A method and system for controlling moisture content of a gaseous flow. A pair of desiccant contact structures each provided with a process adapted to pass through a process gaseous stream to altering the moisture content of the gaseous stream. Each desiccant contact structure also has a regeneration side adapted to pass through a regeneration gaseous stream for altering the moisture content of a desiccant in the contact structure. The process side of a first desiccant contact structure is fluidly connected to the regeneration side of a second desiccant contact structure via a first closed recirculation loop. In an alternative embodiment a second closed recirculation loop may also be provided on the regeneration side of the first desiccant contact structure. Gaseous flow is then provided to the process side of the second desiccant contact structure to thereby control its moisture.

The present invention relates to systems for regenerating desiccants wheels using superheated steam and to a dehumidifier comprising a system for regenerating a desiccant wheel using superheated steam. In particular the invention relates to dehumidifier systems and dehumidifiers comprising such dehumidifier systems, the dehumidifier systems each comprising a closed regeneration loop for regenerating a rotary desiccant wheel using superheated steam; and uses of excess superheated steam generated during regeneration.

A method includes receiving moisturized air from a refrigerated room and absorbing, in a portion of a desiccant wheel, moisture from the moisturized air, wherein absorbing moisture from the moisturized air produces dehumidified air. The method further includes discharging the dehumidified air to the refrigerated room.

A dehumidifying air handling unit for an HVACR system includes a housing, a desiccant wheel, and a cooling heat exchanger. A main airflow path extending through the housing from an air inlet to and air discharged outlet of the housing. The desiccant wheel includes a first end and a second end that are each disposed in the main airflow path and a metal organic framework desiccant that is moved between the first end and the second end. A desiccant wheel includes a metal organic framework desiccant disposed on a surface of the desiccant wheel. Rotation of the desiccant wheel moves a position of the surface between a first end and a second end of the desiccant wheel. The metal organic framework desiccant has an majority absorption-desorption operating band of 25% relative humidity or less.

The present invention relates to a hybrid heat pump apparatus comprising: a housing having a first channel and a second channel formed therein; a dehumidifying rotor disposed in the housing; a heating unit disposed in the first channel and heating air passing therethrough; a cooling unit disposed in the second channel and selectively cooling air passing therethrough; a coolant circulating unit including a compressor, a first heat exchanger disposed in the second channel, a second heat exchanger, and a four-way valve; and a water circulating pipe through which water circulates and which is connected to the second heat exchanger for heat exchanging between the circulating water and coolant in the second heat exchanger.

A desiccant dehumidifier includes a desiccant rotor, which is rotatably arranged about a center axis; a process air circuit arranged to conduct a process airflow through a process sector of the desiccant rotor; a regeneration air circuit arranged to conduct a regeneration airflow through a regeneration sector of the desiccant rotor; a purge air circuit arranged to conduct a purge airflow through a first purge sector and a second purge sector of the desiccant rotor; and an air fan arranged downstream of the desiccant rotor, which air fan is configured to generate the regeneration airflow in the regeneration air circuit and the purge airflow in the purge air circuit. The purge air circuit is arranged to conduct the purge airflow through the first purge sector in a first direction through the desiccant rotor, and through the second purge sector in a second direction through the desiccant rotor, wherein the first direction is opposite to the second direction.

A system for ventilation, dehumidification, and cooling includes an outdoor unit dehumidifying and cooling introduced outside air; and an indoor unit connected to the outdoor unit to perform ventilation, in which the outdoor unit includes a dehumidification rotor, an evaporative cooler, an evaporative condenser, a ventilation damper, a heating unit, and a controller operating and stopping at least one of the dehumidification rotor, the evaporative cooler, the evaporative condenser, the ventilation damper, or the heating unit.

An air conditioning apparatus comprises an inlet module, an airflow guiding module, a hygroscopic wheel a dehumidification heating module and an internal recirculation heating module. The airflow guiding module includes an air channel switching unit, an outflowing air channel in air communication with an external environment outside of an air-conditioning environment, and an inflowing air channel in air communication with the air-conditioning environment. The air conditioning apparatus of the present invention meets various requirements for air conditioning. In addition, when the air conditioning apparatus performs a dehumidification process, the hygroscopic wheel and the dehumidification heating module is applied to remove the moisture of the air conditioning flow of the inflowing air channel, and thus the relative humidity of the air-conditioning environment is directly reduced so as to increase the dehumidifying efficiency.

A solid desiccant cooling system comprising a common intake delivering air (19) to a first pathway (21) for air to be conditioned, and a second pathway (31) for regeneration air and structure (24) retaining a mass of solid desiccant for cyclic movement between a first location (24a), in which the solid desiccant lies in the first pathway (21) for dehumidifying the air to be cooled by adsorption of moisture to the desiccant, and a second location (24b) in which the solid desiccant lies in the second pathway (31) for the regeneration air to take up moisture therein as water vapor. The second pathway has an air heater arrangement (35) upstream of the second location (24b) for heating the regeneration air and the first pathway (21) has an air cooler arrangement (25) independent of the air heater arrangement (35) downstream of the first location (24a). An air delivery device (40) is coupled to both of the first and second pathways (21, 31) and adapted or configured to deliver pressurized air along both the first and second pathways (21, 31). A control strategy is also provided to change the flow path of air from the common intake based on the need to satisfy alternative heating or cooling needs at different times of the day and season.

An air-conditioning system includes: a first duct through which air discharged from an electronic instrument passes; a water vapor retention chamber; an evaporator configured to be heated by the air passing through the first duct and thereby to generate water vapor inside the water vapor retention chamber; a desiccant rotor including an adsorbent to adsorb moisture and configured to be driven and rotated by a driving unit; a humidification chamber; a second duct configured to feed outdoor air introduced from an outdoor space into the humidification chamber; and a third duct configured to feed the air passing through the humidification chamber into a room where the electronic instrument is installed, wherein a portion of the desiccant rotor is located inside the water vapor retention chamber, and another portion of the desiccant rotor is located inside the humidification chamber.