Appliance with refuelable and rechargeable metal-air fuel cell battery power supply unit integrated therein

Abstract

A device / system having an integrated refuelable and rechargable metal-air FCB based power supply unit for generating and providing electrical power to at least one electrical-energy-consuming load device disposed therein. An external power source is used to recharge the metal-air FCB subsystems embodied therein. A control subsystem automatically transitions between discharging mode (wherein at least one metal-air FCB subsystem supplies electrical power to the electrical power-consuming load device) and a recharging mode (wherein the external power source is electrically coupled to at least one metal-air FCB subsystem to thereby recharge the metal-air FCB subsystem(s). The metal-air FCB subsystem(s) are refueled by manually loading and unloading metal-fuel from the metal-air FCB subsystem(s). Preferably, electrical power provided to the at least one electrical power-consuming load device is supplied solely by electrical power generated by discharging metal-fuel in the metal-air fuel cell battery subsystem(s). In addition, the metal-air FCB subsystem(s) preferably has a modular architecture that enable flexible and user-friendly operations in loading of metal-fuel, unloading of consumed metal-fuel, replacement of the ionic-conducting medium, and replacement of the cathode.

Description

RELATED CASES[0001] This Application is related to U.S. patent application Ser. No. 09 / 695,698, assigned to Reveo, Inc. and entitled "Refuelable And Rechargeable Metal-Air Fuel Cell Battery Power Supply Unit For Integration Into An Appliance., and to U.S. patent application Ser. No. 09 / 695,699, assigned to Reveo, Inc. and entitled "POWER GENERATION AND DISTRIBUTION SYSTEM / NETWORK HAVING INTERRUPTABLE POWER SOURCE AND REFUELABLE AND RECHARGEABLE METAL-AIR FUEL CELL BATTERY SUBSYSTEM", filed concurrently herewith.[0002] 1. Field of the Invention[0003] The present invention relates to improved methods and systems for electrochemically producing electrical power using metal-air fuel cell battery (FCB) technology.[0004] 2. Description of the Related Art[0005] An ever-expanding range of electrical systems and devices are vital to the normal continuation of daily life for individuals and businesses in today's society. Such systems and devices include portable devices (radio / tape / CD / DVD sys...

AI Technical Summary

Benefits of technology

[0016] Accordingly, a prime object of the present invention is to substitute the traditional power supply units and methodologies (typically, one or more switching power regulators) integrated in an electrical system or device with an integrated power supply unit comprising one or more rechargeable and refuelable metal-air FCB-based subsystems. This solution is, energy efficient, environmentally-friendly, and reliable, thus enabling consumers to use the system / device without the risk and limitations of prolonged interruption. Moreover, the solution is cost-effect because it eliminates the need for auxiliary power generation systems by integrating the rechargeable and refuelable metal-air FCB-based subsystem into the system / device. The electrical system or device may be a computer processing apparatus, a portable electronic device (such as radio, disc player, other music playing devices, camcorder, other video playing / recording devices, telephone, PDA, other communication devices), an appliance (such as television, audio equipment, washing machine, refrigerator, freezer, oven, stove, furnace, air conditioner) or an electrically-powered tool.

Problems solved by technology

However, the reliability of this power grid is fragile and can be compromised by unpredictable severe weather (snow / ice storms, earthquakes, tornadoes, hurricanes), system failure (excessive demand, lack of supply of natural gas to generation systems) and / or human error.

Ice accumulation on trees and overhead lines caused hundreds of millions of dollars of damage in both the United States and Canada and left hundreds of thousands of people without power for periods ranging from a few hours to more than three weeks.

In another example, during the unusually hot summer of 1988, the power infrastructure of Auckland, New Zealand unpredictably could not handle the stress caused by the extreme demand, and the aging underground transmission cables that were vital to feeding the city with electricity failed in succession.

Thus, previous failures of the power grid have shown that the disruptions caused by such failures can be massive, especially if the failures are prolonged.

However, the reliability of many of these alternate power generation systems is also fragile.

For example, the supply of power from solar-powered generation systems / wind-powered generation systems / hydroelectric generation systems can be unpredictably interrupted for prolonged periods of time due to weather conditions (lack of sunlight / lack of wind / severe drought conditions).

In such systems, interruptions can lead to unwanted disruptions, especially if the interruptions are prolonged.

These systems too have serious limitations.

More specifically, auxiliary power generation devices that use conventional battery technology (lead acid, nickel-cadmium, or nickel-metal hydrides) have limited operation time, long recharge time, and low energy density; thus making such devices impractical for many applications.

Moreover, replacement of such batteries is costly and raises numerous environmental hazards (that typically are dealt with using special encapsulation containers and careful disposal).

Similarly, auxiliary power generation devices that use combustible fuel (such as gasoline and diesel engine generators) are costly, heavy, loud, emit noxious gases and fumes; thus making such devices impractical for many applications.

Moreover, such devices raise numerous environmental and safety hazards related to the transportation and use of the combustible fuels used therein.

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