Adsorption air-conditioning system

The invention claimed is: 1. A vehicle air-conditioning system for cooling a vehicle cabin, comprising: an adsorption heat pump driven by an engine waste heat recovery system, the heat pump comprising a first adsorbing/desorbing heat exchanger, a second evaporating/condensing heat exchanger, a radiator, and an air-conditioning core, the first and second heat exchangers arranged inside a vacuum enclosure and thermally coupled via vapor, wherein the air-conditioning core contains a plurality of double tube plates, each double tube plate comprising an inner tube arranged within an outer tube, with phase changing materials surrounding the inner tube within the outer tube, wherein the inner tube of each plate selectively fluidly communicates with one or more tubes of a tube-and-plate assembly of the second heat exchanger depending on a mode of the system; and a controller comprising a processor and a storage medium programmed with computer readable data representing instructions executable by the processor to, during a desorbing/condensing mode in which the inner tubes of the air-conditioning core are fluidly decoupled from the system, actuate a blower to cool a vehicle passenger cabin by blowing air through the air-conditioning core into the cabin as the phase changing materials in the air-conditioning core melt. 2. The system of claim 1 , wherein the tube-and-plate assembly of the second heat exchanger is a second tube-and-plate assembly, and wherein the first heat exchanger comprises a first tube-and-plate assembly, the first tube-and-plate assembly comprising one or more tubes and a plurality of adsorbent-coated plates thermally coupled with the tubes, and wherein depending on the mode of the system, the tubes of the first heat exchanger are fluidly coupled with either the waste heat recovery system or the radiator, and the tubes of the second heat exchanger are fluidly coupled with either the radiator or the air-conditioning core. 3. The system of claim 1 , wherein the system does not include an engine-driven compressor, a dedicated evaporator, or a dedicated condenser. 4. The system of claim 1 , wherein the first and second heat exchangers are the only pair of heat exchangers in the system. 5. The system of claim 1 , wherein the first and second heat exchangers are stacked vertically within the enclosure. 6. The system of claim 1 , wherein the first and second heat exchangers are arranged side by side within the enclosure. 7. The system of claim 2 , wherein during an adsorbing/evaporating mode, the tubes of the first heat exchanger fluidly communicate with the radiator while the tubes of the second heat exchanger fluidly communicate with the inner tubes of the air-conditioning core, and wherein during the desorbing/condensing mode, the tubes of the first heat exchanger fluidly communicate with the waste heat recovery system while the tubes of the second heat exchanger fluidly communicate with the radiator. 8. The system of claim 7 , wherein the air-conditioning core further comprises segments containing air-cooling fins, each segment arranged between and thermally coupled with two of the double tube plates. 9. An air-conditioning system, comprising: first and second tube-and-plate heat exchangers thermally coupled by vapor inside a vacuum enclosure; a first coolant loop comprising adsorbent-coated plates of the first heat exchanger and either a heat source or a radiator depending on an operating mode of the air-conditioning system; a second coolant loop comprising non-adsorbent-coated plates of the second heat exchanger and either the radiator or an air-conditioning core containing phase changing materials, depending on the operating mode; and a controller comprising a processor and a storage medium programmed with computer readable data representing instructions executable by the processor to, during a desorbing/condensing mode in which the inner tubes of the air-conditioning core are fluidly decoupled from the system, actuate a blower to cool a vehicle passenger cabin by blowing air through the air-conditioning core into the cabin as the phase changing materials in the air-conditioning core melt. 10. The system of claim 9 , wherein during the desorbing/condensing mode, the first coolant loop comprises the heat source and the second coolant loop comprises the radiator, and wherein during an adsorbing/evaporating mode, the first coolant loop comprises the radiator and the second coolant loop comprises the air-conditioning core. 11. The system of claim 9 , wherein the system does not include a compressor, a dedicated evaporator, or a dedicated condenser. 12. The system of claim 9 , wherein the first and second heat exchangers are the only pair of heat exchangers in the system. 13. The system of claim 9 , wherein one or more inner tubes of the air-conditioning core selectively fluidly communicate with one or more tubes of the second heat exchanger depending on the operating mode. 14. A method for a vehicle air-conditioning system, comprising: during engine operation, alternating between a desorbing/condensing mode comprising circulating coolant between a waste heat recovery system and a first heat exchanger while circulating coolant between a radiator and a second heat exchanger and an adsorbing/evaporating mode comprising circulating coolant between the radiator and the first heat exchanger while circulating coolant between an air-conditioning core comprising phase changing materials and the second heat exchanger, wherein the desorbing/condensing mode further comprises cooling a vehicle passenger cabin by blowing air through the air-conditioning core into the cabin as the phase changing materials in the air-conditioning core melt, and wherein in the desorbing/condensing mode, inner tubes of the air-conditioning core are fluidly decoupled from the system. 15. The method of claim 14 , wherein the first and second heat exchangers are tube-and-plate heat exchangers arranged in a common vacuum enclosure and thermally coupled by vapor, wherein circulating coolant in the first heat exchanger comprises circulating coolant in one or more tubes of the first heat exchanger which are thermally coupled with adsorbent-coated plates of the first heat exchanger, and wherein circulating coolant in the second heat exchanger comprises circulating coolant in one or more tubes of the second heat exchanger which are thermally coupled with non-adsorbent-coated plates of the second heat exchanger. 16. The method of claim 15 , wherein during the desorbing mode, vapor desorbs from the adsorbent-coated plates of the first heat exchanger and condenses on the non-adsorbent-coated plates of the second heat exchanger while the phase changing materials in the air-conditioning core release thermal energy, and wherein during the adsorbing mode, vapor evaporates from the non-adsorbent-coated plates of the second heat exchanger and is adsorbed at the adsorbent-coated plates of the first heat exchanger while the phase changing materials in the air-conditioning core store thermal energy. 17. The method of claim 16 , further comprising: during the desorbing mode, controlling inlet and outlet valves of the first heat exchanger to fluidly couple the first heat exchanger with the waste heat recovery system while fluidly decoupling the first heat exchanger and the radiator, and controlling inlet and outlet valves of the second heat exchanger to fluidly couple the second heat exchanger with the radiator while fluidly decoupling the second heat exchanger and the air-conditioning core; during the adsorbing mode, controlling the in