| 1. Course Title | Photovoltaic Systems | |||||||
| 2. Code | 3ФЕИТ04Л029 | |||||||
| 3. Study program | EAOIE, EEUM | |||||||
| 4. Organizer of the study program (unit, institute, department) | Faculty of Electrical Engineering and Information Technologies | |||||||
| 5. Degree (first, second, third cycle) | First cycle | |||||||
| 6. Academic year/semester | III/6, IV/8 | 7. Number of ECTS credits | 6.00 | |||||
| 8. Lecturer | Dr Dimitar Dimitrov | |||||||
| 9. Course Prerequisites | ||||||||
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10. Course Goals (acquired competencies): Obtaining knowledge about PV systems’ operation. Getting ability for identification of cost-effective PV systems application. Competence for adequate choice of locations and components of PV systems. Acquainting with methods analyzing and sizing of PV systems. |
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11. Course Syllabus: Introduction, application and types of photovoltaic (PV) systems. Characteristics and components of the solar radiation. Meteo databases. Photovoltaic conversion processes in solar cells. Current-voltage characteristics of solar cells and temperature influence. Types of PV cells and their characteristics. Components of a PV generator. Balance-of-system components. Stand-alone PV systems. Hybrid PV systems. Grid-connected PV systems. Component connections and topologies. Mounting structures and choosing adequate location for installing a PV system. Techno-economic analyses of PV systems. Methods for sizing of PV systems. |
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| 12. Learning methods: Lectures with presentations, interactive lectures, numerical exercises, laboratory exercises, study visits. | ||||||||
| 13. Total number of course hours | 3 + 1 + 1 + 0 | |||||||
| 14. Distribution of course hours | 180 | |||||||
| 15. Forms of teaching | 15.1. Lectures-theoretical teaching | 45 | ||||||
| 15.2. Exercises (laboratory, practice classes), seminars, teamwork | 30 | |||||||
| 16. Other course activities | 16.1. Projects, seminar papers | 30 | ||||||
| 16.2. Individual tasks | 30 | |||||||
| 16.3. Homework and self-learning | 45 | |||||||
| 17. Grading | 17.1. Exams | 35 | ||||||
| 17.2. Seminar work/project (presentation: written and oral) | 10 | |||||||
| 17.3. Activity and participation | 5 | |||||||
| 17.4. Final exam | 50 | |||||||
| 18. Grading criteria (points) | up to 50 points | 5 (five) (F) | ||||||
| from 51 to 60 points | 6 (six) (E) | |||||||
| from 61 to 70 points | 7 (seven) (D) | |||||||
| from 71 to 80 points | 8 (eight) (C) | |||||||
| from 81 to 90 points | 9 (nine) (B) | |||||||
| from 91 to 100 points | 10 (ten) (A) | |||||||
| 19. Conditions for acquiring teacher’s signature and for taking final exam | Continual attendance of lectures, doing homeworks and student projects. | |||||||
| 20. Forms of assessment | During the semester, two partial written 120 minutes exams or a written 120 minutes exam are forseen. For students who have passed the partial exams or the exam, a final oral exam (duration 60 minutes) may be conducted. The points from the partial exams or the exam and the final oral exam are included into the final grade | |||||||
| 21. Language | Macedonian and English | |||||||
| 22. Method of monitoring of teaching quality | Internal evaluation and surveys. | |||||||
| 23. Literature | ||||||||
| 23.1. Required Literature | ||||||||
| No. | Author | Title | Publisher | Year | ||||
| 1 | Planning and Installing Photovoltaic Systems | DGS/Berlin | 2008 | |||||
| 2 | Heinrich Häberlin | Photovoltaics System Design and Practice | John Wiley & Sons Ltd. | 2012 | ||||
| 3 | Tamer Khatib, Wilfried Elmenreich | Photovoltaic Solar Energy Generation Using MATLAB® | John Wiley & Sons Ltd. | 2016 | ||||
| 23.2. Additional Literature | ||||||||
| No. | Author | Title | Publisher | Year | ||||
| 1 | B. K. Hodge | Alternative Energy Systems and Applications | Ars LAMINA | 2013 | ||||
| 2 | Christiana Honsberg, Stuart Bowden | www.pveducation.org | Arizona State University | 2016 | ||||
| 3 | T. Markvart | Solar Electricity | John Wiley & Sons Ltd. | 1994 | ||||
