Self-regenerated hybrid dehumidifier with air purification

The invention claimed is: 1. A system for removing moisture from process air comprising: an enclosure including at least one gas inlet and one gas outlet, the enclosure further includes: a plurality of thermal conductive elements having at least one superhydrophilic-nanostructured composite surface and composite adsorbent; at least one heat storage member; at least one thermoelectric heating and cooling member communicating with the plurality of thermal conductive elements and the at least one heat storage member, respectively, forming at least two water circulations within the enclosure; and at least one particulate air filter disposed adjacent to the at least one gas inlet; wherein the process air is ventilated into the system through the at least one gas inlet, and passes through the at least one particulate air filter, followed by passing through the plurality of thermal conductive elements to contact the at least one superhydrophilic-nanostructured composite surface and water adsorbent in order to effect moisture removal; wherein heat generated from water of the at least one thermoelectric heating and cooling member is stored in the at least one heat storage member and the heat stored in the at least one heat storage member changes the state of material in the at least one heat storage member and provides heat to the water of the at least one thermoelectric heating and cooling member; wherein moisture from the process air is condensed on the at least one superhydrophilic-nanostructured composite surface when the process air contacts the at least one superhydrophilic-nanostructured composite surface due to a surface temperature being below a dew point temperature and/or at least a compound of the composite adsorbent absorbs water molecules from the moisture, and water condensed on said at least one superhydrophilic-nanostructured composite surface is collected by a water collection member disposed in the enclosure due to gravity. 2. The system of claim 1 , wherein the at least one superhydrophilic-nanostructured composite surface has a water contact angle of less than 10 degrees. 3. The system of claim 2 , wherein the at least one superhydrophilic-nanostructured composite surface comprises at least one photo-induced compound in order to exert photocatalytic superhydrophilicity to the at least one superhydrophilic-nanostructured composite surface. 4. The system of claim 3 , wherein the at least one photo-induced compound comprises titanium dioxide. 5. The system of claim 2 , wherein the at least one superhydrophilic-nanostructured composite surface comprises at least a metal deposited electrochemically and sintered to exert superhydrophilicity. 6. The system of claim 5 , wherein the metal comprises copper. 7. The system of claim 2 , wherein the at least one superhydrophilic-nanostructured composite surface comprises at least a metal substrate developed by dip-coating. 8. The system of claim 7 , wherein the metal substrate comprises a copper substrate. 9. The system of claim 1 , wherein the composite adsorbent comprises carbon nanotube, zeolite, calcium chloride, silica gel, activated carbon, or any combination thereof. 10. The system of claim 9 , wherein the composite adsorbent is coated on the at least one superhydrophilic-nanostructured composite surface by spraying or electrostatic coating. 11. The system of claim 1 , wherein the plurality of thermal conductive elements is arranged to form tubular, shell, double pipe, hairpin, flat plate, fin, radiator, spiral structure, serpentine-shaped, or any combination thereof, to increase solid-liquid contact area of the superhydrophilic-nanostructured composite surface. 12. The system of claim 1 , wherein a first ventilation fan is disposed in the enclosure along a first air pathway for ventilating the process air from outside the enclosure through the gas inlet, subsequently through the at least one particulate air filter, followed by contacting the at least one superhydrophilic-nanostructured composite surface and the composite adsorbent of the plurality of the thermal conductive elements, before the process air being discharged from the enclosure through the gas outlet to the exterior of the enclosure. 13. The system of claim 1 , wherein a second ventilation fan is disposed such that hot air generated from the at least one heat storage member is directed towards the plurality of thermal conductive elements so that heat from the hot air heats the surface thereof so that water molecules absorbed by the composite adsorbent are released from the composite absorbent to the relatively colder superhydrophilic-nanostructured composite surface. 14. A self-regenerated method for removing moisture from process air comprising: providing an enclosure where the process air is treated; first ventilating the process air from a gas inlet of the enclosure through an air pathway to reach a plurality of thermal conductive elements; providing a superhydrophilic-nanostructured composite surface coated with one or more chemical-based adsorbents on the plurality of thermal conductive elements to be disposed within the enclosure in an orientation substantially perpendicular to the direction of air flow in the air pathway from the gas inlet in order to maximize contact rate per surface area of the superhydrophilic-nanostructured composite surface to a volume of incoming process air; providing a thermoelectric heater and cooler module having at least two water circulations respectively communicating with a liquid section of the plurality of the thermal conductive elements and with a heat storage member, one end of the liquid section of the thermal conductive elements more proximal to the superhydrophilic-nanostructured composite surface receiving a relatively cool water from the thermoelectric heater and cooler module while the other end of the liquid section of the thermal conductive elements more distal to the superhydrophilic-nanostructured composite surface transferring a relatively warm water to the thermoelectric heater and cooler module; the heat storage member including a material responsive to temperature change when the temperature of the water from the thermoelectric heater and cooler module exceeds a phase-transition temperature of said material of the heat storage member such that said material is converted from solid state into liquid state; second ventilating the air in the enclosure towards a direction which a maximum air flow rate first flowing through the heat storage member to carry away heat from said material of the heat storage member after being converted into liquid state followed by flowing through multiple gaps between each pair of two different vertical planes of the thermal conductive elements is provided to elevate the surface temperature of the superhydrophilic-nanostructured composite surface such that water molecules from the incoming process air absorbed by the one or more chemical-based adsorbents are ready to be released from the chemical-based absorbents; after said second ventilated air passing through the material of the heat storage member having been converted from solid to liquid state thereof by the relatively warm water at a temperature exceeding the phase-transition temperature of the material from the thermoelectric heater and cooler module, transferring the water after cooling by said ventilated air from the heat storage member back to the thermoelectric heater and cooler module in order to circulate a relatively cool water to the end of the liquid section of the plurality of thermal conductive elements more proximal to the superhydrophilic-nanostructured composite surf