Refrigerant leak detection and management based on condensation from air samples

The invention claimed is: 1. A refrigerant leak detection system for a heating, ventilation, and air conditioning (HVAC) system, wherein the refrigerant leak detection system comprises: a vessel comprising walls configured to contain an air sample; a cooling device operatively coupled to the walls of the vessel and comprising a cooled surface configured to cool the vessel; a liquid detection device operatively coupled to a bottom portion of the walls of the vessel and comprising optical circuitry or electrical circuitry configured to detect liquid in the vessel; and an actuator configured to actuate a transfer mechanism that is operatively coupled to the vessel and configured to provide a pressure differential to collect the air sample in the vessel. 2. The refrigerant leak detection system of claim 1 , wherein the vessel, the cooling device, the liquid detection device, and the actuator are integral components of a sensor. 3. The refrigerant leak detection system of claim 1 , comprising a controller configured to: actuate the actuator to collect the air sample in the vessel; activate the cooling device to cool the air sample to a predefined temperature threshold; control the liquid detection device to identify whether a condensed refrigerant is present in the vessel; and instruct the HVAC system to modify operation when the condensed refrigerant is present in the vessel. 4. The refrigerant leak detection system of claim 1 , comprising a compression assembly operatively coupled to the vessel and configured to compress the air sample against the walls of the vessel. 5. The refrigerant leak detection system of claim 4 , comprising a controller configured to instruct the compression assembly to compress the air sample after collecting the air sample in the vessel. 6. The refrigerant leak detection system of claim 5 , wherein the controller is configured to instruct the compression assembly to compress the air sample in coordination with activating the cooling device to cool the air sample. 7. The refrigerant leak detection system of claim 4 , wherein the compression assembly comprises the actuator operatively coupled to the transfer mechanism, and wherein the transfer mechanism comprises a piston in a sealed engagement with the walls of the vessel. 8. The refrigerant leak detection system of claim 7 , comprising a controller configured to instruct the compression assembly to compress the air sample by instructing the actuator to actuate the piston to reduce an interior volume of the vessel. 9. The refrigerant leak detection system of claim 1 , wherein the vessel comprises: a port fluidly coupling an interior of the vessel to a monitored air volume exterior to the vessel; and a valve fluidly coupled to the port, wherein the valve is configured to open to enable the air sample to traverse the port and to close to impede the air sample from traversing the port. 10. The refrigerant leak detection system of claim 9 , comprising a conduit having a proximal end fluidly coupled to the port and a distal end in fluid communication with the monitored air volume, wherein the conduit comprises the valve. 11. The refrigerant leak detection system of claim 9 , comprising a fan as the transfer mechanism, wherein the fan is fluidly coupled to the port. 12. The refrigerant leak detection system of claim 11 , comprising a controller configured to instruct the actuator to collect the air sample by activating the fan to draw the air sample into the vessel while the valve is open. 13. The refrigerant leak detection system of claim 1 , comprising a desiccant element fluidly coupled to the vessel, wherein the desiccant element is configured to absorb water from the air sample during or after entry into the vessel. 14. The refrigerant leak detection system of claim 13 , wherein the desiccant element is integrated into a conduit that fluidly couples the vessel to a monitored air volume. 15. The refrigerant leak detection system of claim 13 , comprising a regenerator operatively coupled to the desiccant element and configured to regenerate the desiccant element by heating the desiccant element to release the water absorbed from the air sample. 16. The refrigerant leak detection system of claim 3 , comprising a controller configured to activate the cooling device to cool the air sample to an intermediate predefined temperature threshold to condense liquid water from the air sample before activating the cooling device to cool the air sample to the predefined temperature threshold, and wherein the controller is configured to instruct the refrigerant leak detection system to drain the liquid water from the vessel when the liquid water is present in the vessel. 17. The refrigerant leak detection system of claim 1 , wherein a sensor including the vessel, the cooling device, the liquid detection device, and the actuator is disposed within a bent portion of a return duct or a supply duct of the HVAC system. 18. The refrigerant leak detection system of claim 1 , wherein the transfer mechanism comprises a fan or a shaft coupled to a piston. 19. A heating, ventilation, and air conditioning (HVAC) system, comprising: a sensor that includes a vessel having walls, a compression assembly operatively coupled to the vessel and configured to compress an air sample against the walls of the vessel, a cooling device operatively coupled to the walls of the vessel and comprising a cooled surface, and a liquid detection device operatively coupled to a bottom portion of the walls of the vessel and comprising optical circuitry or electrical circuitry; and a controller configured to instruct the sensor to collect the air sample in the vessel from a monitored air volume of the HVAC system, instruct the compression assembly to compress the air sample to a predefined pressure threshold, instruct the cooling device to cool the air sample to a predefined temperature threshold via the cooled surface, instruct the liquid detection device to identify whether a condensed refrigerant is present in the vessel via the optical circuitry or the electrical circuitry, and instruct the HVAC system to modify operation when the condensed refrigerant is present in the vessel. 20. The HVAC system of claim 19 , wherein the liquid detection device is configured to detect the condensed refrigerant including one or more refrigerants, one or more refrigerant additives, or a combination thereof, that have leaked from a vapor compression system of the HVAC system. 21. The HVAC system of claim 19 , wherein the controller is configured to instruct the sensor to compress the air sample while cooling the air sample. 22. The HVAC system of claim 19 , wherein the controller is configured to instruct the sensor to compress the air sample before cooling the air sample. 23. The HVAC system of claim 19 , wherein the controller is configured to communicatively couple to a HVAC controller of the HVAC system. 24. The HVAC system of claim 19 , wherein the liquid detection device is configured to identify that the condensed refrigerant is present in the vessel when any liquid is present in the vessel after cooling the air sample. 25. The HVAC system of claim 19 , wherein the liquid detection device comprises the optical circuitry that is configured to measure a refractive index after cooling the air sample, and wherein the liquid detection device is configured to identify that condensed refrigerant is present in