The present disclosure evaporation panel systems including plurality of evaporation panels, wherein a first evaporation panel and a second evaporation panel of the plurality of evaporation panels each include evaporation shelves and support columns to support and separate to the evaporation shelves. At least a portion of the support columns include evaporation fins so that wastewater is loadable along the support column. The first evaporation panel and the second evaporation panel in this example are releasably connectable to one another to form a sub-assembly.

An evaporation panel can include a first evaporation shelf including a first upper surface and a first lower surface, a second evaporation shelf positioned beneath the first evaporation shelf and having a second upper surface, and a support column disposed between the first evaporation shelf and the second evaporation shelf. In this example, the support column can include an evaporation fin.

A wastewater evaporative separation system can include an evaporation panel assembly having a plurality of individual evaporation panels laterally and releasably joined together, the evaporation panel assembly configured for receiving wastewater from a body of wastewater and evaporating water therefrom as the wastewater cascades down the evaporation panel assembly and contaminants become more concentrated. The system also includes a wastewater delivery system fluidly associated with the body of wastewater with a fluid directing assembly delivering the wastewater from the body of wastewater to an upper portion of the evaporation panel assembly.

An improved water management system with improved airflow distribution for counterflow evaporative heat exchangers is provided. Such heat exchangers include open cooling towers, closed circuit cooling towers, and evaporative condensers. The improved water management system eliminates water splash out and the noise associated with water splashing. Further when the fan assemblies are located below the evaporative heat exchanger, the improved water management system keeps the fans dry and prevents freezing in subzero climates.

A cooling tower includes a tower casing, a pumping device, a water storage tank, at least one cooling assembly and a fan unit. The cooling assembly includes a first multiple-layer cooling unit comprising a first water collection basin, a first fill material unit provided underneath the first water collection basin, and a first water receiving basin provided underneath the first fill material unit and connected to the water storage tank. The second multiple-layer cooling unit includes a second water collection basin connected to the water storage tank, and a second fill material unit provided underneath the second water collection basin. The cooling water in the second water collection basin is arranged to be distributed on the second fill material unit. The water flowing in the second water collection basin is collected in the water storage tank.

An air conditioning tower includes a tower casing, a compressor provided in the tower casing, a heat exchanger provided in the tower casing and connected to the compressor, an evaporative cooling system which includes at least one multiple-effect evaporative condenser, and a centrifugal fan. The multiple-effect evaporative condenser includes a pumping device, a first cooling unit, a second cooling unit, and a bottom water collecting basin. The first cooling unit includes a first water collection basin, a plurality of first heat exchanging pipes, and a first fill material unit. The second cooling unit includes a second water collection basin, a plurality of second heat exchanging pipes, and a second fill material unit.

An indirect evaporative cooling system includes a frame, a heat exchanger core, a supply fan to move indoor return air inside the heat exchanger core, and an outdoor exhaust fan supported by the frame to draw outdoor air over the heat exchanger core in a direction perpendicular to the indoor return air. The system further includes a water spray system positioned above the heat exchanger core to spray water over the heat exchanger core, and a water collection and management system disposed below the heat exchanger core to collect water sprayed onto the heat exchanger core. The water collection and management system includes a water basin configured to contain fluid. The water basin is configured to include an operational water volume and a water reserve volume which together define a total usable water volume, and includes a water height set point to define the water reserve volume.

An improved water management system with improved airflow distribution for counterflow evaporative heat exchangers is provided. Such heat exchangers include open cooling towers, closed circuit cooling towers, and evaporative condensers. The improved water management system eliminates water splash out and the noise associated with water splashing. Further when the fan assemblies are located below the evaporative heat exchanger, the improved water management system keeps the fans dry and prevents freezing in subzero climates.

The present invention is directed to a cooling tower that has a cooling tower structure having fill material supported by the cooling tower structure and configured to receive heated process fluid and a motor mounted to the cooling tower structure. The motor has a casing and a rotatable shaft and is sealed to prevent fluids, moisture, foreign particles and contaminants from entering the casing. A fan is connected to the rotatable shaft of the motor. Rotation of the rotatable shaft rotates the fan thereby inducing an upward moving mass flow of cool air through the fill material. A basin is attached to the cooling tower structure for collecting cooled fluid. A fluid distribution system distributes the cooled fluid in the basin. The fluid distribution system has a pumping device to pump cooled fluid from the basin, fluid piping to receive the pumped cooled fluid and fluid spray devices fluidly connected to the fluid piping for spraying fluid on the casing of the motor so as to transfer heat of the casing to the fluid.

In a method for supplying cooling water to a condenser under conditions where an evaporation rate of the cooling water is low during a certain time and is higher during other times, cooling water is delivered from a body of water underlying a cooling tower to the condenser. During the certain time when the evaporation rate of the cooling water is low, a level of the water in the body of water is controlled to a value such that a concentration of a contaminant in the body of water is low, and such that the temperature of the water in the body of water throughout the other times will assure a desired condensate temperature in the condenser throughout the other times. Then, a level of the water in the body of water during the other times is controlled to a value maintaining the low concentration of a dissolved solid and ions.