1. |
Outline |
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Outline; Automobile development engineering 1 and 2 describe the basic knowledge of automobile system design and estimation of performance. Thermodynamics, strength analysis of materials, mechanical dynamics, vibration engineering, fluid mechanics, tribology, and control engineering are applied to automobile system design. Exercises of the automobile system design and the performance estimation will be given to improve your understanding. Students can acquire the knowledge, skill and behavior for DP2 to DP5.
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2. |
Objectives |
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Objectives; Thermodynamics, strength analysis of materials, mechanical dynamics, vibration engineering, fluid mechanics, tribology, and control engineering are applied to automobile system design. Automobile development engineering 1 describes handling and stability, braking performance, and so on. Automobile development engineering 2 describes power train systems, drivability, environmental applicant technology and ergonomics design. Students will acquire engineering ability through exercises of automobile performance estimation and design. And students can discuss about the future mobility based on the knowledge and skill obtained through this lectures.
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3. |
Grading Policy |
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Your final grade will be calculated according to the reports for tasks(100%). And students have to take a class over 2/3 of total classes in this course, in order to take part in the term-end examination.
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4. |
Textbook and Reference |
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Textbook『Automobile Engineering(the second edittion)』;Kenji Higuchi et al, Tokyo Denki University Pablishing Breau 『Automobile Engineering for Easy Understanding』;Kenji Higuchi et al, Nisshin Pablishing Co., Ltd. 『Heat Engine Engineering』;Toshiaki Ochi et al, Korona Pablishing Co., Ltd. 『Base of Automobile Engineering』;JSAE
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5. |
Requirements (Assignments) |
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Students should study(1hr)reading textbook and documents by LMS and they also should review(2hr) based on the lectures and understand the content and then try to write a report. Students are required to submit a report for task in classes.
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6. |
Note |
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Students have to prepare and bring a scientific electronic calculator in the class. This course will be taught in Japanese.
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7. |
Schedule |
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1. Operation and Cycle of Engine |
2. Combustion and Thermal Efficiency of Engine |
3. Output and Function of Engine |
4. Practice ; Measurement of Engine Output and Fuel Consumption |
5. Task ; Calculation of Thermal Efficiency, Output, Fuel Consumption, Piston Speed and Mean Effective Pressure of Engine |
6. Running Resistance and Power Performance |
7. Automobile Performance Diagram and Gear Ratio |
8. Climbing and Acceleration Performance and Coasting Ability |
9. Task①;Calculation of Running Speed and Driving Force
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10. Task②;Calculation of Gear Ratio
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11. Practice;Comparison of Maximum Speed and Climbing Performance by changing Engine Output(Torque)---by Car Simulation |
12. The Human Biological System |
13. Comfortability of Driver and Passenger; Driving Position, Field of Vision and Ride |
14. Human-Machine Interface and Driver's Model |
15. Practice; Comparison between Response Performance of the Human Reaction Time and Automobile---by Car Simulation |
|
1. |
Outline |
|
Outline; Automobile development engineering 1 and 2 describe the basic knowledge of automobile system design and estimation of performance. Thermodynamics, strength analysis of materials, mechanical dynamics, vibration engineering, fluid mechanics, tribology, and control engineering are applied to automobile system design. Exercises of the automobile system design and the performance estimation will be given to improve your understanding. Students can acquire the knowledge, skill and behavior for DP2 to DP5.
|
2. |
Objectives |
|
Objectives; Thermodynamics, strength analysis of materials, mechanical dynamics, vibration engineering, fluid mechanics, tribology, and control engineering are applied to automobile system design. Automobile development engineering 1 describes handling and stability, braking performance, and so on. Automobile development engineering 2 describes power train systems, drivability, environmental applicant technology and ergonomics design. Students will acquire engineering ability through exercises of automobile performance estimation and design. And students can discuss about the future mobility based on the knowledge and skill obtained through this lectures.
|
3. |
Grading Policy |
|
Your final grade will be calculated according to the reports for tasks(100%). And students have to take a class over 2/3 of total classes in this course, in order to take part in the term-end examination.
|
4. |
Textbook and Reference |
|
Textbook『Automobile Engineering(the second edittion)』;Kenji Higuchi et al, Tokyo Denki University Pablishing Breau 『Automobile Engineering for Easy Understanding』;Kenji Higuchi et al, Nisshin Pablishing Co., Ltd. 『Heat Engine Engineering』;Toshiaki Ochi et al, Korona Pablishing Co., Ltd. 『Base of Automobile Engineering』;JSAE
|
5. |
Requirements (Assignments) |
|
Students should study(1hr)reading textbook and documents by LMS and they also should review(2hr) based on the lectures and understand the content and then try to write a report. Students are required to submit a report for task in classes.
|
6. |
Note |
|
Students have to prepare and bring a scientific electronic calculator in the class. This course will be taught in Japanese.
|
7. |
Schedule |
|
1. Operation and Cycle of Engine |
2. Combustion and Thermal Efficiency of Engine |
3. Output and Function of Engine |
4. Practice ; Measurement of Engine Output and Fuel Consumption |
5. Task ; Calculation of Thermal Efficiency, Output, Fuel Consumption, Piston Speed and Mean Effective Pressure of Engine |
6. Running Resistance and Power Performance |
7. Automobile Performance Diagram and Gear Ratio |
8. Climbing and Acceleration Performance and Coasting Ability |
9. Task①;Calculation of Running Speed and Driving Force
|
10. Task②;Calculation of Gear Ratio
|
11. Practice;Comparison of Maximum Speed and Climbing Performance by changing Engine Output(Torque)---by Car Simulation |
12. The Human Biological System |
13. Comfortability of Driver and Passenger; Driving Position, Field of Vision and Ride |
14. Human-Machine Interface and Driver's Model |
15. Practice; Comparison between Response Performance of the Human Reaction Time and Automobile---by Car Simulation |
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