초록 ▼

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.

대표청구항 ▼

1. A method of designing a geothermal heating and cooling system to heat or cool a building, comprising: selecting at least one geothermal heat exchanger source;selecting at least one geothermal heat exchanger sink;predicting a thermal energy demand of the building for a selected time period;predict

1. A method of designing a geothermal heating and cooling system to heat or cool a building, comprising: selecting at least one geothermal heat exchanger source;selecting at least one geothermal heat exchanger sink;predicting a thermal energy demand of the building for a selected time period;predicting a thermal energy loss and gain of the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink over the selected time period to meet the predicted thermal energy demand;determining a cost of installing and operating the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink based upon the predicted thermal energy loss and gain;running, using a controller, a simulation of a heating and cooling system that includes the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink;optimizing, using the controller, a type, interconnectivity, or size of the at least one geothermal heat exchanger source or the at least one geothermal heat exchanger sink based upon the determined cost and the simulation; andgenerating, using the controller, a geothermal heating and cooling system design that includes the optimized at least one geothermal heat exchanger source and the optimized at least one geothermal heat exchanger sink. 2. The method of claim 1, wherein predicting a thermal energy demand or predicting a thermal energy loss comprises predicting expected load. 3. The method of claim 1, wherein predicting a thermal energy demand or predicting a thermal energy loss comprises predicting occupancy of the building, a usage schedule of the building, a weather forecast, or outdoor air quality. 4. The method of claim 1, wherein predicting a thermal energy demand or predicting a thermal energy loss comprises considering insulation and conduction properties of the building. 5. The method of claim 1, wherein determining a cost of installing and operating comprises considering electrical rate data. 6. The method of claim 1, wherein the building is an existing building. 7. The method of claim 1, wherein the building is designed and not constructed, and wherein determining the cost comprises determining a cost of operating existing equipment, building material costs, and building construction costs. 8. The method of claim 1, further comprising considering at least one design limitation when optimizing. 9. The method of claim 8, wherein the at least one design limitation includes land usage, ground conditions, or ground water. 10. The method of claim 1, further comprising predicting an energy efficiency of use of the at least one geothermal heat exchanger source and the at least one heat exchanger sink over the selected time period, and wherein optimizing further comprises optimizing based upon the predicted efficiency. 11. The method of claim 10, wherein optimizing based upon the predicted efficiency comprises optimizing such that an energy efficiency ratio of the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink is between 75 and 100. 12. The method of claim 1, wherein the simulation includes an envelope of the building, fume hood controls, or lighting configuration. 13. The method of claim 1, wherein the simulation includes various wall constructions, window placement, roof insulations, or lighting configurations. 14. The method of claim 1, further comprising predicting CO2 emission of the heating and cooling system when using the at least one geothermal heat exchanger source and the at least one heat exchanger sink over the selected time period, and wherein optimizing further comprises optimizing based upon the predicted CO2 emission. 15. The method of claim 1, further comprising predicting a building energy footprint when using the at least one geothermal heat exchanger source and the at least one heat exchanger sink over the selected time period, and wherein optimizing further comprises optimizing based upon the predicted building energy footprint. 16. The method of claim 1, further comprising predicting a building electrical usage when using the at least one geothermal heat exchanger source and the at least one heat exchanger sink over the selected time period, and wherein optimizing further comprises optimizing based upon the predicted building electrical usage. 17. The method of claim 1, wherein determining a cost of operating comprises estimating maintenance costs and energy costs. 18. The method of claim 1, further comprising obtaining building information including the size of building, and wherein predicting a thermal energy demand of the building for a selected time period comprises predicting based upon building information. 19. A method of designing a geothermal heating and cooling system to heat or cool a building, comprising: selecting at least one geothermal heat exchanger source;selecting at least one geothermal heat exchanger sink;predicting a thermal energy demand of the building for a selected time period;predicting a thermal energy loss and gain for of the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink over the selected time period to meet the predicted thermal energy demand;determining a cost of installing and operating the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink based upon the predicted thermal energy loss and gain;predicting, using a controller, an energy efficiency of use of the at least one geothermal heat exchanger source and the at least one geothermal heat exchanger sink over the selected time period;optimizing, using the controller, a type, interconnectivity, or size of the at least one geothermal heat exchanger source or the at least one geothermal heat exchanger sink based upon the determined cost and the predicted efficiency; andgenerating, using the controller, a geothermal heating and cooling system design that includes the optimized at least one geothermal heat exchanger source and the optimized at least one geothermal heat exchanger sink. 20. The method of claim 19, wherein predicting a thermal energy demand or predicting a thermal energy loss comprises predicting expected load.