2.1a. Modul Handbook of B.Eng Civil Engineering
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Modul name |
Hydraulic Modelling |
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Level module |
6 (undergraduate) |
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Abbreviation of applicable |
SIP 620324 |
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Sub-heading, if applicable |
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Courses included in the module, if applicable |
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Semester |
VI |
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Person in charge |
Ir. Ahmad Zakaria, M.T., Ph.D |
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Lecturer |
1. Ir. Ahmad Zakaria, M.T., Ph.D 2. Subuh Tugiono, ST., MT |
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Language |
Bahasa Indonesia, English |
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Classifications within the curriculum |
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Teaching (hours per week during the semester |
2 class hour lecture (2´170 minutes lecture) ´ 16 weeks |
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Workload per semester |
340 minutes lecture is divided into 100 minutes face to face interaction, 120 minutes structural activities, 120 minutes independent study |
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Credit points |
2 SKS (3.12 ECTS) |
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Learning objective |
A01 |
Fulfilling task with moral, ethics and manner (2-S) |
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A02 |
Capable to be part of team work and showing social awareness (4a-W) |
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A03 |
Being eager to be independent (4b-S) |
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C04 |
Capable to design and apply innovative construction, eco-friendly, low-cost, adaptive to climate change (7a-S) |
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P05 |
Mastering tools and software, collecting information, and applicable procedure that has been determined (7b-S) |
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C06 |
Capable to fulfill task as technician, analyst, and engineer with low-cost approach, emphasizing in coastal building and infrastructure that adaptive to climate change (8-S) |
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C07 |
Knowledgeable and skillful to fulfill the requirements of applicable standard incorporating factual and specific expertise emphasizing in coastal building and infrastructure that adaptive to climate change; hence having competencies to complete task properly and thoroughly (9-S). |
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A08 |
Responsible and enable to fulfill task holistically (10-S) |
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A09 |
Have a willingness to learn throughout lifetime (11-S) |
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Note: C: cognitive; A: affective; P: psychomotor |
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Course Learning Outcomes/ Competencies |
Being able to:
1. Explain the geometry of river and create a river confluence (C2;2-C6;18) 2. Explain data acquisition method, how to create a new model, how to add data to an existing model, how to make synergy liquid (C2;2) 3. Analyze general hydraulic system, advanced hydraulic analysis, including age and contamination (C4;1) 4. Analyze steady water depth profiles for the different flow scenarios entering cross sections, on the longitudinal profile of the river and entering it with geometry information to the model (C4;1) 5. Represent hydraulic analysis of the water depth profiles on cross sections and on the longitudinal profile of the river (C4;3) 6. Apply hydraulic calculations by adding a hydraulic structure (culvert) to the river system (C6;11-C6;18) 7. Represent a river model where there exists a river confluence (C4;3) 8. Use and analysis of the non-steady conditions and make a simulation (C3;5-C4;1-C6;15) 9. Apply a hydraulic model by adding a bridge into the river system (C6-11). 10. Develop flood model in 2D (two-dimension) using software, and analysis of the flow conditions (C6;19-C4;1). 11. Model a channel from a DEM and export results to any GIS software: create a hydraulic model of a channel, adjust Digital Elevation Models (DEM), obtain cross-sections from DEMs, perform a steady flow simulation, obtain results that can be used in any GIS software (C6;15-C6;11-C3;8-C2;19). 12. Analyze sediment, geometry, entering quasi unsteady flow data (sediment), setting initial condition and transport parameters, transport of sediment (C4;1-C4;3). 13. Creating a flood hazard map (C6;20) 14. Explain the sequence of a code (C6;7) 15. Create dynamic maps (C6;20)
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Content |
Lecturing:
1. Flow data details: geometry information of the cross sections of the river, river confluence, river system, hydraulic structure (culvert), general hydraulic system, advanced hydraulic analysis, synergy liquid, hydraulic calculations; steady flow, steady water depth profiles, different flow scenarios; model of cross section and longitudinal profile of the river with geometry input. 2. Hydraulic modeling: river system, reservoir structure and components, evaluate long-time simulation results, inserting geometry information of the cross sections of the river, non-steady conditions 3. Hydraulic modelling: bridge structure 4. Developing a flood model in 2D (two-dimension) using software: different flow conditions. 5. Modeling a channel from a Digital Elevation Models (DEM): hydraulic model of a channel, adjust DEM, obtain cross-sections from DEMs, steady flow simulation. 6. Sediment analysis: geometry preparation, quasi unsteady flow data (sediment), initial condition and transport parameters, Transport of sediment, flood hazard map, the sequence of a code, dynamic maps |
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A. Practical work
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Study/ exam achievement |
Assessment Aspect (%) |
A1 |
A2 |
A3 |
C4 |
P5 |
C6 |
C7 |
A8 |
A9 |
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Quiz (20%) - writing test |
Ö |
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Ö |
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Ö |
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Ö |
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Mid test (25%)- writing test |
Ö |
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Ö |
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Ö |
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Ö |
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Final test (35%)- writing test |
Ö |
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Ö |
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Ö |
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Ö |
Ö |
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Final Task (20%) |
Ö |
Ö |
Ö |
Ö |
Ö |
Ö |
Ö |
Ö |
Ö |
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Score index |
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A |
A ³76 |
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B+ |
71 £ B+ < 76 |
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B |
66 £ B < 71 |
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C+ |
61 £ C+< 66 |
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C |
56 £ C < 61 |
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D |
50 £ D < 56 |
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E |
E < 50 |
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Forms of media |
Software |
Hardware |
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Ms. Office (PPT, Ms Word, Ms. Excel) |
Projector |
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LCD |
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Laptop, computer |
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