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Systems, methods and devices for utilizing an energy chassis device designed to sense, collect, store and distribute energy from where it is available using devices that harvest or convert energy to locations requiring energy such as but not limited to HVAC (heating, ventilation and cooling) systems

Systems, methods and devices for utilizing an energy chassis device designed to sense, collect, store and distribute energy from where it is available using devices that harvest or convert energy to locations requiring energy such as but not limited to HVAC (heating, ventilation and cooling) systems. The systems, methods and devices can also be used with a next generation geothermal heat exchanger that achieves higher energy harvesting efficiency and provides greater functionality than current geothermal exchangers.

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1. A heating and cooling system comprising: a plurality of thermal energy sources and a plurality of thermal energy sinks; anda controller, the controller configured to: determine a thermal energy stored in each of the thermal sources;determine a thermal energy capacity of each of the thermal sinks;

1. A heating and cooling system comprising: a plurality of thermal energy sources and a plurality of thermal energy sinks; anda controller, the controller configured to: determine a thermal energy stored in each of the thermal sources;determine a thermal energy capacity of each of the thermal sinks;determine a thermal energy storage and dissipation rate for each of the thermal sources;determine a thermal storage capacity each of the thermal sinks;predict a thermal energy loss and gain and a thermal retention of the system over a preselected time period based upon use of one or more of the thermal sources or sinks and the determined thermal energy, the determined thermal energy capacity, the thermal energy storage and dissipation rate, and the determined thermal storage capacity of the one or more of the thermal sources or sinks;compare the predicted thermal energy loss and gain and the thermal retention of the system to a target parameter;select at least one of the plurality of thermal sources or sinks based upon the comparison; andinitiate a use of the selected at least one thermal source or sink. 2. A method for using a plurality of thermal energy sources and a plurality of thermal energy sinks of a heating and cooling system to heat or cool a building comprising the steps of: predicting a thermal energy loss and gain for each of the thermal sources and thermal sinks over a selected time period, wherein each of the thermal energy sources is configured to store thermal energy and to allow for extraction of the stored energy therefrom, and wherein each thermal energy sink is configured to absorb and store thermal energy;comparing the thermal energy loss and gain for each of the thermal sources and thermal sinks to a thermal energy demand of the building for the selected time period to obtain a comparison;selecting at least one of the thermal sources or sinks based upon the comparison; andheating or cooling the building to meet the thermal energy demand by initiating a use of the selected at least one thermal source or sink for the selected time period based upon the comparison. 3. The method of claim 2, further comprising: determining the amount of thermal energy stored in each of the thermal sources and sinks;determining the thermal energy capacity of each of the thermal sources and thermal sinks for the selected time period; anddetermining the thermal energy storage and dissipation rate of each of the thermal sources and sinks for the selected time period; andwherein the step of predicting a thermal energy loss and gain for each of the thermal sources and thermal sinks over a selected time period comprises predicting the thermal energy loss and gain based upon the determined amount of thermal energy, thermal energy capacity, and thermal energy storage and dissipation rate. 4. The method of claim 2, wherein the thermal sources and thermal sinks comprise hybrid thermal sources and thermal sinks. 5. The method of claim 2, wherein each of the thermal sources and thermal sinks comprise at least one geothermal source or sink. 6. The method of claim 2, further comprising determining the thermal energy demand based upon real-time data. 7. The method of claim 2, wherein the thermal energy demand of the building is a predicted future thermal energy demand of the building. 8. The method of claim 7, further comprising preheating or precooling of a thermal storage source or sink based upon the predicted future thermal energy demand. 9. The method of claim 7, further comprising predicting the future thermal energy demand of the building based upon weather trends or historical data. 10. The method of claim 7, further comprising charging at least one of the thermal sources or thermal sinks to at least partially meet the predicted future thermal energy demand of the building. 11. The method of claim 2, further comprising repeating the steps of predicting and comparing to obtain a second comparison; and selecting and initiating the use of a second thermal source or sink based upon the second comparison to further heat or cool the building. 12. A heating and cooling system comprising: a plurality of thermal energy sources and a plurality of thermal energy sinks, wherein each of the thermal energy sources is configured to store thermal energy and to allow for extraction of the stored energy therefrom, and wherein each thermal energy sink is configured to absorb and store thermal energy; anda controller, the controller configured to:predict a thermal energy loss and gain for each of the thermal sources and thermal sinks over a selected time period;compare the thermal energy loss and gain for each of the thermal sources and thermal sinks to a thermal energy demand for the selected time period to obtain a comparison;select at least one of the thermal sources or sinks based upon the comparison; andinitiate a use of the selected at least one thermal source or sink. 13. The system of claim 12, wherein the controller is further configured to: determine the amount of thermal energy stored in each of the thermal sources in sinks;determine the thermal energy capacity of each of the thermal sources and thermal sinks for the selected time period; anddetermine the thermal energy storage and dissipation rate of each of the thermal sources and sinks for the selected time period; andwherein the step of predicting a thermal energy loss and gain for each of the thermal sources and thermal sinks over a selected time period comprises predicting the thermal energy loss and gain based upon the determined amount of thermal energy, thermal energy capacity, and thermal energy storage and dissipation rate. 14. The system of claim 12, wherein the thermal sources and thermal sinks comprise hybrid thermal sources and thermal sinks. 15. The system of claim 12, wherein at least one of the thermal sources and thermal sinks is a geothermal source or sink. 16. The system of claim 12, the controller further configured to determine the thermal energy demand based upon real-time data. 17. The system of claim 12, wherein the thermal energy demand is a predicted future thermal energy demand. 18. The system of claim 17, wherein the controller is further configured to preheat or precool a thermal storage source or sink based upon the predicted future thermal energy demand. 19. The system of claim 17, wherein the controller is further configured to predict the future thermal energy demand based upon weather trends and historical data. 20. The system of claim 17, wherein the controller is further configured to charge at least one of the thermal sources or thermal sinks to at least partially meet the predicted future thermal energy demand. 21. The system of claim 12, wherein the controller is further configured to repeat the steps of predicting and comparing to obtain a second comparison and select and initiate the use of a second thermal source or sink based upon the second comparison.