Basic Knowledge of Cooling Towers
2025-01-04
Cooling towers are devices that use the contact between water and air and the evaporation process to dissipate waste heat generated in industrial processes or refrigeration and air - conditioning systems. In industrial production or refrigeration processes, waste heat generally needs to be removed by cooling water. A certain amount of water is drawn from natural water bodies such as rivers, lakes, and seas as cooling water. The cooling process equipment absorbs waste heat, causing the water temperature to rise, and then the water is discharged back into rivers, lakes, or seas. This cooling method is called once - through cooling. When once - through cooling conditions are not available, a cooling tower is required for cooling. The function of the cooling tower is to conduct heat exchange between the cooling water carrying waste heat and the air inside the tower, transferring the waste heat to the air and releasing it into the atmosphere.
I. Basic Working Principle of Cooling Towers - Drying
After being drawn by the fan, dry (low - enthalpy) air enters the cooling tower from the air inlet network. High - temperature water molecules with a high saturated vapor partial pressure flow towards the air with a low pressure. Hot and humid (high - enthalpy) water is sprayed into the tower from the water distribution system. When water droplets come into contact with the air, on the one hand, there is direct heat transfer between the air and the water. On the other hand, due to the pressure difference between the water vapor surface and the air, evaporation occurs under the action of pressure. Up to now, the latent heat of evaporation is carried away, taking away the heat in the water, that is, evaporative heat transfer, thus achieving the purpose of temperature reduction.
II. Working Process of Cooling Towers
Take the working process of a circular counter - flow cooling tower as an example:
Hot water from the main machine room, under a certain pressure by the water pump, passes through pipes, horizontal pipes, bent pipes, and the central pipe, and is pumped to the water distribution system of the cooling tower. The water is evenly sprayed onto the packing through the small holes on the water distribution pipes. Dry air with low enthalpy enters the tower from the bottom air inlet network under the action of the fan. When the hot water flows through the surface of the packing, it forms a water film and exchanges heat with the air. Hot and humid air with high humidity and high enthalpy is drawn out from the top, and the cooled water droplets fall into the bottom basin and flow into the main machine through the outlet pipe.
Under normal circumstances, the air entering the tower is dry air with a low wet - bulb temperature. There is a significant difference in the concentration of water molecules and the kinetic energy pressure difference between the water and the air. When the fan is operating, under the action of the static pressure in the tower, water molecules continuously evaporate into the air, becoming water vapor molecules. The average kinetic energy of the remaining water molecules will decrease, thus reducing the temperature of the circulating water.
From the above analysis, it can be seen that evaporative cooling has nothing to do with whether the air temperature (usually the dry - bulb temperature) is lower or higher than the water temperature. As long as water molecules can continuously evaporate into the air, the water temperature will decrease. However, the evaporation of water into the air will not continue indefinitely.
When the air in contact with the water is unsaturated, water molecules continuously evaporate into the air. But when the air on the water - air contact surface reaches saturation, water molecules can no longer evaporate, but are in a state of dynamic equilibrium. The number of water molecules evaporating out is equal to the number of water molecules returning from the air to the water, and the water temperature remains unchanged. It can be seen that the drier the air in contact with the water, the easier the evaporation is, and the easier it is to reduce the water temperature.
Hot water from the main machine room, under a certain pressure by the water pump, passes through pipes, horizontal pipes, bent pipes, and the central pipe, and is pumped to the water distribution system of the cooling tower. The water is evenly sprayed onto the packing through the small holes on the water distribution pipes. Dry air with low enthalpy enters the tower from the bottom air inlet network under the action of the fan. When the hot water flows through the surface of the packing, it forms a water film and exchanges heat with the air. Hot and humid air with high humidity and high enthalpy is drawn out from the top, and the cooled water droplets fall into the bottom basin and flow into the main machine through the outlet pipe.
Under normal circumstances, the air entering the tower is dry air with a low wet - bulb temperature. There is a significant difference in the concentration of water molecules and the kinetic energy pressure difference between the water and the air. When the fan is operating, under the action of the static pressure in the tower, water molecules continuously evaporate into the air, becoming water vapor molecules. The average kinetic energy of the remaining water molecules will decrease, thus reducing the temperature of the circulating water.
From the above analysis, it can be seen that evaporative cooling has nothing to do with whether the air temperature (usually the dry - bulb temperature) is lower or higher than the water temperature. As long as water molecules can continuously evaporate into the air, the water temperature will decrease. However, the evaporation of water into the air will not continue indefinitely.
When the air in contact with the water is unsaturated, water molecules continuously evaporate into the air. But when the air on the water - air contact surface reaches saturation, water molecules can no longer evaporate, but are in a state of dynamic equilibrium. The number of water molecules evaporating out is equal to the number of water molecules returning from the air to the water, and the water temperature remains unchanged. It can be seen that the drier the air in contact with the water, the easier the evaporation is, and the easier it is to reduce the water temperature.
III. Classification of Cooling Towers
IV. Composition of Cooling Towers
- Water - spraying Packing
The water (hot water) that needs to be cooled is splashed into water droplets or formed into a water film multiple times to increase the contact area and time between water and air, and promote the heat exchange between water and air. The cooling process of water mainly takes place in the water - spraying packing. - Water Distribution System
It distributes hot water evenly over the entire water - spraying packing. Whether the hot water is evenly distributed or not has a great impact on the cooling effect. If the water distribution is uneven, it not only directly reduces the cooling effect but also causes some cooling water droplets to splash and drift out of the tower. - Ventilation Equipment
In mechanical - draft cooling towers, a ventilator is used to generate the expected air flow to ensure the required cooling effect. - Air Distribution Device
Devices such as air inlets, louvers, and air guide plates are used to guide the air to be evenly distributed across the entire cross - section of the cooling tower. - Ventilation Duct
The function of the ventilation duct is to create good aerodynamic conditions, reduce ventilation resistance, and send the hot and humid air discharged from the cooling tower to a high altitude to reduce the recirculation of hot and humid air.
The ventilation duct of a mechanical - draft cooling tower is also called the air duct. The ventilation duct of a natural - draft hyperbolic cooling tower plays the role of ventilation and sending hot and humid air to a high altitude. - Water Eliminator
It separates the water droplets carried in the discharged hot and humid air from the air, reducing the loss of escaped water and the impact on the surrounding environment. - Tower Body
The outer enclosure structure of the cooling tower. The tower bodies of mechanical - draft cooling towers and natural - draft hyperbolic cooling towers are closed, which play the functions of support, maintenance, and organizing suitable airflows.
The tower body of an open - type cooling tower is open along the tower height to allow natural wind to enter the tower.
- Sump
It is located at the lower part of the cooling tower and collects the cooling water falling from the water - spraying packing. Sometimes, the sump also has a certain reserve volume to regulate the flow. - Water Transmission System
The inlet pipe sends hot water to the water distribution system. A valve is installed on the inlet pipe to adjust the water inflow of the cooling tower. The outlet pipe sends the cooled water to the water - using equipment or the circulating water pump. In the sump, a make - up water pipe, a blow - down pipe, an overflow pipe, and a drain pipe are also installed. When necessary, a connecting pipe can also be set between multiple cooling towers. - Other Facilities
Including access doors, maintenance ladders, walkways, lighting, electrical control, lightning protection devices, and flight - obstacle signs set when necessary. Sometimes, test components for the cooling tower are also set for testing needs.
The different combinations of the above - mentioned components form various types and uses of cooling towers: open drip - type cooling towers, natural - draft hyperbolic cooling towers, induced - draft (or forced - draft) counter - flow cooling towers, induced - draft cross - flow cooling towers, etc.
V. Scope of Application of Cooling Towers
Waste heat generated in industrial production or refrigeration processes generally needs to be removed by cooling water. The function of the cooling tower is to conduct heat exchange between the cooling water carrying waste heat and the air inside the tower, transferring the waste heat to the air and releasing it into the atmosphere.
For example, in a thermal power plant, the boiler heats water into high - temperature and high - pressure steam, which drives the steam turbine to do work and make the generator generate electricity. The waste steam after the steam turbine has done work is discharged into the condenser, exchanges heat with the cooling water, and condenses into water, which is then pumped back to the boiler for recycling. In this process, the waste heat of the exhaust steam is transferred to the cooling water, raising the water temperature. The cooling water carrying waste heat transfers the heat to the air in the cooling tower and is discharged into the atmospheric environment from the air duct.
The application scope of cooling towers: mainly applied in air - conditioning cooling systems, refrigeration series, injection molding, leather processing, foaming, power generation, steam turbines, aluminum profile processing, air compressors, industrial water cooling, etc. The most applications are in the air - conditioning cooling, refrigeration, and plastic chemical industries.
For example, in a thermal power plant, the boiler heats water into high - temperature and high - pressure steam, which drives the steam turbine to do work and make the generator generate electricity. The waste steam after the steam turbine has done work is discharged into the condenser, exchanges heat with the cooling water, and condenses into water, which is then pumped back to the boiler for recycling. In this process, the waste heat of the exhaust steam is transferred to the cooling water, raising the water temperature. The cooling water carrying waste heat transfers the heat to the air in the cooling tower and is discharged into the atmospheric environment from the air duct.
The application scope of cooling towers: mainly applied in air - conditioning cooling systems, refrigeration series, injection molding, leather processing, foaming, power generation, steam turbines, aluminum profile processing, air compressors, industrial water cooling, etc. The most applications are in the air - conditioning cooling, refrigeration, and plastic chemical industries.
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