Athletic activity monitoring device with energy capture

We claim: 1. An energy harvesting device configured to be integrated into an item of clothing, comprising: an insulated container, comprising: an outer membrane comprising an outer surface and an inner surface, the outer surface being in contact with an external environment; an inner membrane, spaced apart from the outer membrane, having an outer surface and an inner surface; an outer cavity spaced between the outer membrane and the inner membrane; an aperture extending from the outer surface of the outer membrane to the inner surface of the outer membrane, the aperture configured to permit an ingress of air and water from the external environment into the outer cavity; an inner cavity encapsulated by the inner membrane; an outer heat exchanger extending through the inner membrane, the inner membrane sealed around at least a portion of the outer heat exchanger; a thermoelectric generator positioned within the inner cavity, the thermoelectric generator thermally coupled to the outer heat exchanger at a first side and thermally coupled to an inner heat exchanger at a second side; and an expandable membrane encapsulating a mass of phase change material, at least a portion of the expandable membrane coupled to the inner heat exchanger, wherein the outer heat exchanger, the thermoelectric generator, and the inner heat exchanger are configured to allow bi-directional conduction of heat between the mass of phase change material and the external environment, wherein the aperture is configured to allow water to enter into the outer cavity during a wash cycle as the item of clothing is laundered, and wherein the phase change material is configured to store a portion of heat energy captured during a dryer cycle as the item of clothing is laundered. 2. The energy harvesting device of claim 1 , wherein the aperture is substantially aligned with a primary axis of conduction of the insulated container. 3. The energy harvesting device of claim 1 , further comprising: an open-cell foam positioned within the outer cavity. 4. The energy harvesting device of claim 1 , wherein at least a portion of the outer heat exchanger extends through the outer membrane and is in contact with the external environment. 5. The energy harvesting device of claim 1 , wherein a mass of water retained within the outer cavity during the wash cycle is configured to evaporate during the dryer cycle, and such that the thermoelectric generator and the expandable membrane are exposed to a temperature range below a failure temperature. 6. The energy harvesting device of claim 5 , wherein water vapor is configured to escape from the outer cavity through the aperture. 7. The energy harvesting device of claim 1 , wherein the outer membrane and the inner membrane comprise an impermeable material. 8. The energy harvesting device of claim 1 , wherein ingress of air and water from the external environment into the outer cavity occurs at an external environmental pressure of approximately 1 atm or less. 9. The energy harvesting device of claim 1 , wherein ingress of air and water from the external environment into the outer cavity occurs at an external environmental pressure of approximately 1 atm or more. 10. The energy harvesting device of claim 1 , wherein ingress of water from the external environment into the outer cavity is by capillary action. 11. The energy harvesting device of claim 1 , wherein the expandable membrane facilitates thermal expansion of the phase change material within the inner cavity. 12. The energy harvesting device of claim 1 , further comprising an activity monitoring circuit coupled within the cavity, and provided with electrical energy by the thermoelectric generator. 13. The energy harvesting device of claim 1 , wherein the dryer cycle has a mean temperature of 45-85 degrees Celsius. 14. An energy harvesting device, comprising: an insulated container, comprising: a permeable outer membrane comprising an outer surface and an inner surface; an inner membrane, spaced apart from the outer membrane, having an outer surface and an inner surface; an outer cavity, at least partially filled with open-cell foam, spaced between the outer membrane and the inner membrane; an inner cavity encapsulated by the inner membrane; a thermoelectric generator positioned within the inner cavity, the thermoelectric generator thermally coupled to an outer heat exchanger at a first side and an inner heat exchanger at a second side; and an expandable membrane encapsulating a mass of phase change material, at least a portion of the expandable membrane coupled to the inner heat exchanger, wherein the outer heat exchanger, the thermoelectric generator, and the inner heat exchanger are configured to allow bi-directional conduction of heat to and from the phase change material, wherein the permeable outer membrane is configured to allow water to soak into the open-cell foam, and wherein the phase change material is configured to store a portion of heat energy captured from an external environment having a mean temperature in a range of approximately 45-85 degrees Celsius. 15. The energy harvesting device of claim 14 , wherein a mass of water retained within the open-cell foam is configured to protect the thermoelectric generator and the expandable membrane from being exposed to a temperature of air in the external environment above a failure temperature. 16. The energy harvesting device of claim 14 , wherein at least a portion of the outer heat exchanger is exposed to the outer cavity. 17. The energy harvesting device of claim 14 , wherein at least a portion of the outer heat exchanger is exposed to the external environment. 18. The energy harvesting device of claim 14 , wherein the inner membrane is impermeable. 19. The energy harvesting device of claim 14 , wherein the inner and outer heat exchangers comprise an aluminum alloy. 20. The energy harvesting device of claim 14 , wherein the phase change material comprises a salt-hydrate. 21. The energy harvesting device of claim 14 , wherein the insulated container is configured to be positioned within or on an item of athletic apparel. 22. The energy harvesting device of claim 14 , wherein the inner heat exchanger comprises at least one fin in contact with the phase change material. 23. The energy harvesting device of claim 14 , wherein the thermoelectric generator further comprises a rectifier circuit configured to output a voltage with a same polarity as heat energy is transferred into and out from the insulated container. 24. The energy harvesting device of claim 14 , wherein the phase change material is configured to reach an approximate thermal equilibrium with the external environment at approximately 20 degrees Celsius within at least 4 hours. 25. An energy harvesting device, comprising: an insulated container, comprising: an outer membrane comprising an outer surface and an inner surface; an inner membrane, spaced apart from the outer membrane, having an outer surface and an inner surface; an outer cavity, spaced between the outer membrane and the inner membrane; an inner cavity encapsulated by the inner membrane; a thermoelectric generator module positioned within the inner cavity, the thermoelectric generator thermally coupled to an expandable membrane that encapsulates a mass of phase change material, wherein the outer membrane is configured to allow a liquid to enter into the