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Assuming the ideal gas law applies, the volume of air exiting the evaporator can be calculated using the formula V2 = (V1 * T1) / T2, where V1 = 3000 ft^3, T1 = 75°F, and T2 = 55°F. Thus, the volume of air exiting the evaporator would be approximately 2400 ft^3 based on the given information.
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If 3000 ft of air is crossing an evaporator coil and is cooled from 75 F to 55 F what would be the volume of air in ft exiting the evaporator coil 2887.8 ft?
To find the volume of air exiting the evaporator coil, we first calculate the volume of air that entered: 3000 ft * (75 F - 55 F) = 60000 ft·F. The volume of air exiting is given as 2887.8 ft. Therefore, the volume of air exiting the evaporator coil is 2887.8 ft.
If 3000 ft3 of air is crossing an evaporator coil and is cooled from 75 degree Fahrenheit to 55 degree Fahrenheit what would be the volume of air in ft3 exiting the evaporator coil?
Assuming the air behaves ideally, there is no change in the volume of air passing through the evaporator coil during the cooling process. Therefore, the volume of air exiting the evaporator coil would also be 3000 ft3.
What happens to the refrigerant in an evaporator?
In the evaporator, the refrigerant absorbs heat from the surrounding air or substance, causing it to evaporate and turn into a low-pressure gas. This phase change allows the refrigerant to cool down the air passing through the evaporator coils before it is circulated back into the space being cooled.
Evaporator in a refrigeration sistem?
The evaporator in a refrigeration system is where the refrigerant absorbs heat from the surrounding air or space being cooled. As the low-pressure liquid refrigerant passes through the evaporator coils, it evaporates into a gas, cooling the surrounding area in the process. This helps to lower the temperature and maintain the desired cooling effect in the refrigeration system.
What is the purpose of an evaporator in the refrigeration cycle is to?
The purpose of the evaporator in the refrigeration cycle is to absorb heat from the space being cooled, causing the refrigerant to evaporate and turn into a gas. This process cools the air inside the space and allows the refrigerant to carry the absorbed heat to the compressor for further processing.
If 3000 ft3 of air is crossing an evaporator coil and is cooled from 75°F to 55°F, what would be the volume of air, in ft3, exiting the evaporator coil?
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If 3000 ft of air is crossing an evaporator coil and is cooled from 75 F to 55 F what would be the volume of air in ft exiting the evaporator coil 2887.8 ft?
To find the volume of air exiting the evaporator coil, we first calculate the volume of air that entered: 3000 ft * (75 F - 55 F) = 60000 ft·F. The volume of air exiting is given as 2887.8 ft. Therefore, the volume of air exiting the evaporator coil is 2887.8 ft.
If 3000 ft3 of air is crossing an evaporator coil and is cooled from 75 degree Fahrenheit to 55 degree Fahrenheit what would be the volume of air in ft3 exiting the evaporator coil?
Assuming the air behaves ideally, there is no change in the volume of air passing through the evaporator coil during the cooling process. Therefore, the volume of air exiting the evaporator coil would also be 3000 ft3.
How does an evaporator work?
an evaporator is a part of a refrigeration plant by which the refrigerant is made to boil at a much lower temperature and pressure. the idea is to extract the heat from the region which we want to cool. basically the evaporator is located at the region where the thing to be cooled is situated.
Do you have to remove the dash to replace the evaporator on 1996 Milinea Evacuated and recharged system and it cooled for less than 24 hours Supposedly it has a leak in the evaporator?
yup. however, there are some very good stop leak additives out there.
What happens to the refrigerant in an evaporator?
In the evaporator, the refrigerant absorbs heat from the surrounding air or substance, causing it to evaporate and turn into a low-pressure gas. This phase change allows the refrigerant to cool down the air passing through the evaporator coils before it is circulated back into the space being cooled.
Where in the refrigeration system is heat absorbed into the refrigerant?
The heat is released by heat exchangers in the atmosphere.
Evaporator in a refrigeration sistem?
The evaporator in a refrigeration system is where the refrigerant absorbs heat from the surrounding air or space being cooled. As the low-pressure liquid refrigerant passes through the evaporator coils, it evaporates into a gas, cooling the surrounding area in the process. This helps to lower the temperature and maintain the desired cooling effect in the refrigeration system.
What is the purpose of an evaporator in the refrigeration cycle is to?
The purpose of the evaporator in the refrigeration cycle is to absorb heat from the space being cooled, causing the refrigerant to evaporate and turn into a gas. This process cools the air inside the space and allows the refrigerant to carry the absorbed heat to the compressor for further processing.
What is the function of evaporator blower?
The function of an evaporator blower is to circulate air over the evaporator coils in an air conditioning system. This helps to facilitate the heat transfer process, where heat is removed from the air passing over the coils, leading to cooled air being distributed throughout the space. The blower also helps to maintain proper airflow and ensure efficient cooling operation.
Function of evaporator condenser expansion valve and condenser?
Condesor- cools the liquid formed gas after compressor compresses. After condensor it pass through the expansion valve, then again liquid formed gas expanses to gas form and produses cooling .this cooled gas then passes through the evaporator coils
What is chiller approach temperature?
Evaporator Approach is the difference between the evaporating refrigerant temperature - measured at the well in the evaporator -and leaving chilled water temperature.Take all readings with the water cooled chiller at full load.Condenser Approach is the difference between the liquid refrigerant temperature - as measured on the liquid line - and leaving condenser water temperature.
