ENGCV323-18A (HAM)

Water Engineering 2

15 Points

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Faculty of Science and Engineering
Te Mātauranga Pūtaiao me te Pūkaha
School of Engineering

Staff

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Convenor(s)

Lecturer(s)

Administrator(s)

Placement Coordinator(s)

Tutor(s)

Student Representative(s)

Lab Technician(s)

Librarian(s)

: cheryl.ward@waikato.ac.nz
: debby.dada@waikato.ac.nz

You can contact staff by:

  • Calling +64 7 838 4466 select option 1, then enter the extension.
  • Extensions starting with 4, 5 or 9 can also be direct dialled:
    • For extensions starting with 4: dial +64 7 838 extension.
    • For extensions starting with 5: dial +64 7 858 extension.
    • For extensions starting with 9: dial +64 7 837 extension.
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Paper Description

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Application of fluid mechanics principles to water engineering applications such as the design of pipe system networks, pump characteristics and selection, open channel flow, hydraulic jump, measurement, analysis and modelling of surface hydrological processes.

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Paper Structure

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This paper is taught using a combination of lectures, tutorials and practical exercises. This paper includes four main parts.

The first part focuses on Pipe Hydraulics this section starts with principals of flow in single pipelines and expend to pipe network, pumps and design of water distribution systems.

The second part concentrates on Open Channel Hydraulics, after studying principals of flow in open channels, this section follows by designing of hydraulic structures like culverts and spillways.

The third part of the paper deals with Groundwater Hydraulics and gives useful information about groundwater investigations and groundwater numerical modelling.

The last part of the paper concentrates on Hydrology Engineering and provide required information for hydrologic study including infiltration process, surface water/groundwater interaction methods, runoff models and routing models.

this paper introduces papular water Engineering computer designing models.

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Learning Outcomes

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Students who successfully complete the course should be able to:

  • 1. Analyse pipelines and pipe networks, including:
    • Major and minor losses,
    • Single pipe analyses,
    • Pipe network analysis,
    • Computer applications, and
    • Practical aspects of pipe system design.
    Linked to the following assessments:
  • 2. Analyse uniform and nonuniform open channel flow, including:
    • Manning’s formula,
    • Specific energy,
    • Critical depth,
    • Sub-and supercritical flow,
    • Froude number,
    • Flow profiles, and
    • Practical aspects of channel system design .
    Linked to the following assessments:
  • 3.Assessment of ground water resources
    • Types of aquifers,
    • Fundamental equations of groundwater flow,
    • Numerical and analytical solutions of groundwater equation, and
    • Aaquifer tests Design.
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  • 4. Apply standard techniques, computational tools, and data used by engineers in  conducting hydrologiccal analyses.
    • Rainfall-runoff models,
    • Routing models,
    • Stormwater system design, and
    • River basin modelling.
    Linked to the following assessments:
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Assessment

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Assessed work involves completing three laboratory and one field experiment reports. Each report is expected to include following materials: original data, graphs and analysis, and an interpretation of the results presented. A report template and marking criteria will be provided to show what does it mean a “good report”.

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Assessment Components

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The internal assessment/exam ratio (as stated in the University Calendar) is 50:50. There is no final exam. The final exam makes up 50% of the overall mark.

The internal assessment/exam ratio (as stated in the University Calendar) is 50:50 or 0:0, whichever is more favourable for the student. The final exam makes up either 50% or 0% of the overall mark.

Component DescriptionDue Date TimePercentage of overall markSubmission MethodCompulsory
1. Exam
50
2. Test
12 Apr 2018
3:00 PM
20
  • In Class: In Lecture
3. Assessed lab. 1 report
11 May 2018
11:30 PM
7
  • Online: Submit through Moodle
4. Assessed lab. 2 report
18 May 2018
11:30 PM
7
  • Online: Submit through Moodle
5. Assessed lab. 3 report
25 May 2018
11:30 PM
7
  • Online: Submit through Moodle
6. Assessed field experiment report
1 Jun 2018
11:30 PM
9
  • Online: Submit through Moodle
Assessment Total:     100    
Failing to complete a compulsory assessment component of a paper will result in an IC grade
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Required and Recommended Readings

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Required Readings

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provided materials on the Moodle site.
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Recommended Readings

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Chin D. A., 2006; Water-Resources Engineering. 2nd edition. Pearson Prentice Hall.

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Online Support

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Online support will be provided via Moodle, which is accessible to all students who are enrolled in the paper.
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Workload

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There are 34 lectures, 12 tutorials, 6 hours of hydraulic lab, and 2 hours of fieldwork. Three laboratory and one field experiment reports are expected to take approximately 5 hours of individual study each to complete.
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Linkages to Other Papers

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Prerequisite(s)

Prerequisite papers: ENGCV223

Corequisite(s)

Equivalent(s)

Restriction(s)

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