Life cycle analysis of structural systems of residential housing units in the Philippines
In designing a house, or any structure, there are three things commonly considered by the structural engineer these are represented in the safety-serviceability-cost triangle. Safety and serviceability ensure that the structure can fulfill its intended purpose by satisfying code requirements on stre...
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oai:animorepository.dlsu.edu.ph:etd_bachelors-59062023-06-20T06:41:18Z Life cycle analysis of structural systems of residential housing units in the Philippines Arcilla, Nicolas Ryan D. Ong, Janelle Kathryn P. In designing a house, or any structure, there are three things commonly considered by the structural engineer these are represented in the safety-serviceability-cost triangle. Safety and serviceability ensure that the structure can fulfill its intended purpose by satisfying code requirements on strength, ductility, and deflections. Addressing economy, on the other hand, requires value engineering to produce an optimum design with reasonable cost. However, the triangle is increasingly found to be incomplete. There is the question of environmental impacts the structure may bear on society. But what parameter may be used to guide structural designers to make their structure "greener"? This paper proposes the use of a "Structural Sustainability Index (SSI)", a single-score based on the life Cycle Assessment (LCA) framework. The SSI was derived from five environmental impacts, whose respective weights were determined from a survey of Civil Engineering professionals. The impacts and their weights are: Global Warming Potential (36%), Ocean acidification (10%), Human Toxicity (12%), Abiotic Material Depletion (16%), and Energy Use (26%).";"The concept was applied to low-cost housing units in the Philippines. Four models with approximately 60 sqm floor area were investigated. The structural systems of these houses are conventional reinforced concrete modular block system, I beam, and modified system. Among the four, the I beam house incurred the lowest SSI of 0.682 while the conventional had the greatest at 0.986. The I beam, however, was found to have the largest contribution in abiotic material depletion due to heavy steel usage. This could be lessened through recycling of steel, as the manufacturing stage was found to contribute the most damage. Significant improvements were made in all impact categories when converting from a conventional to a modified system using T-joints and wall stiffeners, for a total of 9.87% decrease in SSI. Costs likewise decreased. With the SSI and LCA framework, sustainability concerns can be quantified by structural engineers and significant improvements can be made in designing." 2013-01-01T08:00:00Z text https://animorepository.dlsu.edu.ph/etd_bachelors/5403 Bachelor's Theses English Animo Repository Structural analysis (Engineering) Sustainable buildings—Design and construction Civil Engineering Structural Engineering |
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Structural analysis (Engineering) Sustainable buildings—Design and construction Civil Engineering Structural Engineering Arcilla, Nicolas Ryan D. Ong, Janelle Kathryn P. Life cycle analysis of structural systems of residential housing units in the Philippines |
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In designing a house, or any structure, there are three things commonly considered by the structural engineer these are represented in the safety-serviceability-cost triangle. Safety and serviceability ensure that the structure can fulfill its intended purpose by satisfying code requirements on strength, ductility, and deflections. Addressing economy, on the other hand, requires value engineering to produce an optimum design with reasonable cost. However, the triangle is increasingly found to be incomplete. There is the question of environmental impacts the structure may bear on society. But what parameter may be used to guide structural designers to make their structure "greener"?
This paper proposes the use of a "Structural Sustainability Index (SSI)", a single-score based on the life Cycle Assessment (LCA) framework. The SSI was derived from five environmental impacts, whose respective weights were determined from a survey of Civil Engineering professionals. The impacts and their weights are: Global Warming Potential (36%), Ocean acidification (10%), Human Toxicity (12%), Abiotic Material Depletion (16%), and Energy Use (26%).";"The concept was applied to low-cost housing units in the Philippines. Four models with approximately 60 sqm floor area were investigated. The structural systems of these houses are conventional reinforced concrete modular block system, I beam, and modified system. Among the four, the I beam house incurred the lowest SSI of 0.682 while the conventional had the greatest at 0.986. The I beam, however, was found to have the largest contribution in abiotic material depletion due to heavy steel usage. This could be lessened through recycling of steel, as the manufacturing stage was found to contribute the most damage. Significant improvements were made in all impact categories when converting from a conventional to a modified system using T-joints and wall stiffeners, for a total of 9.87% decrease in SSI. Costs likewise decreased.
With the SSI and LCA framework, sustainability concerns can be quantified by structural engineers and significant improvements can be made in designing." |
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Arcilla, Nicolas Ryan D. Ong, Janelle Kathryn P. |
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Arcilla, Nicolas Ryan D. Ong, Janelle Kathryn P. |
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Arcilla, Nicolas Ryan D. |
title |
Life cycle analysis of structural systems of residential housing units in the Philippines |
title_short |
Life cycle analysis of structural systems of residential housing units in the Philippines |
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Life cycle analysis of structural systems of residential housing units in the Philippines |
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Life cycle analysis of structural systems of residential housing units in the Philippines |
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Life cycle analysis of structural systems of residential housing units in the Philippines |
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life cycle analysis of structural systems of residential housing units in the philippines |
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2013 |
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