontal Irradiation [Online]. Available: https://irena.masdar.ac.ae/GIS/?map=529.
17. Itten, R., Frischknecht, R., Stucki, M., 2014. Life Cycle Inventories of Electricity Mixes and Grid, Version 1.3. treeze Ltd., Uster, Switzerland.
18. Jacobsson S, Johnson A. The diffusion of renewable energy technology: an analytical framework and key issues for research. Energy Policy 2000; 28(9): P-625-40.
19. Kebede KY, Mitsufuji T. Solar Innovation Systems Building: A Case of an NGO in Ethiopia. IEEE International Conference on Business Innovation and Technology Management; Beijing: IEEE Press; 2013, p. 92-7.
20. Kebede KY, Mitsufuji T, Choi EK. Looking for Innovation System Builders: A Case of Solar Energy Foundation in Ethiopia. African Journal of Science, Tehnology, Innovation, and Development.Forthcoming.
21. Lundvall B-A. National systems of innovation: Towards a theory of innovation and interactive learning. London: Pinter Publishers; 1992. P-21-22.
22. Malerba F. Sectoral systems of innovation and production. Research Policy 2002; 31(2):247, P–64.
23. Muchie M. Re-thinking Africa’s development through the national innovation system. In: Muchie M, Gammeltoft P,. Lundvall B-A˚, editors. Putting Africa First: The Making of African Innovation Systems, Sweden: Aalborg University Press; 2003. P-41.
24. Musiolik J, Markard J. Creating and shaping innovation systems: Formal networks in the innovation system for stationary fuel cells in Germany. Energy Policy 2011; 39:1909, P–22.
25. Musiolik J, Markard J, Hekkert MP. Networks and network resources in technological innovation systems: Towards a conceptual framework for system building. Technological Forecasting & Social Change 2012; P–48.
26. Musiolik J. Innovation-system building: On the role of actors, networks and resources. The case of stationary fuel cells in Germany. Doctoral dissertation, Utrecht University; 2012. P-22.
27. Negro SO, Alkemade F, Hekkert MP. Why does renewable energy diffuse so slowly? A review of innovation system problems. Renewable and Sustainable Energy Reviews 2012; 16: 3836. P-46.
28. Нян Линн Аунг “Разработка солнечной фотоэлектрической системы автономного электроснабжения индивидуальных потребителей в тропических условиях”. Диссертация. – M.: 2015. – 22 с.
29. Tursunov M.N., Mamadolimov A.T. Yarimoʻtkazgichli quyosh elementlari fizikasi va texnologiyasi. Darslik. – T.: 2002. – 48 b.
Do'stlaringiz bilan baham: |
