A liquid container for gas humidification comprises: a first component provided with a gas inlet; a second component connected with the first component and defining a liquid receiving space; a baffle member; and a gas exhaust structure including a first opening and a second opening communicated with each other; wherein the first component includes a first portion and a second portion, the first portion and the baffle member defining a first space, the second portion and the baffle member defining a second space, the first opening of the gas exhaust structure being arranged in the second space; and wherein the first portion and the second portion of the first component respectively include a first guide structure and a second guide structure, the first guide structure being configured to direct gas to the liquid receiving space, and the second guide structure being configured to direct the gas away from the liquid receiving space and into the gas exhaust structure via the first opening.

A liquid container for gas humidification comprises: a first component provided with a gas inlet; a second component connected with the first component and defining a liquid receiving space; a baffle member; and a gas exhaust structure including a first opening and a second opening communicated with each other; wherein the first component includes a first portion and a second portion, the first portion and the baffle member defining a first space, the second portion and the baffle member defining a second space, the first opening of the gas exhaust structure being arranged in the second space; and wherein the first portion and the second portion of the first component respectively include a first guide structure and a second guide structure, the first guide structure being configured to direct gas to the liquid receiving space, and the second guide structure being configured to direct the gas away from the liquid receiving space and into the gas exhaust structure via the first opening.

A cooling pad support system for holding a cooling pad may include a support array; a pivoting platform configured to be pivotably connected with respect to the support array and a support finger configured to be pivotably connected to the pivoting platform. The cooling pad may be sandwiched between the support finger and support array.

A humidifier, including: a flat humidification member formed of a water absorbing member and arranged in an upright posture; a nozzle serving as a water supply unit configured to supply water to the humidification member; and an airflow direction changing plate arranged with a clearance secured between the airflow direction changing plate and the humidification member. On a flat surface of the airflow direction changing plate opposed to the flat humidification member, an airflow direction changing portion is arranged to project toward the flat humidification member, the airflow direction changing portion being configured to change a direction of an air current flowing between the flat humidification member and the airflow direction changing plate.

A humidifier, including: a flat humidification member formed of a water absorbing member and arranged in an upright posture; a nozzle serving as a water supply unit configured to supply water to the humidification member; and an airflow direction changing plate arranged with a clearance secured between the airflow direction changing plate and the humidification member. On a flat surface of the airflow direction changing plate opposed to the flat humidification member, an airflow direction changing portion is arranged to project toward the flat humidification member, the airflow direction changing portion being configured to change a direction of an air current flowing between the flat humidification member and the airflow direction changing plate.

Synthetic media pads configured to be arranged in a stack of an evaporative cooler for a gas turbine, wherein the synthetic media pads include high density synthetic media pads and low density synthetic media pads. The sides of the pads may have surface patterns, such as grooves and ridges, to provide support for the pads.

Synthetic media pads configured to be arranged in a stack of an evaporative cooler for a gas turbine, wherein the synthetic media pads include high density synthetic media pads and low density synthetic media pads. The sides of the pads may have surface patterns, such as grooves and ridges, to provide support for the pads.

A humidifier includes plural separators each formed in a plate shape, the separator including a flow path on each of a front side and a back side thereof, and a water exchanging film sandwiched between the separators at a boundary thereof which are adjacent to each other in a state where the plural separators are stacked on each other. Humidified gas flows in one of the flow paths facing each other with the water exchanging film therebetween, and dry gas flows in the other of the flow paths. The water exchanging film is formed in an elongated shape, and different areas of the water exchanging film are sandwiched by the separators at plural boundaries thereof.

A humidifier includes plural separators each formed in a plate shape, the separator including a flow path on each of a front side and a back side thereof, and a water exchanging film sandwiched between the separators at a boundary thereof which are adjacent to each other in a state where the plural separators are stacked on each other. Humidified gas flows in one of the flow paths facing each other with the water exchanging film therebetween, and dry gas flows in the other of the flow paths. The water exchanging film is formed in an elongated shape, and different areas of the water exchanging film are sandwiched by the separators at plural boundaries thereof.

A system and method for conditioning air is provided that optimizes the use of sustainable and locally sourced materials with agrarian, residential, and industrial applications. The system can be formed with a porous siliceous, or siliceous and aluminous material that is sufficiently porous, to allow conditioning fluid to flow there through. The material can also be formed into a structure that includes one or more passageways configured to allow air to be conditioned to also pass there through. The structure can be configured to cause the conditioning fluid passing through the porous portions of the structure to intersect and mix with air passing there through. The structure may include a plurality of passageways and intersections and may include a plurality of air inlets and outlets for air passage. The system may additionally include a means for storing, collecting, and driving conditioning fluid through the system and a means for collecting solar radiation to drive airflow and regenerate conditioning fluid.