Course Information


Course Information
Course Title Code Semester L+U Hour Credits ECTS
CLIMATIC ENVIRONMENTAL MANAGEMENT OF CROP PRODUCTION STRUCTURES 802100715390 3 + 0 3.0 8.0

Prerequisites None

Language of Instruction Turkish
Course Level Graduate Degree
Course Type Compulsory
Mode of delivery Theoretical and applied instruction based on lectures, homework, presentations, projects
Course Coordinator
Instructors Berna KENDİRLİ
Assistants
Goals Understanding the importance of climatic factors on crop production structure and planning of systems in ensuring the environmental management and to teach criteria for the projected
Course Content Plant requirements, Environmental effects on plant development, Greenhouse types and systems, Regulation of the environmental conditions in greenhouses, Heat and moisture balance, Ventilation systems, Heating and cooling systems, Regulation of the greenhouse, irrigation and drainage systems in greenhouse, Environmental control in computer applications, Project application of environmental control.
Learning Outcomes 1) It is gained engineering training for the planning and designing of crop production structures
2) It uses the method of analysis for the planning of crop production structures
3) It makes planning of crop production structures, properties, elements, plan formulation and implementation related micro and macro planning
4) It performs all types of projects related to the construction and property belonging to crop production structures in the agricultural facilities
5) It makes leadership and to take responsibility within the planning organization

Weekly Topics (Content)
Week Topics Teaching and Learning Methods and Techniques Study Materials
1. Week Classification of crop production structure, definition of greenhouse Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
2. Week Greenhouse climate factors, the effects of climate greenhouse design Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
3. Week Characteristics of the greenhouse climate, energy and mass balance in the greenhouse Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
4. Week Determination of the heat demand in the greenhouse and heating account for case study Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
5. Week Classification of greenhouse heating systems, planning and project planning, analysis of case studies Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
6. Week Designing greenhouse to the hot water heating system, analysis of case studies Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
7. Week Solar heating of greenhouses, sample projects work done Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
8. Week Midterm Exam Week Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
9. Week Geothermal energy for heating the greenhouses, sample projects work done Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
10. Week Planning of ventilation systems in greenhouses and projected, examination of case studies Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
11. Week Planning and projected greenhouse cooling system, examination of the sample projects Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
12. Week Carbon dioxide in greenhouses Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
13. Week Lighting and dimming applications in greenhouses, the analysis of case studies Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework
14. Week The computer-controlled greenhouses and automation systems Lecture; Question Answer; Problem Solving
Colloquium
Project Based Learning 		Homework

Sources Used in This Course
Recommended Sources
Anonymous. 1988. Energy Conservation and Renewable Energies for Greenhouses Heating , FAO Regional Office for Europe. CNRE Guideline No:2, Rome, 168p.
Başçetinçelik, A. ve Öztürk, H., 1996.Seralarda Isıtma. TEMAV Yayınları, No:1, Adana.
Baytorun, N.A., 1995. Seralar. Ç.Ü.Zir. Fak. Yayınları No:110, Ders Kitabı:29, Adana.
Çolak, A., 2002. Sera İçi Kliması ve Otomasyon. Muğla Üniv. Yayınları:31, Ortaca Meslek Yüksek Okulu Yayınları:01, Muğla.
Güncel konuya ilişkin yazılmış bilimsel makaleler, yapılmış projeler.
Öneş, A. 2000. Sera Planlama ve Projeleme Ders Notları. Ankara.
Öztürk, H.,2008. Sera İklimlendirme Tekniği.Hasad Yayıncılık,305s,İstanbul
Titiz,S. 2004. Modern Seralar. Antalya Sanayici ve İşadamları Derneği, 124s,Antalya
Yağcıoğlu,A., 2005. Sera Mekanizasyonu. Ege Üniversitesi Ziraat Fakültesi Yayınları No:562, İzmir.
Zabeltitz, von C.,2011. Integrated greenhouse systems for mild climates, Springer-Verlag Berlin Heidelberg

Relations with Education Attainment Program Course Competencies
Program RequirementsContribution LevelDK1DK2DK3DK4DK5
PY1500000
PY2500000
PY3500000
PY4500000

*DK = Course's Contrubution.
0 1 2 3 4 5
Level of contribution None Very Low Low Fair High Very High
.

ECTS credits and course workload
Event Quantity Duration (Hour) Total Workload (Hour)
Course Duration (Total weeks*Hours per week) 14 3
Work Hour outside Classroom (Preparation, strengthening) 14 3
Homework 2 10
Presentation (Including Preparation Time) 2 15
Project (Including Preparation and presentation Time) 2 15
Report (Including Preparation and presentation Time) 2 15
Midterm Exam 1 3
Time to prepare for Midterm Exam 1 5
Final Exam 1 3
Time to prepare for Final Exam 1 5
1 3
1 2
1 3
1 3
1 6
Total Workload
Total Workload / 30 (s)
ECTS Credit of the Course
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Course Information
  • Course Information
  • Weekly Topics (Content)
  • Sources Used in This Course
  • Relations with Education Attainment Program Course Competencies
  • ECTS credits and course workload