A cooling device for cooling a fluid comprises a vertical cooling tower, into an upper area of which the fluid to be cooled is fed and from a lower area of which the cooled fluid is discharged. The fluid in the cooling tower is cooled by a cooling gas flowing from the bottom to the top. At least one installation in which the fluid is conducted is provided in the gas space of the cooling tower through which cooling gas flows. Each installation comprises at least one fluid channel that is separated at least in part from the gas space of the cooling tower by a fluid-tight membrane wall that is permeable to vapor on both sides.

A cooling device for cooling a fluid comprises a vertical cooling tower, into an upper area of which the fluid to be cooled is fed and from a lower area of which the cooled fluid is discharged. The fluid in the cooling tower is cooled by a cooling gas flowing from the bottom to the top. At least one installation in which the fluid is conducted is provided in the gas space of the cooling tower through which cooling gas flows. Each installation comprises at least one fluid channel that is separated at least in part from the gas space of the cooling tower by a fluid-tight membrane wall that is permeable to vapor on both sides.

The invention relates to an improved cooling apparatus for swimming pools including an inlet for water and an outlet for returning the water with a body between the inlet and outlet, with a reservoir for water contained within. A cooling arrangement associated with the body is included, the cooling arrangement able to act upon and cool the water introduced through the inlet. Further a water control apparatus, associated with the cooling arrangement is included, the water control apparatus including a high level valve and a low level valve, whereby the cooled water in the reservoir is returned through the outlet when the water level in the reservoir is above the lower level valve, and water enters the inlet only when the water level in the reservoir is below the high level valve. The invention also relates to variants thereon and methods of use.

A wet surface air cooler (WSAC), including a tube bundle having a process medium therein, a first inlet, a nozzle assembly positioned adjacent to the first inlet for spraying water over the tube bundle to cool the process medium, an outlet, a fill section spaced from the tube bundle and positioned directly below the outlet, a second inlet provided in an outer wall of the WSAC and positioned below the fill section, the second inlet being configured to provide air from outside the WSAC to the fill section, a fan assembly for causing cause air to flow through the inlet, then past the tube bundle, to be mixed with air flowing through the second inlet, and out the outlet, and a basin extending an entire width of the WSAC for receiving water sprayed from the nozzle assembly.

A single inlet/single outlet modular counterflow cooling tower having two heat transfer sections installed atop two cold water basin sections and below three fan sections, each heat transfer section having its own water distribution system and draining into its own distinct cold water basin section. The water distribution system can provide flow over both heat transfer sections or over only a single section. The center fan support section supports the mechanical drive system for the fan and has a sealing plate at its bottom for sealing the gap between the two heat transfer sections.

A single inlet/single outlet modular counterflow cooling tower having two heat transfer sections installed atop two cold water basin sections and below three fan sections, each heat transfer section having its own water distribution system and draining into its own distinct cold water basin section. The water distribution system can provide flow over both heat transfer sections or over only a single section. The center fan support section supports the mechanical drive system for the fan and has a sealing plate at its bottom for sealing the gap between the two heat transfer sections.

A fill pack includes a first fill sheet defining an air intake edge, an air exit edge and an airflow axis extending between the air intake edge and the air exit edge. The first fill sheet defines a first flute section having a first inlet end, a first outlet end and a first peak extending between the first inlet end and the first outlet end. A second fill sheet defines a second flute section having a second inlet end, a second outlet end and a second peak extending between the second inlet end and the second outlet end. The first peak extends relative to the second peak such that a first flute portion defined by the first and second flute sections has a cross-sectional shape that changes between the first and second inlet ends and the first and second outlet ends.

Systems and methods that involve distributing water droplets onto a media, particular but nonlimiting examples of which include systems and methods for exchanging heat between process water and air in an evaporative cooling system that includes media with a plurality of individual elements each having a surface. The surfaces of at least some of the individual elements individually have a static electrical charge, and the static electrical charges are different among the surfaces of the individual elements.

A fill pack includes a first fill sheet defining an air intake edge, an air exit edge and an airflow axis extending between the air intake edge and the air exit edge. The first fill sheet defines a first flute section having a first inlet end, a first outlet end and a first peak extending between the first inlet end and the first outlet end. A second fill sheet defines a second flute section having a second inlet end, a second outlet end and a second peak extending between the second inlet end and the second outlet end. The first peak extends relative to the second peak such that a first flute portion defined by the first and second flute sections has a cross-sectional shape that changes between the first and second inlet ends and the first and second outlet ends.

In one aspect, a heat exchanger system is provided that includes a cooling system and a sensor configured to detect a variable of the cooling system. The heat exchanger system includes processor circuitry configured to provide the variable and a plurality of potential operating parameters of the cooling system to a machine learning model representative of the cooling system to estimate at least one of energy consumption, water usage, and chemical usage for the potential operating parameters. The processor circuitry is further configured to determine, based at least in part on the estimated at least one of energy consumption, water usage, and chemical consumption, for the potential operating parameters, an optimal operating parameter of the cooling system to satisfy a target optimization criterion.