Systems and methods for controlling power flow between electrified vehicles and charging trailers during in-flight energy transfers

What is claimed is: 1. An electrified vehicle, comprising: a traction battery pack; and a control module programmed to create an energy transfer prioritization control strategy for controlling a transfer of energy to the traction battery pack from an energy unit separate from the electrified vehicle during an in-flight energy transfer event of the electrified vehicle, wherein the energy transfer prioritization control strategy includes a priority ranking score assigned to the traction battery pack, wherein the energy transfer prioritization control strategy is derived based on real-time prognostic information associated with the electrified vehicle, wherein the real-time prognostic information includes a current estimated time of arrival to reach a desired destination associated with a current drive route of the electrified vehicle, wherein the priority ranking score is an aggregated score derived from a combination of a functional status score portion, an energy requirement score portion, an energy performance/limitation score portion, and a user preference score portion of the traction battery pack. 2. The electrified vehicle as recited in claim 1 , wherein the energy transfer prioritization control strategy is derived based on battery prognostic information associated with the traction battery pack. 3. The electrified vehicle as recited in claim 1 , wherein the energy transfer prioritization control strategy is derived based on itinerary/calendar information associated with a user of the electrified vehicle. 4. The electrified vehicle as recited in claim 1 , wherein the energy transfer prioritization control strategy is derived based on a real-time weather condition. 5. The electrified vehicle as recited in claim 1 , wherein the energy transfer prioritization control strategy is derived based on a real-time traffic condition. 6. The electrified vehicle as recited in claim 1 , wherein the energy transfer prioritization control strategy is derived based on an anticipated physical route condition. 7. The electrified vehicle as recited in claim 1 , wherein the control module is further programmed to control the transfer of the energy to the traction battery pack for achieving a full charge of the traction battery pack before the electrified vehicle reaches a planned destination/waypoint. 8. The electrified vehicle as recited in claim 1 , wherein the control module is further programmed to command a charge rate and a time for transferring the energy to the traction battery pack during the in-flight energy transfer event. 9. A bidirectional energy transfer system, comprising: an electrified vehicle; a charging trailer coupled to the electrified vehicle; an electrified recreational vehicle coupled to the charging trailer, wherein the electrified recreational vehicle is a personal watercraft, an all-terrain vehicle (ATV), a utility vehicle (UTV), a motorcycle, or a bike; and a control module programmed to create an energy transfer prioritization control strategy for controlling a transfer of energy from the charging trailer to the electrified vehicle and to the electrified recreational vehicle during an in-flight energy transfer event, wherein the transfer of the energy from the charging trailer to the electrified vehicle is based, at least in part, on real-time prognostic information associated with the electrified vehicle, wherein the real-time prognostic information includes a current traveling speed of the electrified vehicle and a current estimated time of arrival to reach a desired destination associated with a current drive route of the electrified vehicle, wherein the energy transfer prioritization control strategy includes a first priority ranking score assigned to a first traction battery pack of the electrified vehicle and a second priority ranking score assigned to a second traction battery pack of the electrified recreational vehicle, wherein the first priority ranking score is lower than the second priority ranking score during a first, earlier stage of the current drive route, and the first priority ranking score is greater than the second priority ranking score during a second, later stage of the current drive route, wherein the first priority ranking score is an aggregated score derived from a combination of a functional status score portion, an energy requirement score portion, an energy performance/limitation score portion, and a user preference score portion of the first traction battery pack.