Energy production and reduction of pollutants is one of the greatest challenges of our generation.
Populations continue to migrate towards urban areas and COP21 identified cities as key actors in the fight against climate change. Today, 55% of the world's population lives in cities while accounting for over 70% of the global carbon emission. This global trend towards urbanization is projected to continue beyond 2050, where two thirds of the world population will live. Electricity production in the United States alone is the greatest contributor of CO2 emissions with 67% being produced by fossil fuels (mostly coal and natural gas). Renewable sources only account for 14 percent of our production.
Energy costs are soaring and in some of the poorest countries, having a few lights on at home is a luxury. In large metropolitan areas energy consumption is highly regulated and limited to a few that can afford such luxuries. Electricity is too costly and it is too dirty to produce when relying mostly on fossil fuels.
The 21st Conférence des parties (COP) held in Paris in 2015 reinforced the need for global action to curtail the impact of human generated carbon emissions on the warming of our planet.
There are systems which will capture wind to convert into electricity as well as solar energy panels, or magnet generators and store such energy in batteries or the like to reduce the consumption of energy needs generally in residences. In most cases the energy produced by these systems is limited by the unreliability of wind and sun, thus homes in general continues to use partial electricity from the grid. In some cases the energy stored in the residences is in excess of the user requirements and, the user may sell the excess electricity back to the power supplier.
Unlike a house; a high-rise building requires an immense amount of electrical energy to power systems and spaces. Making a high-rise building its own power plant will remove the building from the grid and the recovery of the capital invested in the new system will far offset the cost of energy from power plants.
Making a high-rise building a power plant will also allow for high-rise building owners to produce excess amounts in order to sell energy to neighbors or buildings nearby. The method does not cause any pollution; rather it recycles water and waste.
Additionally; this method can be used in large ships such as cruise ships or even as large as aircraft carriers depending on the scale of the systems installed. Not only there are high winds in the ocean but a moving ship would add to the collection of wind power and follow the method as described.
The present invention relates to a method to produce electrical energy utilizing wind power as a source, converting kinetic energy into electrical energy to generate Hydrogen and Oxygen through electrolysis and using Hydrogen and Oxygen as fuel to produce steam to power steam turbines which will ultimately generate electrical power to provide electricity to a building.
To illustrate the system method a preferred embodiment of the invention is illustrated with the inclusion of the wind turbine apparatus U.S. Pat. No. 9,546,644 B2 as the wind capturing device; however it is to be understood that the description of the preferred embodiment contains many specifics for the purpose of illustration; a person of ordinary skill in the art will appreciate that many variations and alterations to the following details are within the scope of the invention. Accordingly, the following preferred embodiments of the invention are set forth without loss of generality to, and without imposing limitations upon the claimed invention.
The DC output of the generators 5 is controlled and regulated by 8 equipment appropriate to maintain optimal electrical current levels for the purpose of using such DC current for electrolysis of a fluid. Cathode 7 and Anode 6 carry the electrical current from the generators 5 to the electrolyzer 14 further described in
Water mixed with Urea 9 from Urinals 10 contains solids which are filtered and stored in tanks 12 for as needed demand. Water and Urea 9 after being filtered and stored are released as needed into the electrolyzer 14 through pipes 13 to maintain the level of fluid 15. Valve 21 senses the level of water and acidity in the electrolyzer and opens or closes the exit of fluid to sewer through waste pipe 22 or stops the flow of mix 9 into the electrolyzer 14. Community water may be used when the available mix 9 is in short supply. Valve 23 senses that the level of the fluid 15 has fallen below an established level and allows community water to enter the electrolyzer 14. To maintain the acidity of the fluid 15 when necessary a catalyst 28 is stored in tank 25 which supplies community water the needed level of acidity to maintain electrolysis at an optimum level of efficiency.
Cathode 7 and Anode 6 when submerged in the fluid 15 will split water into Oxygen 17 and Hydrogen 18 which are compressed by compressors 19 and 20 respectively. Compressed Hydrogen flows through pipe 29 to a plurality of tanks 27. Hydrogen from pipe 29 is partially deviated through pipe 29-A and it is ignited in burners 16 in order to raise the temperature of the fluid and further optimize the production of Oxygen 17 and Hydrogen 18. Compressed Oxygen 17 flows through pipe 30 into a plurality of storage tanks 26. Valve 31 stops compressor 19 when pressure on the plurality of tanks 26 has reached its established maximum. Similarly; valve 24 stops compressor 20 when pressure on the plurality of Hydrogen storage tanks has reached its established level. Switch 33 as a safety precaution automatically cuts of the power from cathode 7 and anode 6 when storage tanks 26 and 27 have reached their maximum established pressure and electrolysis stops. Pipe 32 connects together the plurality of tanks and releases pressure between tanks to keep the pressure of first tank at a highest level before Oxygen 17 or Hydrogen 18 flow into a second tank and so on.
Compressed Hydrogen 18 and Oxygen 17 are released from the plurality of tanks in high pressure lines 34 and 37 respectively to a combustion chamber 38 further described in
Steam turbine 40 generates kinetic power which is converted into electrical energy by generator 41 and then converted into AC current to power the high-rise building 1.
The present patent application is a continuation in part of provisional U.S. patent application No. 62/411,305 filed on Oct. 21, 2016, the disclosure of which herein is incorporated by reference to the extent not inconsistent with the present disclosure.
Number | Date | Country | |
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62411305 | Oct 2016 | US |