its the amount of water or any other high volatile substance evaporated ( in kg/hr)
why is a multicircuit evaporator used
To calculate the capacity in megawatts of a 400 kV power line, you need to consider the current carrying capacity of the line. This is typically based on factors such as conductor size, ambient temperature, and the type of insulation used. Once you have the current carrying capacity, you can use the formula P = V x I to calculate the power capacity in megawatts, where P is power in MW, V is voltage in kV (400 kV in this case), and I is current in amperes.
During the defrost cycle of a forced draft low temperature evaporator, the evaporator fan would typically be turned off to prevent warm air from interfering with the defrost process and to help the coil achieve proper defrosting temperatures.
The capacity of a container can be measured by determining the maximum amount of liquid or material it can hold. This can be done by filling the container with a known quantity of water and measuring the volume, or by using the container's dimensions to calculate its capacity based on its shape.
To calculate the chilled water coil capacity using the airside performance, you would divide the airside thermal capacity by the ADP (Approach Design Point) temperature difference. This will give you the required chilled water flow rate to meet the cooling load of the airside system.
To calculate the size of an evaporator, you need to determine the desired cooling capacity, which is typically measured in BTUs or kilowatts. This involves assessing the heat load that needs to be removed from the system, considering factors such as temperature differences, fluid flow rates, and the properties of the refrigerant. Once the cooling capacity is established, you can use the appropriate formulas or manufacturer's specifications to select the evaporator surface area and design necessary to achieve that capacity efficiently. Additionally, factors like the type of evaporator (finned-tube, shell-and-tube, etc.) and operating conditions must be considered.
The factors that affect the heat transfer capacity of an evaporator include the surface area available for heat transfer, the temperature difference between the refrigerant and the surrounding air, the airflow over the evaporator coils, the type of refrigerant used, and the cleanliness of the evaporator coils. Additionally, factors like humidity levels and system design can also impact the heat transfer capacity of an evaporator.
Heat Capacity Ratio "C" is Zero for both Condensor & Evaporator
The saturation. Pressure of the low side of system
the system capacity is max out
how to calculate the embroidery machine capacity and Embroidery factory capacity and efficiency.
how to calculate injection molding m/c capacity
I want to know how to calculate the Capacity (Erglang) of one BSC in GSM
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i want to know how to calculate FVC....
machine capacity=looknath/rupesh *100
Lowering the airflow over an evaporator can reduce the rate at which heat is absorbed from the surrounding air, impacting the cooling efficiency of the system. This may lead to decreased cooling capacity, lower energy efficiency, and potential issues with frost or ice buildup on the evaporator coils.