A cooling system for cooling an enclosure, the cooling system including a heat exchange section configured to transfer sensible heat; a humidifier located outside the heat exchange section and configured to humidify a working air stream C so that it transfers latent heat; an air moving system configured to move various air streams through the cooling system; and a piping system configured to connect the heat exchange section to the humidifier and the air moving system. The sensible heat transfer is decoupled from the latent heat transfer.

A mission critical facility is an enclosed space whose failure can bring a significant loss to a business. An example of a mission critical facility is a data center which usually comprises computers, servers, storage equipment, networking equipment, telecom equipment and associated electrical components working 24/7. The electrical components in the data center produce a lot of heat that requires removal from the enclosed space by using an air conditioning system. This invention includes a fluid cooling apparatus that cools the enclosed space using optimum power and water consumptions. The enclosed space can be a mission critical facility including but not limited to a data center. The disclosed fluid cooling apparatus offers low power and water consumption by combining a mechanical cooling system with an evaporative fluid cooling system in one single apparatus. Some embodiments locate the condenser coil for the mechanical cooling system in the evaporative fluid cooling's exhaust air to save on space and power consumption, which is novel in the industry. Also, this invention proposes using pre-cooling techniques for fluid-coolers which further improves the efficiency of the fluid cooling system which is also novel in the industry. The disclosed fluid cooling apparatus has three modes of operation to optimize power and water consumptions. Also, the disclosed fluid cooling apparatus can be used to deliver cold air to the enclosed space, cold fluid to the enclosed space or an end user or a combination of both which is called hybrid-cooling.

A counter-flow simultaneous heat and mass exchange device is operated by directing flows of two fluids into a heat and mass exchange device at initial mass flow rates where ideal changes in total enthalpy rates of the two fluids are unequal. At least one of the following state variables in the fluids is measured: temperature, pressure and concentration, which together define the thermodynamic state of the two fluid streams at the points of entry to and exit from the device. The mass flow rate of at least one of the two fluids is changed such that the ideal change in total enthalpy rates of the two fluids through the device are brought closer to being equal.

A counter-flow simultaneous heat and mass exchange device is operated by directing flows of two fluids into a heat and mass exchange device at initial mass flow rates where ideal changes in total enthalpy rates of the two fluids are unequal. At least one of the following state variables in the fluids is measured: temperature, pressure and concentration, which together define the thermodynamic state of the two fluid streams at the points of entry to and exit from the device. The mass flow rate of at least one of the two fluids is changed such that the ideal change in total enthalpy rates of the two fluids through the device are brought closer to being equal.

An air-cooled heat exchanger (6) arranged in a gas processing facility for performing a liquefaction process of natural gas is configured to supply cooling air to a tube (63) through which a fluid to be cooled is caused to flow, to thereby cool the fluid to be cooled, and a mist supply section (7) is configured to supply mist obtained by spraying demineralized water, to thereby cool the cooling air. Further, the mist supply section (7) is configured to spray the demineralized water from a lateral position on an upstream side of an intake.

An air-cooled heat exchanger (6) arranged in a gas processing facility for performing a liquefaction process of natural gas is configured to supply cooling air to a tube (63) through which a fluid to be cooled is caused to flow, to thereby cool the fluid to be cooled, and a mist supply section (7) is configured to supply mist obtained by spraying demineralized water, to thereby cool the cooling air. Further, the mist supply section (7) is configured to spray the demineralized water from a lateral position on an upstream side of an intake.

A tube bundle for an evaporative refrigerant condenser having a plurality of straight single pass tubes extending between a refrigerant inlet header and a refrigerant outlet header, said tubes having a cross-sectional shape in the form of an ellipse having a major axis and a minor axis, wherein said major axis is longer than said minor axis by a factor of 3 to 7, wherein the amount of required refrigerant charge for a particular heat exchange capacity is substantially and unexpectedly reduced resulting in a substantial and unexpected increase in efficiency.

A common method of condensing vapors is to use evaporative condensers that combine the functions of a shell and tube water cooled condenser and a cooling tower into a single unit. This arrangement saves space and eliminates condenser water piping and pumps. They work by spraying water on a horizontal tube bundle and drawing air through it to cool and condense the vapor inside the tubes into liquid. My invention envisages the vapor to be in the shell and air or a mixture of air and water flowing inside the tubes. It works in several different modes, by selectively using the attached modules. This innovative arrangement saves water and energy, while maintaining high thermal efficiency.

A mission critical facility is an enclosed space whose failure can bring a significant loss to a business. An example of a mission critical facility is a data center which usually comprises computers, servers, storage equipment, networking equipment, telecom equipment and associated electrical components working 24/7. The electrical components in the data center produce a lot of heat that requires removal from the enclosed space by using an air conditioning system. This invention includes a fluid cooling apparatus that cools the enclosed space using optimum power and water consumptions. The enclosed space can be a mission critical facility including but not limited to a data center. The disclosed fluid cooling apparatus offers low power and water consumption by combining a mechanical cooling system with an evaporative fluid cooling system in one single apparatus. Some embodiments locate the condenser coil for the mechanical cooling system in the evaporative fluid cooling's exhaust air to save on space and power consumption, which is novel in the industry. Also, this invention proposes using pre-cooling techniques for fluid-coolers which further improves the efficiency of the fluid cooling system which is also novel in the industry. The disclosed fluid cooling apparatus has three modes of operation to optimize power and water consumptions. Also, the disclosed fluid cooling apparatus can be used to deliver cold air to the enclosed space, cold fluid to the enclosed space or an end user or a combination of both which is called hybrid-cooling.

A water recirculation system operates in a primary mode for evaporatively cooling air. When the water recirculation mode malfunctions, the controller switches a secondary once-through mode. The system includes a sump for collecting water run-off from the evaporative pads, and a pump in fluid communication with the sump. The pump transfers moisture from the sump to the distribution arrangement located at the top of the evaporative pads during the recirculation mode. An automatically operated make-up water valve delivers water to a distribution arrangement on the evaporative pads. A moisture distribution arrangement distributes moisture to the evaporative pads and an automatically operated sump drain valve retains water in the sump when closed and freely drains water from the sump when open. A water level control communicates the sump water level to a control system. A monitoring mechanism detects whether the water-recirculation system has malfunctioned or is operating correctly.