Thermoelectric methods to control temperature of batteries

The invention claimed is: 1. A method of controlling a temperature of a battery, comprising: providing a thermoelectric device that is part of a thermoelectric module; providing a thermal spreader that is part of said thermoelectric module and that is in direct contact conductive heat transfer with said battery, said thermal spreader being parallel spaced from a first surface of said thermoelectric device such that the first surface of said thermoelectric device is thermally coupled with a portion of a surface of said battery via said thermal spreader; providing a first air duct that is between said thermoelectric device and said thermal spreader in said thermoelectric module, said first air duct thermally coupling said first surface of said thermoelectric device in convective heat transfer with said battery via an airflow path; providing a second air duct that is between said thermoelectric device and an outer wall of said thermoelectric module, said second air duct thermally coupling a second surface of said thermoelectric device to the ambient atmosphere through said second air duct; measuring an actual temperature of said battery; comparing said actual temperature to a reference temperature for said battery; heating said battery by operation of said thermoelectric device through said conductive heat transfer and convective heat transfer when said actual temperature is less than said reference temperature; and cooling said battery by operation of said thermoelectric device through said conductive heat transfer and convective heat transfer when said actual temperature exceeds said reference temperature. 2. The method of claim 1 further comprising providing an enclosure for the battery having at least one controllable vent and retaining heat in said battery when said actual temperature is less than said reference temperature by closing said controllable vent. 3. The method of claim 1 further comprising providing an enclosure for the battery having at least one controllable vent and venting heat from said battery when said actual temperature exceeds said reference temperature by opening said controllable vent. 4. The method of claim 1 further comprising retaining heat in said battery when said actual temperature is less than said reference temperature and venting heat from said battery when said actual temperature exceeds said reference temperature. 5. The method of claim 1 further comprising thermally insulating said battery from environmental heat. 6. The method of claim 1 further comprising dissipating heat from said thermoelectric device. 7. The method of claim 6 further comprising thermally insulating said battery from environmental heat, retaining heat in said battery when said actual temperature is less than said reference temperature and venting heat from said battery when said actual temperature exceeds said reference temperature. 8. The method of claim 1 wherein said comparing said actual temperature to a reference temperature for said battery comprises calculating a temperature difference by subtracting said reference temperature from said actual temperature and cooling said battery when said temperature difference is a positive value, and heating said battery when said temperature difference is a negative value. 9. A method of controlling a temperature of a battery, comprising: providing a thermoelectric device that is part of a thermoelectric module; providing a thermal spreader that is part of the thermoelectric module and that is in direct contact conductive heat transfer with said battery, said thermal spreader being spaced from a first surface of said thermoelectric device such that the first surface of said thermoelectric device is thermally coupled with a portion of a surface of said battery via said thermal spreader; providing an air flow duct that is between said thermoelectric device and said thermal spreader in said thermoelectric module and that thermally couples the first surface of said thermoelectric device in convective heat transfer with said battery via an airflow path; thermally insulating said battery from environmental heat; measuring an actual temperature of said battery; establishing a reference temperature for said battery; calculating a temperature difference by subtracting said reference temperature from said actual temperature; heating said battery by operation of said thermoelectric device through said conductive and convective heat transfer when said temperature difference is a negative value; and cooling said battery by operation of said thermoelectric device through said conductive and convective heat transfer when said temperature difference is a positive value. 10. The method of claim 9 further comprising providing an enclosure for the battery having at least one controllable vent and retaining heat in, said battery, when said actual temperature is less than said reference′temperature by closing said controllable vent. 11. The method of claim 9 further comprising providing an enclosure for the battery having at least one controllable vent and venting heat from said battery when said actual temperature exceeds said reference temperature by closing said controllable vent. 12. The method of claim 11 further comprising dissipating heat from said thermoelectric device through said conductive heat transfer, convective heat transfer and/or venting through said controllable vent. 13. A method as described in claim 1 further including protecting said thermal spreader from abrasion with said battery with a layer of adhesive backed fiber material. 14. A method as described in claim 1 further comprising packaging within said battery heat conductive strips. 15. A Method as described in claim 9 further comprising positioning said thermal spreader through an aperture provided in a thermal insulation of said battery to engage a direct contacting conductive heat transfer with a significant portion of an adjacent surface of said battery. 16. A method as described in claim 15 further including protecting said thermal spreader from abrasion with said battery with a layer of adhesive backed fiber Material. 17. A method as described in claim 9 further comprising packaging within said battery heat conductive strips.