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Commercialization for Innovative Products in the Residential Construction IndustryMcCoy, Andrew P. 09 September 2008 (has links)
This work presents the development of a new framework for the commercialization of innovative products in the residential construction industry. It is the aim of this work to identify commercialization decisions, actions, risks, barriers and accelerators specific to the residential construction industry market that will increase the acceptance of product innovations for those developing them.
Commercialization is broadly defined as the process of developing a business enterprise from an idea, through feasibility and implementation, to its acceptance into a market (USDOE 1999, Goldsmith 2003). Commercialization frameworks describe the concurrent decisions and actions along the innovation development process, optimizing all of the technical and business decisions required for a successful introduction to the marketplace. Successful commercialization frameworks serve as a form of development plan, promoting solutions to questions and problems that arise along the development path.
This research derives such a framework for the commercialization of innovative products and makes it specific to residential construction through the following tasks:
1. Understanding standard terminology: defining innovation and commercialization as they relate to this work.
2. Creating a lens for the unique nature of commercialization in this industry: deriving a commercialization framework (matrix) from the research literature in business, construction, and concurrent engineering, capable of accepting later alterations.
3. Understanding the manufacturer's role and risks: conducting case study interviews for fifteen innovative residential construction products that specify important tasks, risks and benefits for commercialization.
4. Understanding the role, risks and benefits of builders, as users of innovation: comparing case studies and workshop surveys of many residential construction industry players that focus on the builder to establish parameters for the innovation commercialization matrix.
5. Linking both manufacturer and builder: comparing manufacturer commercialization best-practices with builder adoption patterns for innovative products over time. / Ph. D.
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Methodology for the Visual Inspection of Selected Engineered Wood Products and Connector Hardware for Prescriptive Non-Compliance at the Pre-Drywall Stage of Residential ConstructionBouldin, John Conrad 16 August 2011 (has links)
The use of engineered wood products (EWP) in residential construction has increased in recent years. Most specifications for the installation of these components are found in proprietary manufacturer literature rather than in the building code. Although some home inspections include EWP prescriptive compliance, very little applied and academic literature addresses this practice. This lack of practical information and the lack of standardized inspection methods can result in undetected non-compliant EWP installations that fail to meet the minimum safety provisions of the building code.
The goal of this project was to develop a visual inspection methodology, associated knowledge base, and software application for the inspection of EWPs and connector hardware (CH) in new residential construction at the pre-drywall stage. The methodology was based upon subject matter expert (SME) inputs and validation was derived from the use of a modified Delphi method that was able to the gather, collate, refine, and validate the research process and outputs based on the expertise of the subject matter experts. The concept of high face validity was used to establish project validity.
Installation problems with EWPs and CH were noted by the SMEs partly because the use and installation instructions for proprietary products are not found in building codes. Building code officials (BCO) and home inspector (HI) SME responses indicated a need for a methodology and software to aid in the inspection process. Although authoritative reference materials for prescriptive installation are available, the scope of material is not consistent between manufacturers, and is presented in different formats for different brands. The developed software application provides ready access to reference materials needed for EWP and CH installations.
No widely accepted inspection methodology is available, although the HI SMEs used systematic inspection methods. Inspection methods such as the top-down method and sighting along the patterns of repetitious framing elements can improve the detection of non-compliant installations. BCO and HI SMEs identified both component-specific and zone-specific techniques as a part of the systematic inspection methodology. Definable high risk areas for each EWP and CH were identified and the associated inspection methods may help the inspector reduce the incidence of undetected problem areas. Knowledge of the high-risk areas may also enhance the inspection.
The developed software application was found to be a useful inspection tool. BCO and HI SMEs determined that functions of the computer software necessary for use included ease of use, onboard reference materials, specific inspection techniques, prepared comments, and technical illustrations. / Ph. D.
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Establishing a Commercialization Model for Innovative Products in the Residential Construction IndustryMcCoy, Andrew P. 05 June 2007 (has links)
Throughout the world, innovation is viewed as a critical factor in the future health of the construction industry. There is universal interest in successful commercialization of innovative construction products. This thesis focuses on the US construction industry's ability to successfully commercialize innovative products. US small, limited-resource innovators will be key players in this success. Recent failures of entrepreneurial business ventures in the commercialization of such products would benefit from a unique model for construction industry commercialization. The general approach is through an identification of accelerators for previously commercialized products, which are incorporated into a generic commercialization model. This process consists of five stages that are presented in this work: defining commercialization and innovation through literature for the residential construction industry; reviewing literature from other-industry commercialization models; establishing a new generic model (or framework) for innovative construction products from such literature; capturing qualitative and quantitative construction data from industry experts regarding actions that facilitate commercialization; populating specific cells of the generic model deemed relevant through this industry data, resulting in the accumulation of important cells, actions, and sequences. This work uses industry cases to present challenges specific to the construction industry and its products. It is limited to five such cases and their important data for residential construction innovation commercialization success. / Master of Science
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Development of the Full Height Truss FrameGordon, Joel Christopher 20 May 2005 (has links)
The full height truss frame (FHTF) is an exciting new residential framing system in response to the need for low floor-to-floor steel construction. The FHTF has the potential to provide low floor-to-floor heights, a column free first floor area, an integrated frame that uses the entire height to resist loads, and the capacity to resist both gravity and lateral loads.
Because of its configuration, the full structural height can be used to resist loads. A FHTF is made up of stacked floor trusses that result in one full height truss spanning the entire width of the building. The FHTF is constructed in a conventional manner one floor at a time. The strength, inertia, and truss height will increase as each floor is added. Therefore, the construction sequence will affect the final stresses in the members.
The purpose of this thesis was to analyze and design two prototype FHTFs, to compare the economy of the prototypes with similar staggered truss frames, and to develop an approximate method to calculate staged member stresses. Each prototype was analyzed using a computer program and designed according to the 2001 American Institute of Steel Construction Load and Resistance Factor Design. The prototypes were used to assess the strength and serviceability of the structures, and the results of the staged analysis were used to validate the numerical method developed to approximate a staged loading sequence based on the non-staged dead load results.
The results of the analysis and design of the prototypes was the initial step in confirming the viability of the FHTF for use in the residential multistory market. FHTFs can be designed with preexisting procedure, and are capable of offering low floor-to-floor heights. The prototypes exhibited excellent lateral stiffness against wind loads. The numerical method for estimating the staged dead load accurately approximated the results of the analysis preformed by ETABS. The numerical method can be used to simulate a variety of sequences in order to optimize the stages. Lastly, the FHTF was shown to be competitive with the staggered truss systems in terms of material usage, fabrication, and construction.
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Framework for rating the sustainability of the residential construction practiceMah, Don Unknown Date
No description available.
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Framework for rating the sustainability of the residential construction practiceMah, Don 06 1900 (has links)
Sustainable development issues and environmental concerns continue to gain headlines as demand within Canada’s residential construction industry escalates. Current construction practices adhere to traditional methods of construction, with inherent weaknesses such as high labour costs, negative environmental impact during and after construction, and minimal technological advancement. Many programs exist to rate building environmental performance, including Leadership in Energy and Environmental Design (LEED) and Built Green, which are primarily performance-based, not practice-based evaluations. Considerable research has supported these performance ratings; however, there has been very little research in construction practice ratings. Hence, the purpose of the research presented in this thesis is to bridge this gap by proposing a construction practice rating program in order to challenge builders’ claims of being sustainable. Although rating programs should include measurements of both performance and practice—given that great performance does not equal great practice, particularly if the standard of performance achievement is low, current programs are based on performance alone. The goal of this thesis is to enhance the sustainability of the residential construction practice through the incorporation of sustainability evaluation rating tools. To achieve this goal, a framework has been developed which encompasses sustainability rating tools that include an integrated construction practice rating program, an application of Building Information Modeling (BIM) for carbon dioxide (CO2) emissions quantification, and implementation of a mathematical linear optimization model as a tool that minimizes cost while incorporating user-defined preferences and numerous environmental criteria under a green building rating system. CO2 emissions of various house construction stages are quantified and utilized in a 3D BIM. Application of the proposed framework is demonstrated in a case study with findings that show the weak results of sustainability ratings for a particular home builder. Hence, the findings in this research demonstrate a residential builder’s ability to measure his sustainability efforts and enhance construction practices based on a rating analysis. The introduction of BIM for quantifying emissions in the construction process is found to be of significant value. / Construction Engineering and Management
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Sustainability assessment framework for the residential construction sector in the UKCuellar Franca, Rosa Marisa January 2013 (has links)
The residential construction sector in the UK plays an important role in society’s wellbeing as it provides shelter, employment and promotes economic growth. However, the sector has been identified as a large contributor to climate change, resource depletion and is associated with different socio-economic issues such as fuel poverty and house affordability. The residential construction sector is growing quickly due to a high housing demand, as will the associated impacts unless significant changes are made. Several studies have assessed the environmental impacts of the residential construction sector, while the social and economic aspects of sustainability are often ignored but are equally important for sustainable development. This thesis presents a sustainability assessment framework capable of addressing the environmental, economic and social issues of the residential construction sector supply chain, using a life cycle approach in order to contribute toward an improved understanding of the current and future trends in the sector.The methodology developed has been applied to the residential construction sector in the UK and demonstrated through three case studies of conventional, passive and zero-carbon houses as well as a sustainability assessment at the sectoral level. The main stakeholders identified here are construction companies and workforce, home owners and occupiers, suppliers, local authorities and the government. The main sustainability issues are resource depletion, waste generation, environmental impacts such as global warming (GWP), ozone depletion, house price and affordability, contribution to GDP, provision of employment, health and safety, impact on local communities and business ethics. The assessment tools used to assess the environmental and economic sustainability are Life Cycle Assessment (LCA) and Life Cycle Costing (LCC), respectively. Social sustainability has been assessed using different social sustainability indicators applicable to the residential construction sector. LCA results indicate that zero-carbon houses have the lowest GWP of the three house types considered, being 71% lower than for the conventional house, compared to a 59% reduction for passive houses. However, passive houses have a better overall environmental performance as they have the lowest impacts for most environmental impact categories. LCC results, on the other hand, indicate that the total life cycle costs for zero-carbon houses are 21% higher than for conventional houses because of the additional cost of renewable technologies, while for passive houses costs are comparable to conventional houses. At a sectoral level, zero-carbon houses can achieve reductions of 13% of the sector’s annual GWP compared to conventional houses, however this will cost the residential construction sector an additional £3 billion per year. The construction of passive houses will cost an additional £1 billion per year compared to conventional houses but can help by reducing the sector’s annual GWP by 10%.This study shows that the current state of the housing sector is environmentally unsustainable and urgent changes must be made in the way houses are constructed and managed. However, the residential construction sector must overcome many socio-economic barriers before introducing low-carbon houses on a large scale.
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Evaluating the Impacts of Hurricane Maria on the Residential Construction Industry in Puerto Rico and the Effectiveness of Reconstruction EffortsWells, M. Bradley 16 June 2020 (has links)
In September of 2017, Hurricane Irma and Hurricane Maria, both category 5 hurricanes, swept across the Caribbean, including the U.S. Territory island of Puerto Rico. These two storms, particularly Hurricane Maria, caused catastrophic damages from high winds and flooding to the island paradise. This research investigates the direct effects that Hurricane Maria had on the residential construction industry within Puerto Rico and evaluates how to better prioritize and manage these types of efforts in the future. This research was initiated to identify challenges and opportunities that have been encountered within the Puerto Rican construction industry during the first year of reconstruction, post-Hurricane Maria. Residential structures that were built using current building codes experienced minimal storm damage. Many of the damaged residential structures, on the other hand, were made up of informal construction, predominantly using light wood framing methods. Unfortunately, homes built using informal construction practices were not insured nor eligible for government rebuilding assistance. Therefore, these damaged structures will more than likely be rebuilt using informal building practices again. Other immediate challenges faced by the construction industry included finding skilled labor and creating access to resources. The results of this research can be used to help prioritize reconstruction efforts and provide best practices following other similar disasters that will inevitably occur in the future. This research is unique in that it specifically targets the construction industry's experience and ultimately the ability to increase the effectiveness of the critical role the construction industry plays in rebuilding efforts.
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The Utilization of Light Gauge Steel in Residential Construction on the State of UtahPerkins, Matthew Zaugg 19 March 2009 (has links) (PDF)
This thesis researched why light gauge steel framing members are not used more in single-family residential construction. A survey was designed to extract information from licensed contractors in Utah on uses of light gauge steel framing members in residential homes. The purpose of the research was to discover what Utah builder's perception was concerning light gauge steel framing. Also, the researcher tried to learn a little about the contractors to see if there was a correlation between contractors that used light gauge steel and those that did not. Names of licensed general building contractors and residential contractors and their contact information were acquired from the State of Utah's Department of Professional Licensing. A random sample of the licensed contractors was selected. They were contacted by mail and telephone and invited to participate in a survey. The researcher discovered that light gauge steel was used in a very limited amount. The respondents seemed build using traditional methods, namely lumber. They were unfimiliar with light gauge steel and its properties, as well as the benefits and disadvantages of light gauge steel.
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Best Practices for Dealing with Price Volatility in Utah's Residential Construction MarketSmith, James Packer 30 June 2010 (has links) (PDF)
Price volatility is a consistent problem that affects all of the parties involved in the residential construction industry. The myriad factors that can have an impact on construction costs are such that it is extremely hard to anticipate upcoming changes in a timely and accurate way. When prices fluctuate during the course of a project, estimates become erroneous and completion of projects within expected budgets becomes difficult. Increasing prices typically leave contractors with the majority of the risk burden due to the enforceability of contracts that are likely to have been executed months prior. The risk associated with the owner's role primarily exists when prices decrease and they are required to make payments on pre-existing contracts that do not accurately reflect "actual" costs at the time of construction. The risk of price volatility needs to be managed. Numerous methods have been developed for managing the risk of price volatility. The various methods available are implemented based on the parties involved, the types of contracts being used, and the existing market conditions. Typical practices transfer the risk of price volatility to other involved parties, be it the owner, the contractor, subcontractors, or suppliers. However, no method has proven completely effective at removing the risks associated with price volatility. Involved parties need to utilize a combination of best practices to protect themselves. They need to coordinate and communicate with the other parties to ensure that the risk of price volatility is appropriately accounted for and managed throughout the construction process.
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