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Bachelor's and Certificate Admissions
Accolades entries are organized by degree program. Each program section includes an overview of the featured student works followed by a listing of individual project abstracts for easy browsing.
Students in the Master of Civil Engineering program pursue one of four tracks in geotechnical engineering, structural engineering, environmental/water resources engineering, or construction management. Reflecting Norwich’s institutional emphasis on learning and doing and the program’s dual cultivation of technical and business acumen, all of the following student projects involve a real-world civil engineering design or management challenge.
The case study provides both engineering technical information and an examination of the construction project management technique utilization, in relation to what was learnt at Norwich University, the lessons learned as a result of the Hurricane Sandy devastation, some salient facts about Hurricane Sandy and its impacts, and responses and mitigation of future occurrences. Hurricane Sandy, also referred to as super-storm Sandy, was unprecedented in scale and impact on the urban cluster comprised of New York City and the surrounding metro areas in addition to numerous coastal communities along the New Jersey and New York coasts. The storm exposed the fragility of our modern urban infrastructure and highlighted the vulnerability of this infrastructure to a potentially new norm of extreme events. The storm caused severe coastal damage, as well as major flooding that disrupted normal life in a number of communities as well as the business activities in Lower Manhattan, the financial capital of the world. The flooding, for the first time, affected numerous underground subways and roadways that further amplified the impact of the storm. The storm has raised awareness of issues associated with climate challenge, sea level rise and challenges we face as engineers and as a society in enhancing the resiliency of our infrastructure to rapidly recover from such an extreme natural event.
This paper encompassed the preparation of most of the necessary front-end engineering design (FEED) elements for a design-build construction management (CM) contract for a 60 metric ton per day (48-million pounds per year) guar processing facility by Kirkuk Global LLC, an international project management consulting firm. The construction management contract will be performed as either a traditional owner’s representative for the project sponsor, or as an at-risk CM under a guaranteed maximum price (GMP). Five major tasks have been identified as part of this project design effort: prepare a plant conceptual site plan and equipment layout design; prepare an organizational chart, plant payroll and construction budget; prepare a baseline project construction schedule; develop a quality assurance and a quality control manual; and prepare overall project pro forma financial statements.
Cost overruns and project delays are somewhat inevitable in the construction industry. The integration of computer applications and the emerging trend of “go green” methods can be used to help eliminate evolving construction problems. Construction project failure rates are as high as forty percent (40%); however integrating selected Building Information Modelling (BIM) tools and green engineering solutions, can generate a remarkable outcome of feasibility and productivity improvement of up to ninety percent (90%). Building Information Modelling (BIM) is defined as an intelligent model-based process that provides digital representations of physical building elements, where the user can view and interact with the model in 2D and 3D views, as well as orthographic two-dimensional plan, sections and elevation views. Selected BIM tools are clash detection, visualization, interoperability, construction planning / scheduling and automated code checking. Green engineering solutions is the application of green materials, cost-effective design, commercialization and use of chemical processes to minimize pollution at the source. Selected Green Engineering solutions such as alternative energy, green roof, structural insulated panels (SIP) and frost protected shallow foundation (FPSF). Case studies were completed to observe the results. Two projects that used neither BIM nor Green Engineering solutions did not achieve the planned completion date whilst the two chosen projects that used both were successful. In conclusion, the integration have proved to be fruitful and is becoming a new trend to attain maxim project feasibility and productivity, which by extension is the achievement of project success.
This project designs elements of the structure for the Flight Dynamics Research Facility at NASA Langley Research Center. The primary objective is to present a preliminary structural design to support a new high velocity wind tunnel. The new building will be sized based on the commercially available tunnel selected. The scope of work for this project will include structural engineering and project management and for the proposed Flight Dynamics Research Facility. Structural design and analysis will support replacement of a 20-foot vertical spin tunnel and a 12-foot low speed tunnel with a single new tunnel with significantly higher flow velocity and flow quality.
This project explored the use of the United States Green Building Council’s (USGBC) LEED sustainable design program and parameters in relation to a multi-purpose hotel and convention center’s site stormwater collection and maintenance system. Base stormwater flow calculations exiting the site were performed according to the standard design practices supported by the City of Houston. This included utilizing a two-hour, 10-year storm as the base design for sizing and capturing 50% of the water created by the newly developed landscape through the use of an underground storage basin. Redesigning the system to achieve LEED credits, improvements to the design were made in the form of a natural wetland, green roofs, rainwater irrigation cisterns, and a permeable pavement. These improvements resulted in a negligent peak flow during the two-hour, 10-year storm. Utilizing a larger, two-hour, 100-year storm as an additional test of efficiency, the peak runoff levels were lower than those of the basis of design flows for the 10-year storm. The steps taken towards LEED certification not only lead to a removal of the underground storage basin concrete, but provided a green oasis in a city asphalt and helped improve the runoff potential in a city that continues to struggle with massive flooding.
The paper covers how mass customization or creating processes where a product can be customized on an individual level can benefit the homebuilding industry. This is achieved by implementing lean processes, managing supply chains, and using manufacturing processes to reduce cycle times and waste. These areas have to incorporate the ability to be flexible to allow for the customization.