Nevşehir Hacı Bektaş Veli University Course Catalogue
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| Year/Semester of Study | 2 / Fall Semester | ||||
| Level of Course | 1st Cycle Degree Programme | ||||
| Type of Course | Compulsory | ||||
| Department | CIVIL ENGINEERING | ||||
| Pre-requisities and Co-requisites | None | ||||
| Mode of Delivery | Face to Face | ||||
| Teaching Period | 14 Weeks | ||||
| Name of Lecturer | OSMAN AKYÜREK (oakyurek@nevsehir.edu.tr) | ||||
| Name of Lecturer(s) | |||||
| Language of Instruction | Turkish | ||||
| Work Placement(s) | None | ||||
| Objectives of the Course | |||||
| The course provides engineering students firm foundations in the study of motion, forces that cause motion and their relationships for rigid bodies using Newton's Laws, energy and momentum principles and introduces systems governed by ordinary differential equations. | |||||
| Learning Outcomes | PO | MME | |
| The students who succeeded in this course: | |||
| LO-1 | Linear motion of a particle. Curvilinear motion of a particle: Cartesian components, Normal and Tangent components, Cylindrical components. Relative motion of two particles. Kinetics of a particle: Force and acceleration (components of Cartesian, Normal-Tangent, Cylindrical), Kinetics of a particle: Work and Energy, Impulsive and Momentum. Planar kinematics of a rigid body: translation motion, rot |
PO-1 Recovery adequate knowledge in the field of mathematics, science and civil engineering; ability to use theoretical and applied information in these areas to model and solve Civil Engineering problems.
PO-2 Ability to determine, identify, formulate and solve the sophisticated engineering problems, to select and apply appropriate methods and techniques for this purpose. PO-4 Skill of development, selection, using modern techniques and tools are necessary for engineering applications, ability of using information technology effectively. |
Term Paper |
| LO-2 | Linear motion of a particle. Curvilinear motion of a particle: Cartesian components, Normal and Tangent components, Cylindrical components. Relative motion of two particles. Kinetics of a particle: Force and acceleration (components of Cartesian, Normal-Tangent, Cylindrical), Kinetics of a particle: Work and Energy, Impulsive and Momentum. Planar kinematics of a rigid body: translation motion, rot |
PO-1 Recovery adequate knowledge in the field of mathematics, science and civil engineering; ability to use theoretical and applied information in these areas to model and solve Civil Engineering problems.
PO-2 Ability to determine, identify, formulate and solve the sophisticated engineering problems, to select and apply appropriate methods and techniques for this purpose. PO-3 The ability of designing a complex system, process, device product under realistic constraints and conditions and to meet certain requirements; for this purpose, the ability of applying modern design methods. |
Term Paper |
| LO-3 | An ability to design a complex system, process, device product under realistic constraints and conditions in a way to comply with specific requirements; an ability to apply modern design methods for this aim. |
PO-1 Recovery adequate knowledge in the field of mathematics, science and civil engineering; ability to use theoretical and applied information in these areas to model and solve Civil Engineering problems.
PO-2 Ability to determine, identify, formulate and solve the sophisticated engineering problems, to select and apply appropriate methods and techniques for this purpose. PO-11 Knowledge about contemporary issues and the global and societal effects of engineering practices on health, environment, and safety awareness of the legal consequences of engineering solutions |
Term Paper |
| PO: Programme Outcomes MME:Method of measurement & Evaluation |
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| Course Contents | ||
| Linear motion of a particle. Curvilinear motion of a particle: Cartesian components, Normal and Tangent components, Cylindrical components. Relative motion of two particles. Kinetics of a particle: Force and acceleration (components of Cartesian, Normal-Tangent, Cylindrical), Kinetics of a particle: Work and Energy, Impulsive and Momentum. Planar kinematics of a rigid body: translation motion, rotation motion and general motion. Planar relative motion of rigid bodies. Planar kinetics of a rigid body: Force and acceleration (translation motion, rotation motion and general motion). Planar kinetics of a rigid body: Energy methods. Vibration of particle and rigid body. | ||
| Weekly Course Content | ||
| Week | Subject | Learning Activities and Teaching Methods |
| 1 | Linear motion of a particle. | Description Method- Question Answer(Distance Education) |
| 2 | Cartesian components of curvilinear motion of a particle. | Description Method- Question Answer(Distance Education) |
| 3 | Normal-Tangent and Cylindrical components of curvilinear motion of a particle. | Description Method- Question Answer(Distance Education) |
| 4 | Relative motion of two particles. | Description Method- Question Answer(Distance Education) |
| 5 | Kinetics of a particle: Force and acceleration, components of Cartesian. | Description Method- Question Answer(Distance Education) |
| 6 | Kinetics of a particle: components of Normal-Tangent, Cylindrical. | Description Method- Question Answer(Distance Education) |
| 7 | Kinetics of a particle: Work and Energy, Impulsive and Momentum. | Description Method- Question Answer(Distance Education) |
| 8 | mid-term exam | |
| 9 | Planar translation and rotation motions of rigid bodies. | Description Method- Question Answer(Distance Education) |
| 10 | Planar general and relative motions of rigid bodies. | Description Method- Question Answer(Distance Education) |
| 11 | Planar kinetics of a rigid body: Force and acceleration, equations of translation and rotation motion. | Description Method- Question Answer(Distance Education) |
| 12 | Planar kinetics of a rigid body: General motion. | Description Method- Question Answer(Distance Education) |
| 13 | Planar kinetics of a rigid body: Energy methods. | Description Method- Question Answer(Distance Education) |
| 14 | Vibration of particle and rigid body. | Description Method- Question Answer(Distance Education) |
| 15 | Vibration of particle and rigid body. | Description Method- Question Answer(Distance Education) |
| 16 | final exam | |
| Recommend Course Book / Supplementary Book/Reading | ||
| 1 | Prof. Dr. R.C. Hibeler ve S.C. FAN, “ Mühendislik Mekaniği, Dinamik”, Literatür yayıncılık, 2007. | |
| 2 | Prof. Dr. Ferdinand P. BEER ve Prof. Dr. E. Russel JHONSTON, JR, “Mühendisler İçin Mekanik, Dinamik”, Birsen yayınevi, Baskı:1993. | |
| 3 | Prof. Dr. Mehmet H. Omurtag Muhendsilik Mekanigi DINAMIK | |
| Required Course instruments and materials | ||
| 1-Prof. Dr. R.C. Hibeler ve S.C. FAN, “ Mühendislik Mekanigi, Dinamik”, Literatür yayincilik, 2007. 2- Prof. Dr. Ferdinand P. BEER ve Prof. Dr. E. Russel JHONSTON, JR, “Mühendisler için Mekanik, Dinamik”, Birsen yayinevi, Baski:1993. | ||
| Assessment Methods | |||
| Type of Assessment | Week | Hours | Weight(%) |
| mid-term exam | |||
| Other assessment methods | |||
| 1.Oral Examination | |||
| 2.Quiz | |||
| 3.Laboratory exam | |||
| 4.Presentation | |||
| 5.Report | |||
| 6.Workshop | |||
| 7.Performance Project | |||
| 8.Term Paper | 1 | 1 | 40 |
| 9.Project | 1 | 1 | 60 |
| final exam | |||
| Student Work Load | |||
| Type of Work | Weekly Hours | Number of Weeks | Work Load |
| Weekly Course Hours (Theoretical+Practice) | 14 | 3 | 42 |
| Outside Class | |||
| a) Reading | 4 | 14 | 56 |
| b) Search in internet/Library | 0 | ||
| c) Performance Project | 0 | ||
| d) Prepare a workshop/Presentation/Report | 0 | ||
| e) Term paper/Project | 0 | ||
| Oral Examination | 0 | ||
| Quiz | 0 | ||
| Laboratory exam | 0 | ||
| Own study for mid-term exam | 8 | 3 | 24 |
| mid-term exam | 2 | 1 | 2 |
| Own study for final exam | 8 | 3 | 24 |
| final exam | 2 | 1 | 2 |
| 0 | |||
| 0 | |||
| Total work load; | 150 | ||