The invented system used in wet cooling tower, restore outlet fog of cooling tower into collection basin and consequently cooling water cycle. This invention comprises three main components; pump and its pertaining piping, waterfall and micron fog eliminator. In the first stage, the air containing fog is passed through a waterfall before exhausting. This action causes some portions of fog to condensate and fall down, remaining droplets of the fog grow and together with air cross the fog eliminator blades. Fog's droplets are entrapped between blades, leave the air, and restore to the tower. Therefore, humidity of exhausted air from tower will be effectively reduced.

The invented system used in wet cooling tower, restore outlet fog of cooling tower into collection basin and consequently cooling water cycle. This invention comprises three main components; pump and its pertaining piping, waterfall and micron fog eliminator. In the first stage, the air containing fog is passed through a waterfall before exhausting. This action causes some portions of fog to condensate and fall down, remaining droplets of the fog grow and together with air cross the fog eliminator blades. Fog's droplets are entrapped between blades, leave the air, and restore to the tower. Therefore, humidity of exhausted air from tower will be effectively reduced.

A cooling system (20) includes a media exchanger (50), a cooling section (22), and a cooling circuit (120) for circulating a cooling fluid (130) between the media exchanger (50) and the cooling section (22). The media exchanger (50) receives outside air (38) and the cooling section (22) receives return air (32) from and interior space (34). When the cooling fluid (130) circulates into the cooling section (22) via the cooling circuit (120), the temperature of the return air (32) is reduced through indirect heat transfer between the cooling fluid (130) and the return air (32) to produce conditioned air (84). The conditioned air (84) is provided as supply air (46) into the interior space (34). When the cooling fluid circulates into the media exchanger via the cooling circuit, the temperature of the cooling fluid is reduced through direct heat transfer between the cooling fluid and the outside air.

A heat exchange system includes a first heat exchanger subassembly, a second heat exchanger subassembly, a first nozzle configured to spray fluid at the first heat exchanger subassembly, and a second nozzle configured to spray fluid at the second heat exchanger subassembly. The heat exchange system further includes memory storing controller-executable instructions and a controller configured to execute the instructions, which cause the controller to activate the first nozzle when an outdoor temperature is below a threshold temperature, and activate the first nozzle and the second nozzle when the outdoor temperature is above the threshold temperature.

There is provided a system and method for collecting water droplets from an airflow of a cooling tower (8) through condensation of water vapour using an electrostatic separator (20), wherein the electrostatic separator is a single unit electrostatic separator (20) or a multi-unit electrostatic separator. The method for water particles collection from the exhaust airflow of a cooling tower primarily comprises condensing water vapour into large water droplets. It is experimentally proved that electrostatic separation solves the problem of visible plume pollution, and blow down decreased since collected water flows back to the circulating water. Additionally, electrostatic separation results in small pressure drop of the cooling tower (8).

The automatic reset of an evaporative cooling water dissolved solids set point based on detection of water softener performance is provided. A controller has a sensor, or is given an input signal, which confirms that the softener is operating properly. Positive confirmation of water softener performance allows the controller to maintain a user specified high total dissolved solids set point in the evaporative cooling water. Should a failure of the softener be detected, the controller then maintains a user specified lower total dissolved solids set point.

An evaporative cooling system includes an inlet, an outlet, a cooling module and a fan. The inlet is for accepting hot air and the outlet is for expressing air that has a temperature that is lower than the hot air. The cooling module is positioned in the vicinity of the inlet and incorporates a substantially vertical evaporative media and a spray nozzle positioned at a bottom end of the evaporative media. The spray nozzle sprays water upwardly and air flow from the fan causes the water from the spray nozzle to wet the evaporative media.

An evaporative cooling system includes an inlet, an outlet, a cooling module and a fan. The inlet is for accepting hot air and the outlet is for expressing air that has a temperature that is lower than the hot air. The cooling module is positioned in the vicinity of the inlet and incorporates a substantially vertical evaporative media and a spray nozzle positioned at a bottom end of the evaporative media. The spray nozzle sprays water upwardly and air flow from the fan causes the water from the spray nozzle to wet the evaporative media.

A method and apparatus for inspecting cooling tower fill pack to detect the presence of fouling, wherein the method comprises using ground penetrating radar (GPR). The method comprises transmitting GPR to the fill pack and detecting reflected radar signals from the fill pack. A method of cleaning fouling from a cooling tower, comprising the steps of: inspecting the cooling tower fill pack with ground penetrating radar (GPR); identifying those parts of the fill pack in which unacceptable levels of fouling are present; and cleaning the parts so identified is also presented.

A method and apparatus for inspecting cooling tower fill pack to detect the presence of fouling, wherein the method comprises using ground penetrating radar (GPR). The method comprises transmitting GPR to the fill pack and detecting reflected radar signals from the fill pack. A method of cleaning fouling from a cooling tower, comprising the steps of: inspecting the cooling tower fill pack with ground penetrating radar (GPR); identifying those parts of the fill pack in which unacceptable levels of fouling are present; and cleaning the parts so identified is also presented.