Air Cooled Condenser | ACC | Working | Applications | Parts | Dry Cooling | Types of Condensers скачать в хорошем качестве

Air Cooled Condenser | ACC | Working | Applications | Parts | Dry Cooling | Types of Condensers

Air Cooled Condenser | ACC | Working | Applications | Parts | Dry Cooling | Types of Condensers Hi This is Upendra Kumar Malla. Welcome to my channel .I wanted to provide some basic information about Mechanical engineering and Industrial safety . Watch 1200+ latest videos in playlist (    / @upendrakumarmalla   ) those videos may use full to you. Telegram group link 👇👇 https://t.me/joinchat/kBKPMSg2enQ1N2I1 App link -Google play store link https://clpdiy17.page.link/6eZ4 For Desktop / Web access - web link : https://web.classplusapp.com/login Org code: arfxv An Air Cooled Condenser (ACC) is a heat exchanger used in power plants and other industrial processes to cool and condense steam or other vaporized fluids. It's an alternative to water-cooled condensers, which require a constant source of water for cooling. ACCs are particularly useful in areas where water availability is limited or environmental regulations restrict the use of water for cooling purposes. Here's how an Air Cooled Condenser works: Steam Condensation: In power plants, steam is used to turn turbines and generate electricity. After the steam passes through the turbines, it needs to be condensed back into water so that it can be recycled through the system. The condensation process releases a large amount of heat. Heat Exchange: In an ACC, the hot vaporized fluid (steam) from the turbines is passed through tubes or coils. These tubes are arranged in banks, and a large number of these banks are typically mounted in a grid-like fashion. Air Flow: Ambient air is blown across the tubes to absorb the heat from the vaporized fluid. As the air passes over the tubes, it heats up and carries away the heat energy released during the condensation process. This causes the vaporized fluid to lose heat and condense back into a liquid state. Fan Systems: Large fans are used to create the necessary air flow. These fans are strategically placed to optimize the heat exchange process. The air flow rate, fan size, and other design factors are carefully chosen to ensure efficient heat transfer and condensation. Cooling Medium: The ambient air serves as the cooling medium in an ACC. Unlike water-cooled systems, no additional water source is required, which can be advantageous in regions where water scarcity is a concern. Heat Rejection: As the ambient air absorbs the heat from the vaporized fluid, it gets warmer and is released into the atmosphere. The condensation process effectively releases the latent heat of vaporization, which was originally absorbed to convert the fluid into vapor. Air Cooled Condensers have several advantages, including reduced water consumption, less environmental impact, and simplified maintenance compared to water-cooled systems. However, they might be less efficient in terms of heat transfer compared to water-cooled systems, especially in areas with high ambient temperatures. Therefore, the design and efficiency of an ACC depend on factors like climate conditions, specific power plant requirements, and overall system configuration. #condenser #condenserworking #evaporativecooler #evaporativecondenser #condeserclassification #surfacecondenser #highlevejetcondenser #shellandtubecondeser #powerplant #refrigeration #condenserimportance