This a continuation of application Ser. No. 10/100,489.
In summary this invention has ten recognizable advantages which out weighed the present invention. (1) The present automobile pollutants which is hydrocarbons, carbon monoxide, carbon dioxide, which deplete our ozone layer is totally eliminated. (2) Water is not a pollutant and by venture of its nature of the water cycle will continue to exist forever. (3) By using water molecule which is hydrogen, automobiles could be powered and by recycling the end product which is hydrogen dioxide to mix with oxygen and atmospheric air, water is obtained. (4) If perhaps there would be a run off of excess water via the overflow pipe, that, is not a pollutant and returns to the water cycle. (5) Reduced operational cost, water is available at reduced cost.
(6) Recycled water does not permit constant addition of water in the tank. (7) The vehicle produces its combustible hydrogen which is the main fuel and so constant fueling is eliminated. (8) Fire risk is reduced as water stations and transporting water has apparently less or no risk. (9) Reduced weight due to re-cycling of water, bulky tanks, may not be necessary. (10) If hydrogen tank is full before the electrolysis device malfunctions, car would be running for days allowing the operator time for maintenance.
The only disadvantage associated with this device is when the hydrogen tank is empty when the electrolysis device has malfunctioned, the car will stall until a new device is installed, this however is not a serious disadvantage considering the advantages which is overwhelming.
The details of the invention are described in connection with the accompanying drawings in which:
Components
A water tank is provided to store the water for fuel for the engine. The electrolysis unit converts the water to hydrogen and oxygen. A plastic tank re-enforced with steel metal, connecting plastic pipes also re-enforced via hydrogen pump to the injectors. Three non-return valves are components of the system. A water heater is installed into the water tank to maintain it at room temperature. An air pump and a converter are used to convert oxygen to water. A film of water cushion in a plastic tank surrounds the entire hydrogen tank to maintain hydrogen in the tank at room temperature.
Operation
An alternative fuel- water- is filled in the water tank (A), this leads into the electrolysis device (C) via pipe (B). Two outlet ports (D) and (E) carry hydrogen and oxygen. The hydrogen passes via a non-return valve to a plastic tank (F)—a non absorbent material to hydrogen—to a hydrogen pump (G) and to the injectors 1, 2, 3, and 4. As shown in
When water flows from tank to electrolysis device (C), water is exploded into oxygen (−) and hydrogen (+). The hydrogen flows through a non-return valve to a hydrogen tank (F) and the pump (G) sends it to the injectors 1,2,3,4, See
Induction
Referring to
Compression
When the piston ascends on compression stroke, both valves are closed and a high temperature is built up in the compressed air.
Power
As the piston is close to top dead center of the cylinder, hydrogen via the injector nozzle is sprayed into the compressed air according to the firing order. Just after then an accurately timed spark occurs from a spark plug which ignites the hydrogen. Expansion and pressure of gases occurs and the piston descends on a downward stroke. Both valves are closed.
Exhaust
As the piston ascends, the exhaust valve opens and the hydrogen dioxide (HO) enters the exhaust pipe. On reaching the oxygen discharged from the electrolysis device via pipe (J), it becomes water and flows into the converter (L). A blast of air from the air pump (M), compensates for the oxygen that may be required to convert more water vapor to water. This water flows back into the water tank to be re-used. The accurately timed spark is controlled by conventional electronic means utilized in automobiles.
An overflow pipe installed to the water tank allows excess water to flow out to the ground.
As shown in
Number | Name | Date | Kind |
---|---|---|---|
3608660 | Smith et al. | Sep 1971 | A |
5119768 | Russell | Jun 1992 | A |
6155212 | McAlister | Dec 2000 | A |
6257175 | Mosher et al. | Jul 2001 | B1 |
6314732 | Lookholder | Nov 2001 | B1 |
Number | Date | Country |
---|---|---|
10-176796 | Jun 1998 | JP |
Number | Date | Country | |
---|---|---|---|
20020170820 A1 | Nov 2002 | US |