The present invention relates to a fan cylinder bracing system for a cooling tower having a fan deck that extends along a longitudinal axis. The bracing system has a first ring having a first diameter wherein the first ring is located at a first position along the longitudinal axis. It also has a second ring having a second diameter wherein the second ring is located at a second position along the longitudinal axis. Finally, the cylinder bracing system has a first brace connected to the first ring and said second ring, wherein said first brace transfers loads from the first ring to the second ring.

A liquid distribution device for fluid cooling devices particularly for cooling towers comprises at least one primary distribution pipe or at least one primary distribution trough, wherein a plurality of secondary distribution pipes are connected to the at least one primary distribution pipe or the at least one primary distribution trough, wherein the secondary distribution pipes are provided with nozzles, wherein the secondary distribution pipes at least section-wise have an angular cross-section and are formed from a fiber reinforced plastic.

A cooling tower is provided with a housing containing a fan at the bottom of the tower, and a plurality of layers of water collection troughs or channels above the fan to capture water droplets sprayed downwardly from the top of the device through an evaporative cooling pad located above the collection troughs. The collection troughs extend from one side of the housing to the other in the form of a structural support for the housing and the equipment therein. The troughs have open ends which extend through the housing to discharge collected water to an adjacent vertical tank.

A method for solids removal in heat exchanger systems includes a first water flow path from a heat exchanger to a cooling tower and back to the heat exchanger, including: forming an additional path in parallel with the first path, wherein water flows from the heat exchanger to a UET reactor and back to the heat exchanger, and wherein the UET reactor including means for solids removal from the water using a partial electrolysis process. Optionally, the volumetric flow rate in the additional path is about 5% of the volumetric flow rate in the first water flow path.

A method for solids removal in heat exchanger systems includes a first water flow path from a heat exchanger to a cooling tower and back to the heat exchanger, including: forming an additional path in parallel with the first path, wherein water flows from the heat exchanger to a UET reactor and back to the heat exchanger, and wherein the UET reactor including means for solids removal from the water using a partial electrolysis process. Optionally, the volumetric flow rate in the additional path is about 5% of the volumetric flow rate in the first water flow path.

This low-pressure condenser is provided with: a pressure bulkhead which partitions the inside of the container into an upper space and a lower space; a heat transfer tube which is arranged in the upper space; and a reheater which is arranged in the lower space and which, by means of high-temperature steam flowing from the outside into the lower space, heats water which condenses in the upper space and flows into the lower space. The reheater includes multiple partition members, a receiving plate which receives water flowing downward via the partition members, and a dam which is connected to the outer peripheral edge of the receiving plate. The lower ends of the multiple partition members are below the upper end of the dam.

This low-pressure condenser is provided with: a pressure bulkhead which partitions the inside of the container into an upper space and a lower space; a heat transfer tube which is arranged in the upper space; and a reheater which is arranged in the lower space and which, by means of high-temperature steam flowing from the outside into the lower space, heats water which condenses in the upper space and flows into the lower space. The reheater includes multiple partition members, a receiving plate which receives water flowing downward via the partition members, and a dam which is connected to the outer peripheral edge of the receiving plate. The lower ends of the multiple partition members are below the upper end of the dam.

A water tower applied to the water source heat pump central air conditioner is provided, and includes a tower body, a water storage tank, an air distributing device, cooling fillers, a water distributing device, a water collector, and ventilating equipment, wherein the water storage tank is arranged at the bottom of the interior of the tower body, and the air distributing device, the cooling fillers, the water distributing device, the water collector and the ventilating equipment are sequentially arranged above the water storage tank. Furthermore, the water tower applied to the water source heat pump central air conditioner includes a plurality of return water pipes and a plurality of supply pipes; the water inlet ends of the multiple return water pipes are in connection with the return water outlets of a plurality of air conditioner main units, arranged in all storeys correspondingly.

A system and a method for promoting improved air flow through a cooling tower and reduced inner air pressure losses caused by rain in the rain zone of a cooling tower. Aerodynamic modules are mounted on the lower edge of the cooling tower shell in order to deflect the downward-flowing air about the lower edge of the tower shell and into the rain zone. The aerodynamic modules can be modularly mounted, can be replaced, and do not affect the statics of the tower shell. Aerodynamic modules can also be built on the base area to deflect the incoming air over any obstacles. Troughs or dripping elements can also promote flow by reducing the rain falling in an outer area.

A system and a method for promoting improved air flow through a cooling tower and reduced inner air pressure losses caused by rain in the rain zone of a cooling tower. Aerodynamic modules are mounted on the lower edge of the cooling tower shell in order to deflect the downward-flowing air about the lower edge of the tower shell and into the rain zone. The aerodynamic modules can be modularly mounted, can be replaced, and do not affect the statics of the tower shell. Aerodynamic modules can also be built on the base area to deflect the incoming air over any obstacles. Troughs or dripping elements can also promote flow by reducing the rain falling in an outer area.