Design And Analysis Performance of Liquid Petroleum Gases System in Residential Building; Review
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Abstract
Liquefied petroleum gases (LPG) consist of hydrocarbons obtained by refining crude oil, either from propane or butane or a mixture of the two. There are often other components such as propylene, butylene or other hydrocarbons, but they are not the main component. The study aims to review previous studies dealing with designing an LPG system to deliver gas to residential campuses and buildings. LPG is extracted from natural gas NG by several processes, passing through fractionation towers and then pressuring into CNG storage tanks. Gas contains several problems, including gas leakage through the pipes and leads to fires or explosions in LPG storage and distribution tanks, so safety conditions were taken in the design and implementation. The major results are the gas leak detector showed that rapid response to gas leakage sense, so it is recommended to place the device at a distance of 0.6-2 meters from the gas source and at a distance of 0.2 to 1 meter above the ground, and the major conclusion is new techniques for using hardware and software components must be demonstrated again that can be applied to models to show fast and effective results.
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• Matthews, G., William, and Zeissig, R., Hilmar, 2011. Residential Market for LPG, pp (11)
• Paczuski, Maciej, and Marchwiany, Marcin, 2017. Liquefied Petroleum Gas (LPG) as a Fuel for Internal Combustion Engines, pp (106-107).
• Mahalingam, A., Naayagi, T. R., and Mastorakis, E. N., 2012. Design and Implementation of an Economic Gas Leakage Detector, pp (20-22)
• Ţălu, Ştefan, 2018. Design and Optimization of Pressurized Toroidal LPG Fuel Tanks with Variable Section, pp (32)
• Enalume O.K., and Silas O., 2017. Design and Implementation of an Efficient LPG Leakage Detector, pp (20-22)
• Silva, Robson, Ana, Bruno, and Brunetto, Pedro, 2015. Cooker-Top Gas Burners (Lpg) Design Parameters Experimental Analysis, pp (1).
• Flores, Otoniel, Ronny, and Bruno, 2021. Design and Implementation of An Iot Based Lpg and Co Gases Monitoring System, pp (1)
• Kumar, Ajay; Mukesh, and Singh, Balwinder, 2016. Designing and Implementaion of Smart LPG Trolley with Home Safety, pp (185)
• Mihai and Stefan, 2018. Design and Optimization of Pressurized Toroidal LPG Fuel Tanks with Variable Section, pp (32)
• Dalaba, Maxwell, Alirigia R., and Mesenbring E., 2018. Liquified Petroleum Gas (LPG) Supply and Demand for Cooking in Northern Ghana, pp (716)
• park, J. J., and Jeon S., 2005. Design of Pyongtaek LPG Storage Terminal Underneath the Lake Namyang, pp (81)
• PRIF, 2016. LPG and Natural Gas, pp (31).
• Synáka F., Čulíka K., Rievaja V., and Gaňaa J., 2019. Liquefied petroleum gas as an alternative fuel, pp (528).
• Ryskamp R., 2017. Emissions and Performance of Liquefied Petroleum Gas as a Transportation Fuel: A Review, pp (10-21).
• Leeuwen V.R., Evans A., and Hyseni B., 2017. Increasing the Use of Liquefied Petroleum Gas in Cooking in Developing Countries, pp (3).
• New Delhi, 2018. PETROLEUM AND NATURAL GAS REGULATORY BOARD, pp (77-88)
• Cumo F., Garcia A.D., Stefanini V., and Tiberi M., 2015. Technologies and Strategies to Design Sustainable Tourist Accommodations in Areas of High Environmental Value Not Connected to The Electricity Grid, pp (22)
• Salman A.M., Ismail R.M., and Kahtan Y.Y., 2018. Optimization thickness of head type for horizontal LPG pressure vessels according to ASME, pp (581-582).
• Oda Dawood A., 2019. Static and Time History Earthquake Analysis of LPG Spherical Steel Tanks in Iraq, pp (5)