Regenerative fuel cell technology
First Claim
1. A power supply for a plug-in hybrid electric vehicle consisting of a battery pack capable of providing a power output between 20 and 1000 kW, a fuel cell capable of providing a power output between 0.2 and 20 kW, a hydrogen fuel tank with a rated capacity rated in miles of travel at an average city fuel economy rating where the rated capacity in miles is equal to between 4.5 and 18 times the fuel cell maximum power rating in kW, and a control means that utilizes the power output of the battery pack to provide the high power needs of the vehicle and uses the fuel cell as a battery charger to charge the battery pack.
0 Assignments
0 Petitions
Accused Products
Abstract
For a mobile fuel cell system a narrow-gap modular approach allows reforming to be performed in the same architecture as the fuel cell. A regenerative fuel cell operates much like a battery using electrical power to produce hydrogen and oxygen. The preferred mode of using the regenerative fuel cell is as a battery charger since this application is able to use a much smaller fuel cell than is required to power the vehicle. A novel equilibrating tank between the electrolysis oxygen and hydrogen tanks allows pressurized oxygen and hydrogen to be used without mechanical compression equipment.
-
Citations
17 Claims
-
1. A power supply for a plug-in hybrid electric vehicle consisting of
a battery pack capable of providing a power output between 20 and 1000 kW, a fuel cell capable of providing a power output between 0.2 and 20 kW, a hydrogen fuel tank with a rated capacity rated in miles of travel at an average city fuel economy rating where the rated capacity in miles is equal to between 4.5 and 18 times the fuel cell maximum power rating in kW, and a control means that utilizes the power output of the battery pack to provide the high power needs of the vehicle and uses the fuel cell as a battery charger to charge the battery pack.
-
5. An improved fuel cell power system using an air separator to supplement a stored electrolysis oxygen supply consisting of
a pressurized regenerative fuel cell capable of producing hydrogen through hydrolysis of water and producing electrical power through electrochemical reactions of oxygen and a fuel, an electrolysis oxygen tank capable of storing between 0.2 and 100 kilograms of oxygen, an air-separated oxygen tank capable of storing between 0.2 and 100 kilograms of oxygen, an air separator capable of separating air into at least one oxygen stream having a purity of at least 50 wt % oxygen, a hydrogen storage tank, a liquid fuel storage tank containing a liquid fuel, and a control means that directs the utilization of at least 70% of the stored hydrogen and stored electrolysis oxygen before switching to the use of air-separated oxygen and liquid fuel where the pressurized regenerative fuel cell is capable of operating at pressures greater than 5 bars of pressure.
-
8. The system according to 7 where the liquid fuel is a short chain alcohol.
-
9. The system according to 8 where the liquid fuel is comprised of methanol, ethanol, or a mixture of methanol and ethanol.
-
10. The system according to 5 where the liquid fuel is converted to hydrogen prior to use by the fuel cell.
-
11. The system according to 5 where the air separator is a membrane system comprised of at least one membrane and at least one compression means.
-
13. The fuel cell power system according to 12 where the last fuel cell group has a higher ratio of mass of catalyst to surface area of membrane than the first fuel cell group.
-
14. The fuel cell power system according to 12 where a recycle stream connects the cathode exit of the last fuel cell group to the air separator where oxygen in the recycle stream is separated in the air separator and is returned to the fuel cell group.
-
15. A regenerative fuel cell system consisting of
a pressurized regenerative fuel cell capable of producing hydrogen through hydrolysis of water and producing electrical power through electrochemical reactions of oxygen and a fuel, a pressurized electrolysis oxygen tank capable of storing between 0.2 and 100 kilograms of oxygen and having a oxygen tank volume consistent with storing the oxygen at a pressure between 50 and 500 bars of pressure, a pressurized hydrogen storage tank capable of storing between 0.025 and 12.5 kilograms of hydrogen and having a hydrogen tank volume consistent with storing the hydrogen at a pressure between 50 and 500 bars of pressure where the ratio of the volume of the hydrogen tank to the oxygen tank is between 1: - 1.6 and 1;
2.1,a line with one end connecting the bottom of the hydrogen tank and a second end connected to the oxygen tank where the line is filled with a liquid that freely flows between the two tanks and equilibrates the pressures of the two tanks. - View Dependent Claims (16, 17)
- 1.6 and 1;
Specification