The present invention maintains a compact evaporator size in a centrifugal chiller utilizing a low pressure refrigerant used at a maximum pressure of less than 0.2 MPaG while avoiding efficiency losses and equipment damage that result from carryover of liquid state refrigerant to the turbo compressor side. This evaporator is equipped with a pressure vessel into which a condensed refrigerant is introduced, a refrigerant inlet which is provided to the bottom portion of the pressure vessel, a refrigerant outlet which is provided to the top portion of the pressure vessel, a heat transfer pipe group which passes through the interior of the pressure vessel, circulates liquid to be chilled through the interior thereof, and exchanges heat between the liquid to be chilled and the refrigerant, and a demister which is disposed between the refrigerant outlet and the heat transfer pipe group in the interior of the pressure vessel and carries out vapor-liquid separation of the refrigerant, a dividing section (for example, a plurality of notches) being provided between the periphery of the demister and the inner peripheral surface of the pressure vessel. The dividing section is provided to a side of the demister along the lengthwise direction.

A drift eliminator is provided that includes a plurality of blades interleaved by a plurality of spacers. Each spacer has a first leg, a second leg, and a support strip, each of the first and second legs including an upper edge and a lower edge, with the support strip extending laterally from the upper edge of the first leg to the upper edge of the second leg. Each blade includes at least one portion having a plurality of alignment slots formed therein, the plurality of alignment slots extending from an upper surface of the blade portion to a lower surface of the blade portion. Each spacer includes a plurality of alignment tabs extending from the first leg and the second leg, each of the plurality of alignment tabs interfiting with a corresponding one of the plurality of alignment slots in the at least one first blade portion.

A drift eliminator is provided that includes a plurality of blades interleaved by a plurality of spacers. Each spacer has a first leg, a second leg, and a support strip, each of the first and second legs including an upper edge and a lower edge, with the support strip extending laterally from the upper edge of the first leg to the upper edge of the second leg. Each blade includes at least one portion having a plurality of alignment slots formed therein, the plurality of alignment slots extending from an upper surface of the blade portion to a lower surface of the blade portion. Each spacer includes a plurality of alignment tabs extending from the first leg and the second leg, each of the plurality of alignment tabs interfiting with a corresponding one of the plurality of alignment slots in the at least one first blade portion.

A system for reducing evaporative cooling water losses using an electric and magnetic field inducing device is disclosed. The device influences a liquid's properties including evaporation rate, diffusion, vapor, heat transfer rate, and/or fluid properties. The device comprises a malleable core with notches and electrically conductive windings wrapped around the flexible core around the notches. An insulative coating isolates the windings from the core. The device is pliable and is wrapped and/or attached around a conduit (e.g., a makeup line or pipe or a recirculating line or pipe of an evaporative cooling tower) with flowing fluid and current is passed through the windings to treat the fluid.

A cooling tower structure having a concrete perimeter foundation wall with a perimeter rebar grouping. The structure includes at least four columns formed of CMU blocks with at least two columns being freestanding and positioned approximate corners of the foundation wall. Each column further includes a column rebar grouping being tied into the perimeter rebar grouping. At least three bond-beams formed of CMU blocks are connected between the columns at least four feet above the foundation. The bond-beams include beam rebar groupings tying into at least one of the column rebar groupings. The structure includes housing walls formed of CMU blocks extending upward from the bond beams. At least one fan is on at least one pedestal column positioned within the foundation wall, with a pedestal rebar grouping extending though the pedestal column from a concrete pedestal footing. A series of water collection troughs are positioned within the cooling tower above the fan and fill media is positioned in the cooling tower above the collection troughs.

In various embodiments, the present invention relates to heat dissipation systems including a hygroscopic working fluid and methods of using the same. In various embodiments, the present invention provides a method for heat dissipation using a hygroscopic working fluid. The method can include transferring thermal energy from a heated process fluid to the hygroscopic working fluid in a process heat exchanger, to form a cooled process fluid. The method can include condensing liquid from a feed gas on a heat transfer surface of a feed gas heat exchanger in contact with the cooled process fluid, to form a cooled feed gas, the heated process fluid, and a condensate. The method can include dissipating thermal energy from the hygroscopic working fluid to a cooling gas composition with a fluid-air contactor. The method can include transferring moisture between the hygroscopic working fluid and the cooling gas composition with the fluid-air contactor. The method can include adding at least part of the condensate to the hygroscopic working fluid.

In various embodiments, the present invention relates to heat dissipation systems including a hygroscopic working fluid and methods of using the same. In various embodiments, the present invention provides a method for heat dissipation using a hygroscopic working fluid. The method can include transferring thermal energy from a heated process fluid to the hygroscopic working fluid in a process heat exchanger, to form a cooled process fluid. The method can include condensing liquid from a feed gas on a heat transfer surface of a feed gas heat exchanger in contact with the cooled process fluid, to form a cooled feed gas, the heated process fluid, and a condensate. The method can include dissipating thermal energy from the hygroscopic working fluid to a cooling gas composition with a fluid-air contactor. The method can include transferring moisture between the hygroscopic working fluid and the cooling gas composition with the fluid-air contactor. The method can include adding at least part of the condensate to the hygroscopic working fluid.

The present application provides a gas turbine engine. The gas turbine engine may include a compressor and an inlet air system positioned upstream of the compressor. The inlet air system may include a wetted media pad for evaporative cooling. The wetted media pad may include a contoured configuration.

A method for regulating climate, comprising: 1) allowing the formation of a relatively high temperature zone and a low temperature zone in the air above the ground; 2) allowing the formation of air convection between the high temperature zone and the low temperature zone as the cold air in the low temperature zone has a greater density than the hot air in the high temperature zone. A device for regulating climate is, i.e. an automatic air tower. The automatic air tower comprises a column (1) with an air inlet (12) at the bottom, wherein the column comprises a startup unit (13) and a shutdown unit (14) inside and has an air outlet (15) at the top. The aforesaid method and tower can prevent and eliminate the formation of haze and cool the earth's ground.

A method for regulating climate, comprising: 1) allowing the formation of a relatively high temperature zone and a low temperature zone in the air above the ground; 2) allowing the formation of air convection between the high temperature zone and the low temperature zone as the cold air in the low temperature zone has a greater density than the hot air in the high temperature zone. A device for regulating climate is, i.e. an automatic air tower. The automatic air tower comprises a column (1) with an air inlet (12) at the bottom, wherein the column comprises a startup unit (13) and a shutdown unit (14) inside and has an air outlet (15) at the top. The aforesaid method and tower can prevent and eliminate the formation of haze and cool the earth's ground.