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Dynamics and management of surface water and groundwater systems including modelling of water demand, surface processes, recharge, abstraction and integration of water infrastructure.
Integrated Surface Water and Groundwater Engineering is a final year elective course on water engineering in the undergraduate curriculum for civil and natural resources engineering students. A basic understanding of water systems is quite important in the study of surface and groundwater flows and for this reason ENCN342 is a prerequisite for this course.The increasing demand for water resources challenges our ability to understand and describe the underlying hydrologic processes. Water resources problems are seldom isolated, and their solution requires sophisticated numerical approaches to management that must address different, often conflicting, demands for water. Problems could include flood protection, conjunctive use of surface water and groundwater resources, and optimizing water distribution in a pipe network. This course introduces you to the tools you will need to conceptualize and solve complex water problems.Surface water engineeringIncreasingly, water resources are being managed on a catchment basis. Sustainable catchment management relies on robust understanding of: rainfall-runoff processes across the soil-plant-atmosphere continuum; how variability in catchment characteristics can influence rates and volumes of runoff; the relationship between flow and surface/groundwater water level at any location; and the effect of infrastructure on surface water flows. The development of appropriate catchment management solutions is also dependent on the ability to correctly evaluate the impact of different options. Furthermore, the growing focus on climate change has provoked increased need to understand the complex feedback between the climate, landuse, and the hydrologic cycle. This part of the course will deepen and expand the knowledge and skills gained in the previous parts of the surface water hydrology curriculum so that student will be able to work on a wider spectrum of hydrological engineering problems in an integrated manner. This includes both modelling of surface water processes and design of surface water infrastructure (e.g., earth channel design, culverts, drop structures).Groundwater engineeringBy virtue of their underground nature, groundwater systems are largely unobserved except where they breach surfaces (streams, springs, seepage) or are intersected by wells. Therefore, an ability to infer, extrapolate, abstract and model based on limited observations is essential to the sustainable use of these resources. This section of the course will introduce you to conceptual and numerical modelling of the whole groundwater system, including concepts of recharge and discharge, and safe-yield, abstraction, drawdown. The goal is for you to be able to develop models that can predict future aquifer response to water allocation decisions. Advanced topics including the unsaturated zone, groundwater quality, and surface water interactions will also be covered.Pipe network engineeringNetwork design concerns itself with the delivery of water where it is needed, at the required rate, and with enough redundancy to manage peak demand and safety constraints. At the micro-scale, pumping water through a single pipe is a complex problem that depends on friction, energy, pipe geometry, and fluid physics. At the macro-scale, networks must connect multiple inlet sources, user outlets, storage and treatment. This section of the course will challenge you to think about pipe networks as both a design and optimization problem.
1 Select and perform appropriate analytical calculations to address management and/or design aspects of a water resources problem. (Washington Accord WA1), (UC EIE, GA)2 Implement representations of water resource processes in a numerical model, with a specific application in pipe networks, groundwater aquifers, and/or surface water systems. (Washington Accord WA2, WA5), (UC EIE)3 Recommend water resource management activities using analytical calculations or a numerical model as part of the evidence base and consistent with relevant standards or regulations. Washington Accord WA3, WA6, WA7), (UC EIE, BCC, CE)The learning objectives align with the following Sustainable Development Goals (SDGs): SDG 6 Ensure availability and sustainable management of water and sanitation for all.
EMTH210, ENCI199, ENCN201, ENCN205 ENCN213, ENCN221, ENCN231, ENCN242, ENCN253, ENCN281, ENCN342
Students must attend one activity from each section.
Markus Pahlow
David Dempsey , Derek Li and Tom Cochrane
The assessment for this paper comprises several design reports (assignments), a mid-semester test and the final exam.Assignment reportsThere are four of these to be completed, one each for the surface water modelling (15%), groundwater (10%), pipe networks (15%) and surface water infrastructure design (10%) sections. They are an opportunity to apply the practical modelling and design skills you have developed during the lectures and tutorials to a specific case study.In addition to providing a description of the modelling activities, you will also have to submit any files developed with the various software packages used in this course as supporting evidence. Software package file submissions should be documented appropriately including commenting and a brief readme describing contents and proper operation.Special Consideration for AssignmentsAn extension will be granted for evidence-supported requests. Extensions will typically be for up to one week, but the duration will be considered on a case-by-case basis. Students seeking an extension must contact the course coordinator as soon as possible with evidence of their situation, and preferably before the due date. An extension will generally not be granted over the study week period.Special Consideration for Midterm Test and Final ExamStudents will be offered an equivalent alternative midterm test/exam, for evidence-supported requests. This exam will be generally held within a week after the scheduled examination. The alternative midterm test/exam will be of the same form as the original assessment.Note: All communication associated with the arrangement of equivalent alternative tests/exams will be conducted using official UC email accounts and LEARN. The offer to sit an alternative assessment will also provide the date/time when the alternative assessment takes place. Students will have a clearly specified amount of time to respond to the offer to sit the alternative assessment and to accept/decline. If the offer is declined or no response is received in the specified time frame, the original assessment mark will be used to compute the course grade.
This course does not have a required text and instead provides notes and other resources on LEARN. Furthermore, additional material will be posted on the class LEARN site as recommended reading/viewing. Please note that all lecture recordings, made available through LEARN, are copyright and are not for public dissemination.
Domestic fee $1,059.00
International fee $6,000.00
* All fees are inclusive of NZ GST or any equivalent overseas tax, and do not include any programme level discount or additional course-related expenses.
For further information see Civil and Natural Resources Engineering .