HVAC systems and methods with improved humidity regulation

I claim: 1. A heating, ventilating, and air conditioning system for regulating a moisture content of conditioned air, the system comprising: a closed-conduit refrigeration circuit for developing cooling capacity in an evaporator, the closed-circuit refrigeration circuit comprising a refrigerant expansion valve and a suction line; a closed-conduit desiccant circuit for removing at least some moisture from a cooled airflow cooled by the evaporator, the closed-conduit desiccant circuit having an absorber, the absorber comprising: an absorber frame formed with a first substantially-closed perimeter, a pair of absorber membranes coupled to the absorber frame along the first substantially-closed perimeter, the pair of absorber membranes defining opposite surfaces of an absorber processing volume, the pair of absorber membranes formed of a material permeable to vapor and resistant to liquids, and wherein the absorber frame has a first desiccant entry port and a first desiccant exit port configured to allow liquid desiccant to, respectively, enter and exit the absorber processing volume; fan or blower for moving air across a portion of the closed-conduit refrigeration circuit to produce the cooled air flow and across a portion of the closed-conduit desiccant circuit; and wherein a portion of the closed-conduit refrigeration circuit enters the absorber processing volume for cooling desiccant therein; and wherein the closed-conduit refrigeration circuit and the absorber further comprise: a first refrigerant conduit disposed within the absorber processing volume, the first refrigerant conduit having a first refrigerant entry port and a first refrigerant exit port; wherein the first refrigerant entry port is fluidly-coupled to the expansion valve of the closed-conduit refrigeration circuit; and wherein the first refrigerant exit port is fluidly-coupled to the suction line of the closed-conduit refrigeration circuit. 2. The system of claim 1 , wherein the closed-circuit desiccant circuit further comprises a desorber, the desorber comprising: a desorber frame formed with a second substantially-closed perimeter; a pair of desorber membranes coupled to the desorber frame along the second substantially-closed perimeter, the pair of desorber membranes defining opposite surfaces of a desorber processing volume, the pair of desorber membranes formed of a material permeable to vapor and resistant to liquids; and wherein the desorber frame has a second desiccant entry port and a second desiccant exit port configured to allow liquid desiccant to, respectively, enter and exit the desorber processing volume. 3. The system of claim 1 , wherein the closed-circuit desiccant circuit further comprises a desorber, the desorber comprising: a desorber frame formed with a second substantially-closed perimeter; a pair of desorber membranes coupled to the desorber frame along the second substantially-closed perimeter, the pair of desorber membranes defining opposite surfaces of a desorber processing volume, the pair of desorber membranes formed of a material permeable to vapor and resistant to liquids; wherein the desorber frame has a second desiccant entry port and a second desiccant exit port configured to allow liquid desiccant to, respectively, enter and exit the desorber processing volume; a second refrigerant conduit disposed within the desorber processing volume, the second refrigerant conduit having a second refrigerant entry port and a second refrigerant exit port; wherein the second refrigerant entry port is fluidly-coupled to a discharge line of the closed-conduit refrigeration circuit; and wherein the second refrigerant exit port is fluidly-coupled to a condenser of the closed-conduit refrigeration circuit. 4. The system of claim 1 , wherein the closed-circuit desiccant circuit further comprises a desorber, the desorber comprising: a desorber frame formed with a second substantially-closed perimeter; a pair of desorber membranes coupled to the desorber frame along the second substantially-closed perimeter, the pair of desorber membranes defining opposite surfaces of a desorber processing volume, the pair of desorber membranes formed of a material permeable to vapor and resistant to liquids; wherein the desorber frame has a second desiccant entry port and a second desiccant exit port configured to allow liquid desiccant to, respectively, enter and exit the desorber processing volume; and wherein the closed-conduit desiccant circuit comprises: at least one pump for circulating liquid desiccant therein, a supply line fluidly-coupling the first desiccant entry port of the absorber to the second desiccant exit port of the desorber, a return line fluidly-coupling the first desiccant exit port of the absorber to the second desiccant entry port of the desorber. 5. The system of claim 1 , wherein the closed-circuit desiccant circuit further comprises a desorber, the desorber comprising: a desorber frame formed with a second substantially-closed perimeter; a pair of desorber membranes coupled to the desorber frame along the second substantially-closed perimeter, the pair of desorber membranes defining opposite surfaces of a desorber processing volume, the pair of desorber membranes formed of a material permeable to vapor and resistant to liquids; and wherein the desorber frame has a second desiccant entry port and a second desiccant exit port configured to allow liquid desiccant to, respectively, enter and exit the desorber processing volume; and wherein the closed-conduit desiccant circuit comprises: at least one pump for circulating liquid desiccant therein; a supply line fluidly-coupling the first desiccant entry port of the absorber to the second desiccant exit port of the desorber, a return line fluidly-coupling the first desiccant exit port of the absorber to the second desiccant entry port of the desorber, and a heat exchanger thermally-coupled to the supply line and the return line for transferring thermal energy between the supply line and the return line. 6. The system of claim 1 , comprising a refrigerant disposed in the closed-circuit refrigerant circuit and a liquid desiccant disposed in the closed-circuit desiccant circuit. 7. The system of claim 1 , comprising a refrigerant disposed in the closed-circuit refrigerant circuit and a liquid desiccant disposed in the closed-circuit desiccant circuit, and wherein the liquid desiccant comprises a lithium chloride solution. 8. The system of claim 1 , wherein the material permeable to vapor and resistant to liquid comprises a material formed of expanded material comprises one of a group comprising polytetrafluoroethylene and polydimethylsiloxane. 9. An moisture-altering device for altering a moisture content of air processed by a heating, ventilating, and air conditioning system, the device comprising: a frame formed with a substantially-closed perimeter; a pair of membranes coupled to the frame along the substantially-closed perimeter, the pair of membranes defining opposite surfaces of a processing volume, the pair of membranes formed of a material permeable to vapor and resistant to liquid; a refrigerant conduit disposed within the processing volume, the refrigerant conduit having a refrigerant entry port and a refrigerant exit port; and wherein the frame has a desiccant entry port and a desiccant exit port configured to allow liquid desiccant to, respectively, enter and exit the processing volume; and further comprising a refrigerant line coupled to the refrigerant entry port, the refrigerant line in fluid communication with a refrigerant expansion valve of the system. 10. The device of claim 9 , further comprising a discharge line coupled to the refrigerant