CIV6746 Design of Water Distribution and Sewer
Introduction - CIV6746 Assessment
This module has two assessed components:
(i) a written report containing two parts (each part described below in detail) – report worth 80% of the module grade. Part 1 reports on knowledge gained in the module (40% of module grade), Part 2 reports on the completion of a storm sewer overflow design (40% of module grade).
(ii) a design interview at an intermediate stage in the design process in which understanding of the design brief is tested, conceptual designs are evaluated, and a final design concept is determined for more detailed design – worth 20% of the module grade.
A list of dates and times for your interview will be circulated on Blackboard. Requirements for the interview will be posted on Blackboard and will be discussed during earlier tutorial sessions.
Both components are individual assessments.
Written Report: Part 1 - Knowledge
One of the Learning Outcomes of this module is to gain knowledge on methods used to design and operate sewer networks. This Learning Outcome to demonstrate your knowledge is assessed using a structured written report.
In this report, you should describe you understanding of:
1. Key components of sewer networks, how they are linked into networks and how their performance can be simulated.
2. Describe the software tools used by engineers to design sewer networks, explain the underlying simulation approaches, and explain the uncertainties inherent in these models.
3. Describe the expected performance standards for sewer networks and explain how these standards are ensured in the UK. Explain the role of economic, environmental and health regulations in determining expected standards of performance.
4. Describe the major challenges facing sewer networks over the next three decades and describe approaches that are being developed to meet these challenges.
Assessment Requirements: Part 1
This learning outcome will be assessed based on the first part of an individual report (the overall written report is 80% of the module grade, Part 1 is 40% of the module grade). The first part of this individual report should address the 4 items outlined above. This part of the written report should be no longer than 5000 words in length. The quality of referencing is important, and you should clearly describe the sources used to support your descriptions and explanations. The quality and relevance of any figures or tables is important and will also be assessed.
The assessment guidelines Part 1 of the report are:
1. Quality of the technical information, its detail and coverage 50%
2. Quality of any argument and explanation 30%
3. Structure of the report and clarity of executive summary and conclusions 10%
4. Quality of presentation of report (English language, figures, references) 10%
Written Report Part 2 - Sewer Overflow Design
You are to examine a combined sewer system that contains a storm sewer overflow (SSO). The existing overflow is potentially deficient and is the subject of an investigation by the Environment Agency.
The storm sewer overflow (SSO) is located at manhole SK35393201 (as shown on the provided layout plans) and has been identified as a “serious concern” by the Environment Agency as it is believed to be failing to meet the new frequency targets in Defra’s Storm Sewer Overflow Discharge Reduction plan.
There is also significant concern locally about the discharges from this SSO into the receiving watercourse causing “environmental harm”. The water company has already instigated a 12- month water quality monitoring campaign to ascertain whether this overflow meets the Fundamental Intermittent Standards for intermittent discharges. River water quality, rainfall and event duration monitoring data associated with this overflow is therefore available.
You are invited to design a SSO replacement scheme that is to be undertaken as part of the water company’s business planning in response to these concerns. It is proposed to abandon the current problematic SSO and build a new SSO and storage tank to address the frequency and ecological harm concerns on the receiving water.
It is up to you as the designer to investigate the feasibility of providing a storage tank solution to mitigate the detriment on the receiving water from intermittent discharges. A previously build hydraulic model has been initially reviewed by a modelling consultant and an export of this model local to the SSO site have been provided in addition to the results of the water quality monitoring, rainfall and event duration monitoring. Initial assessment of the spill flows predicted in the currently available model suggest that a reasonably sized storage volume to reduce the number of spills and mitigate impacts in the receiving water to an acceptable level can be achieved. However, this model was constructed, calibrated and verified several years ago and may be out of date given population growth and land use change in the upstream catchment. This uncertainty should be considered in your design. Any solution should also not increase flood risk about current levels in the contributing catchment.
As the design engineer, you have been commissioned to complete the initial feasibility investigation and outline a storage-based design and provide a report to the client detailing the following objectives.
1. Describe your understanding of the project brief and the requirements of the project.
2. Provide clear guidance to the client (the water company) on their obligations under the current and emerging legislative frameworks that govern the UK water industry in terms of SSO pollution and flood management, and any other associated design standards.
3. Provide a detailed description of your design to deliver a solution that would ensure that intermittent discharges from the improved overflow would be compliant with current and emerging legislation. Key considerations for your design:
a. Detail how you consider any storage volume would be best configured to be compliant.
b. Your storage tank should not retain sewage for longer than 8 hours duration in order to reduce the risk of septicity. Specify how you would recommend controlling this outlet flow from your tank.
c. Provide details on how you would propose to convey flows from the current system into your tank. This will require careful consideration of how you will connect into the live existing sewer and provide information on how you will manage sewer flows during the construction phase.
4. This is a feasibility study and there are limitations on available data. Provide details on what additional data may need to be collected and any other investigations required to both reduce risk associated with the construction of your proposed storage tank and data requirements for improving the hydraulic model and associated prediction of the design inflows (model risks). Clearly explain any uncertainties in the design method and your resulting solution.
5. Describe the long-term risks associated with the proposed solution and how they could be mitigated. This should include an assessment of the potential impact of emerging regulations, climate change, urban creep and operational issues (such as energy use, sedimentation, the build-up of fats, oils and greases). Describe what should be undertaken in order to mitigate the risk of such occurrences, including proposed maintenance regimes, and if you believe necessary, details of how the system could be adapted in the future to cope with long-term change if required.
Assessment Requirements: Part 2
This element of the overall module will be assessed based on Part 2 of an individual written report (Part 2 is worth 40% of the module mark). Part 2 of the written report should contain information on the 5 objectives outlined above.
The assessment guidelines for the second part of the written report are:
5. Quality of the technical work (see requirements above) 80%
6. Structure of the report and clarity of executive summary and conclusions 10%
7. Quality of presentation of report (English language, figures, references) 10%
Report Submission
For the written report a single pdf file containing the usual Departmental coversheet as the first page, should be submitted following Departmental guidelines by the deadline of 9.30am on Friday 7th June 2024.
Appendices for Design Information
A. Site layout plan
B. Export from hydraulic sewer network model
C. Details of existing SSO arrangement
Other design data - is available in an electronic format on Blackboard
A. Hydraulic network model
B. Water quality data
C. Rainfall data
D. EDM data