Heat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG)

Heat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG)

<p align="justify">Indonesia has a huge geothermal resource potential of 28.9 GWe, which can be converted into electrical energy to meet the needs of the community through geothermal power plant. Any steam taken from geothermal wells has non-condensable gas content, thereby reducing...

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Main Author: Armeza Dani - Nim: 13113127 , Anton
Format: Final Project
Language:Indonesia
Online Access:https://digilib.itb.ac.id/gdl/view/25697
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Institution: Institut Teknologi Bandung
Language: Indonesia
id id-itb.:25697
spelling id-itb.:256972018-03-14T15:28:00ZHeat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG) Armeza Dani - Nim: 13113127 , Anton Indonesia Final Project INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/25697 <p align="justify">Indonesia has a huge geothermal resource potential of 28.9 GWe, which can be converted into electrical energy to meet the needs of the community through geothermal power plant. Any steam taken from geothermal wells has non-condensable gas content, thereby reducing the efficiency of geothermal energy utilization. Allegedly, the non-condensable gas will block the heat transfer inside the condenser. The condenser used in geothermal power plant is a spray tipe direct contact condenser. The cooling water flowing into the condenser will atomized into small drop by spray nozzle. The vapor that enters with the non-condensable gas will transfer its heat to the cooling water droplet. The heat transfer mechanism needs to be analyzed to determine the phenomenon. In this bachelor thesis, a direct condensation heat transfer model is proposed between the condensed vapor and the liquid grains covered with NCG. The influential parameters are then identified and grouped in dimensionless parameters by the Buckingham Pi method. The dimensionless numbers generated include Nu, Re, Ja, Wnc, dl/Dnc, and Prnc. Then the experimental data from spray condenser experiment by Kulic [15], Ranggana [16], and Bontozoglou [17] were processed and developed into a heat transfer correlation equation.<p align="justify"> text
institution Institut Teknologi Bandung
building Institut Teknologi Bandung Library
continent Asia
country Indonesia
Indonesia
content_provider Institut Teknologi Bandung
collection Digital ITB
language Indonesia
description <p align="justify">Indonesia has a huge geothermal resource potential of 28.9 GWe, which can be converted into electrical energy to meet the needs of the community through geothermal power plant. Any steam taken from geothermal wells has non-condensable gas content, thereby reducing the efficiency of geothermal energy utilization. Allegedly, the non-condensable gas will block the heat transfer inside the condenser. The condenser used in geothermal power plant is a spray tipe direct contact condenser. The cooling water flowing into the condenser will atomized into small drop by spray nozzle. The vapor that enters with the non-condensable gas will transfer its heat to the cooling water droplet. The heat transfer mechanism needs to be analyzed to determine the phenomenon. In this bachelor thesis, a direct condensation heat transfer model is proposed between the condensed vapor and the liquid grains covered with NCG. The influential parameters are then identified and grouped in dimensionless parameters by the Buckingham Pi method. The dimensionless numbers generated include Nu, Re, Ja, Wnc, dl/Dnc, and Prnc. Then the experimental data from spray condenser experiment by Kulic [15], Ranggana [16], and Bontozoglou [17] were processed and developed into a heat transfer correlation equation.<p align="justify">
format Final Project
author Armeza Dani - Nim: 13113127 , Anton
spellingShingle Armeza Dani - Nim: 13113127 , Anton
Heat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG)
author_facet Armeza Dani - Nim: 13113127 , Anton
author_sort Armeza Dani - Nim: 13113127 , Anton
title Heat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG)
title_short Heat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG)
title_full Heat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG)
title_fullStr Heat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG)
title_full_unstemmed Heat Transfer Equations Development of Cooling Water Droplet Direct Contact Condensation With Steam Containing Non Condensable Gas (NCG)
title_sort heat transfer equations development of cooling water droplet direct contact condensation with steam containing non condensable gas (ncg)
url https://digilib.itb.ac.id/gdl/view/25697
_version_ 1821910515844120576

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