CA2681645A1 - New energies - Google Patents
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- Publication number
- CA2681645A1 CA2681645A1 CA2681645A CA2681645A CA2681645A1 CA 2681645 A1 CA2681645 A1 CA 2681645A1 CA 2681645 A CA2681645 A CA 2681645A CA 2681645 A CA2681645 A CA 2681645A CA 2681645 A1 CA2681645 A1 CA 2681645A1
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- Prior art keywords
- water
- plasma
- heat
- boiler
- hose
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
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-
- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05H—PLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
- H05H1/00—Generating plasma; Handling plasma
- H05H1/02—Arrangements for confining plasma by electric or magnetic fields; Arrangements for heating plasma
- H05H1/10—Arrangements for confining plasma by electric or magnetic fields; Arrangements for heating plasma using externally-applied magnetic fields only, e.g. Q-machines, Yin-Yang, base-ball
-
- G—PHYSICS
- G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
- G21B—FUSION REACTORS
- G21B1/00—Thermonuclear fusion reactors
- G21B1/11—Details
- G21B1/23—Optical systems, e.g. for irradiating targets, for heating plasma or for plasma diagnostics
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E30/00—Energy generation of nuclear origin
- Y02E30/10—Nuclear fusion reactors
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- Physics & Mathematics (AREA)
- Engineering & Computer Science (AREA)
- Plasma & Fusion (AREA)
- Optics & Photonics (AREA)
- Spectroscopy & Molecular Physics (AREA)
- General Engineering & Computer Science (AREA)
- High Energy & Nuclear Physics (AREA)
- Physical Or Chemical Processes And Apparatus (AREA)
Abstract
We could use an intense plasma laser to start the reaction and keep it running...
1. First we start with the regular hydrogen atoms colliding creating helium and creating energy 2. Largest magnet ever tried surrounding the plasma.
3. The magnet can be one solid (thick walled) case surrounding the plasma in a vertically standing cylinder design, or change shape with to suit the roundness of the plasma so the magnet force is even.
4. In the bottom is a magnet floor (cradle possibly for stability having thick enough in its walls to support the magnets above) possibly with a small pool of water and/or source of water via nozzle such that the water clears the plasma, so it doesn't touch the plasma (rather it vaporizes because of the heat of the plasma).
5. Surrounding the outside of the magnet layer (the magnet's outer surface can be coated with a layer of ceramic to counter rust) is a huge boiler which is fed water (possibly salt water to produce disinfected water and fresh water), at bottlenecks, the boiler can be huge to absorb the heat from the plasma and also fast moving to keep any one contained area the salt water (possibly other liquids such as ethanol), from overheating (the expanding heat pressure turns the turbine).
6. There are large (robot controlled) slit/opening (such as sliding visors) at intervals from top to bottom that penetrate through the surrounding magnet that can be open and shut... closed when the plasma is not too cold and/or the salt water is too cold and open to cool off the plasma or heat the boiler more efficiently to expand heat pressure to turn turbine.
7. At the top can be an (oversized) roof platform with ceramic coating and and/or magnet also with open and (robot controlled) shut slits that increase or decrease heat into an exhaust. Above the roof is a boiler pool with exhaust that feed into a turbine. Salt water (and/or other liquid) is fed into the boiler. The roof is needed to be (possibly slide) opened especially when the pool of water below the plasma has vaporized and is causing increased expanded water pressure in the plasma core.
8. An extra layer of boiler can encapsulate the main boiler this extra layer of boiler can be made of ceramic on the outside to add extra layer from overheating the compartment holding the inner plasma chamber. The extra outer layer can also fill its outer chamber with salt water any and all liquids (even ethanol) to expand pressure to spin turbine (eg. and fresh/disinfected water).
9. Alternatively if the boiler is large enough (enough water sandwiched between plasma core (magnets) and the boiler's walls the inside of the boiler walls can be lined with nanotube solar panels (that can withstand the extreme heat.
10. Additionally the more close contact/exposure material is to the plasma core the more heat resistant the material must be (eg.
the magnets) therefore we will attempt to mix the magnet material the closer the more density per volume of magnet material mixed with carbon nano particles-tubes (even mix the molten magnet with diamond dust) used as heat sinks in electric motors to withstand motors' intense heat. The tiny structures embedded in materials regularly called upon to withstand extreme heat, such as those that form the exterior panels of airplanes and rockets. In the worse scenario we could mix and make diamond/nano particles-tubes shield in front of the magnets facing the plasma core... Since diamonds are so expensive we might need to play around with the sizes of the plasma core. The carbon nano particles-tubes are added as a cheap cutting cost measure to diamonds.
11. We could also layer a thin layer of either diamonds (container) and a thin layer of carbon nano particles-tubes (with openable slits to vent heat from the plasma core and introduce heat to the outer boilers). The layers of the diamonds and/or carbon nano particles-tubes insulate the magnet(s)...
12. Another material to explore is ceramics mixed with nanotubes The material shows electrical conductivity ten trillion times greater than pure alumina, and seven times that of previous ceramics made with nanotubes. Thermal properties, enable conducting heat in one direction, along the alignment of the nanotubes, but reflecting heat at right angles to the nanotubes, making it an attractive material for thermal barrier coatings. This seems the ideal low cost insulator to protect the magnets from overheating while conducting the magnets force back towards the plasma core.
13. On top of the roof (above the plasma core) is a boiler where salt water (And/or liquids such as ethanol) is entered at high volume to boil to steam to turn turbines with possible walls made of nanotubes that absorb heat and convert into energy.
(GP 0.24%) 14. Any and all components can be composed of ceramics, titanium, tungsten steel, carbon nano materials, magnets and/or diamonds (GP 0.1 %).
15. We could also use walls of water falling.
16. The walls of water falling unlike filling a choking/smothering the entire container in a tank/boiler (pool of) with water; can touch and cool off the magnets without smothering out the plasma core. In fact we could adjust the walls of water to vaporize before collecting at the bottom, so the is no rising level of pool of water on the floor of the boiler that surrounds/holds the magnets which in turn hole the plasma core within.
17. To keep one side from getting hotter than the other sides we could use more water on the overheated face to cool the hotter side...
One hydrogen source is from any and all metals (eg aluminium, zinc... ), reacting with in a strong acid (eg. muriatic acid), producing hydrogen gas while crystal remains. The crystal can be used for any and all uses, from decorative, ornamental and any and all aesthetic, parts of walls, parts of interior furniture and fixtures, casings of electronics (and anything - objects -that are expensive are the slightest form of status and prestige symbol), jewelry, substitute metal and wood, eg. door knobs, sculptures, and decorative car interior/exteriors...
The helium output can be used to power cars, and it has no moving parts. It runs by "thermoacoustics" we simply apply external heat to a cylinder or tank (treat can come from the plasma core production and/or mirrors) with the Helium gas (which is a by-product of the hydrogen atoms colliding) inside the cylinder), as the gas heats up it generates the acoustic waves making enough heat to make steam and then it is used to generate electricity.
For cars the sound is converted into electricity, via steam. A microphone like devise, electo-acoustic transducer produces the sound waves. Which can be used to power cars without batteries. therefore no need to discard old batteries which cannot be charged, whereby electric cars without residual pollution later.
And/or use the helium directly as fuel. There considerable growth in demand for helium around the world, eg. medical, industrial and electronic use.
Re: Ocean/Seas (1. floors) Energy and/or 2. Hung from Above 1. We make (flatter) bladders that can be made of mix Teflon (for strength) and rubber for bounce back momentum when bent to much and too long, thus creating more bobbing frequency. The bladder can be filled with enough air to make it stable in water, neither too stringent floating up and/or less air in the hanging version (even slightly weighted at the bottom of the tip of each bladder unit), such that the bladders of the hanging version does not float buoyantly, but rather is the same density/mass as the water so it does not buoyantly float (in one direction and gets stuck there) but rather gets pushed from side to side (on a pivoting ball and socket - swaying) thus either pumping deep salt water (via deep pipe) to a platform and or seashore where the sea water can be used eg. (Gerard Voon's patented mirrors/boiler/turbine/fresh dienfected water) and/or desalination slat water membranes and/or used to grow (on floating barges) salt water tolerant plants such as mangrove and switch grass (salicornia) for biofuel/biomass...
2. Entire groupings of grids can be installed on the sea/ocean floors with pipes that are pumped powered by the bladders, with excess enegy stored in our platform and shipping vessel battery power plants above.
3. Alternatively a less buoyant version of the bladders can be hung upside down from floatation objects above, such as strung between platforms and/or barges and or bobbing grids.., the difference about our floating bladder bobbers and existing bobber grid technology is that the existing bobber grids partially float out of the water, making the that old technology vulnerable to high/strong waves, while our new bladder bobbers are except for solid neck are fully submersed underwater.
4. We could strategically place higher tidal spinning blades secured to posts that clear to the bobbing bladders, to catch the most wave power out of the ocean. We could also string cables from high posts to high posts (or between platforms) and hang spinning blades at frequent intervals, underwater. (GP 0.24%) Re: Floating-Hose Teflon Rubber Ringed 1. The hose is shaped (and/or helixical, square, round, rectangular, diamond and/or triangular... ) along its length like a shipping vessel such that the bottom is shaped like a hull (without the narrowing in absolute width on both ends.
2. The top is flat and is thicker with a rubber layer to maintain stability (spinning of the hose), at the mercy of the waves.
3. Along most of the length of the hose are a loose skin of thin Teflon and/or mixed with plastic and/or mixed with zip log material bags along the front end and then stronger material (eg. Teflon to Teflon/rubber mix on the turbine end).
4. Along its length are rings (whose size must balance its stiffness interfering with the wave squeezing the bulge - eg. large enough to allow the bulge to pass without disrupting (if too small, the rubber ring may bleed the bulge's force) also disrupting the squeezebility of the wave that is squeezing (bending the hose behind the bulge inwards) to result in being directed away from the hose (the vectors of the wave if the rubber rings are too big, may end up at or outwards of the perimeter of the rubber ring keeping in mind that the rubber rings may need to be wider than the alternate intervals of loose skin) while rubber rings their size and intervals are needed to provide support so the hose does not collapse inwardly.
5. Along its length in order maintain rigidity to keep the hose flexible with the waves while able to recover its orientation, (preventing collapsing and/or kinking, we line every sharp angle on the dissection of the perimeter of the hose all along the lengths with rubber (eg.
tube).
6. In the front of the hose is are flaps that open (can dip inwards in a curved gradual design to get water to siphon into the hole while the gaps between sharp corners allow water to pass to surround the the hose exterior length, thus providing squeezing pressure) outwards, such that waves inside the flap are directed into the hose opening, while wave flow outside the flaps directs flow towards the outside of the hose thus squeezing the bulge from outside the hose.(GP 0.25%) Re: Stirling Engine We could use helium waste (See pg. 165 Re: Fusion Reaction) from Fusion Reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood-to power Stirling Engine any and all mechanical and any and all things requiring power/energy...
On a large scale we could (Re: Battery Power Plant pg. 128 - for storage of the electricity produced and transport in large battery exchange programs with gas stations/parkades even delivery to homes/offices...any and all uses supplying fully charged batteries for used batteries like water cooler full for empty delivery and pick up, the delivery can even be like Automobile Association delivery to places where the member has run out of and/or low on low on energy) use helium waste (see pg. 165 Re: Fusion Reaction) from fusion reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood...
Re: Any and All contaminated land and Barren Land We could build solar panels and Gerard Voon's patented TALL GRAVITY TO
ELECTRICITY INVENTION, on empty land (eg. from mountaintop mining).
1. First we start with the regular hydrogen atoms colliding creating helium and creating energy 2. Largest magnet ever tried surrounding the plasma.
3. The magnet can be one solid (thick walled) case surrounding the plasma in a vertically standing cylinder design, or change shape with to suit the roundness of the plasma so the magnet force is even.
4. In the bottom is a magnet floor (cradle possibly for stability having thick enough in its walls to support the magnets above) possibly with a small pool of water and/or source of water via nozzle such that the water clears the plasma, so it doesn't touch the plasma (rather it vaporizes because of the heat of the plasma).
5. Surrounding the outside of the magnet layer (the magnet's outer surface can be coated with a layer of ceramic to counter rust) is a huge boiler which is fed water (possibly salt water to produce disinfected water and fresh water), at bottlenecks, the boiler can be huge to absorb the heat from the plasma and also fast moving to keep any one contained area the salt water (possibly other liquids such as ethanol), from overheating (the expanding heat pressure turns the turbine).
6. There are large (robot controlled) slit/opening (such as sliding visors) at intervals from top to bottom that penetrate through the surrounding magnet that can be open and shut... closed when the plasma is not too cold and/or the salt water is too cold and open to cool off the plasma or heat the boiler more efficiently to expand heat pressure to turn turbine.
7. At the top can be an (oversized) roof platform with ceramic coating and and/or magnet also with open and (robot controlled) shut slits that increase or decrease heat into an exhaust. Above the roof is a boiler pool with exhaust that feed into a turbine. Salt water (and/or other liquid) is fed into the boiler. The roof is needed to be (possibly slide) opened especially when the pool of water below the plasma has vaporized and is causing increased expanded water pressure in the plasma core.
8. An extra layer of boiler can encapsulate the main boiler this extra layer of boiler can be made of ceramic on the outside to add extra layer from overheating the compartment holding the inner plasma chamber. The extra outer layer can also fill its outer chamber with salt water any and all liquids (even ethanol) to expand pressure to spin turbine (eg. and fresh/disinfected water).
9. Alternatively if the boiler is large enough (enough water sandwiched between plasma core (magnets) and the boiler's walls the inside of the boiler walls can be lined with nanotube solar panels (that can withstand the extreme heat.
10. Additionally the more close contact/exposure material is to the plasma core the more heat resistant the material must be (eg.
the magnets) therefore we will attempt to mix the magnet material the closer the more density per volume of magnet material mixed with carbon nano particles-tubes (even mix the molten magnet with diamond dust) used as heat sinks in electric motors to withstand motors' intense heat. The tiny structures embedded in materials regularly called upon to withstand extreme heat, such as those that form the exterior panels of airplanes and rockets. In the worse scenario we could mix and make diamond/nano particles-tubes shield in front of the magnets facing the plasma core... Since diamonds are so expensive we might need to play around with the sizes of the plasma core. The carbon nano particles-tubes are added as a cheap cutting cost measure to diamonds.
11. We could also layer a thin layer of either diamonds (container) and a thin layer of carbon nano particles-tubes (with openable slits to vent heat from the plasma core and introduce heat to the outer boilers). The layers of the diamonds and/or carbon nano particles-tubes insulate the magnet(s)...
12. Another material to explore is ceramics mixed with nanotubes The material shows electrical conductivity ten trillion times greater than pure alumina, and seven times that of previous ceramics made with nanotubes. Thermal properties, enable conducting heat in one direction, along the alignment of the nanotubes, but reflecting heat at right angles to the nanotubes, making it an attractive material for thermal barrier coatings. This seems the ideal low cost insulator to protect the magnets from overheating while conducting the magnets force back towards the plasma core.
13. On top of the roof (above the plasma core) is a boiler where salt water (And/or liquids such as ethanol) is entered at high volume to boil to steam to turn turbines with possible walls made of nanotubes that absorb heat and convert into energy.
(GP 0.24%) 14. Any and all components can be composed of ceramics, titanium, tungsten steel, carbon nano materials, magnets and/or diamonds (GP 0.1 %).
15. We could also use walls of water falling.
16. The walls of water falling unlike filling a choking/smothering the entire container in a tank/boiler (pool of) with water; can touch and cool off the magnets without smothering out the plasma core. In fact we could adjust the walls of water to vaporize before collecting at the bottom, so the is no rising level of pool of water on the floor of the boiler that surrounds/holds the magnets which in turn hole the plasma core within.
17. To keep one side from getting hotter than the other sides we could use more water on the overheated face to cool the hotter side...
One hydrogen source is from any and all metals (eg aluminium, zinc... ), reacting with in a strong acid (eg. muriatic acid), producing hydrogen gas while crystal remains. The crystal can be used for any and all uses, from decorative, ornamental and any and all aesthetic, parts of walls, parts of interior furniture and fixtures, casings of electronics (and anything - objects -that are expensive are the slightest form of status and prestige symbol), jewelry, substitute metal and wood, eg. door knobs, sculptures, and decorative car interior/exteriors...
The helium output can be used to power cars, and it has no moving parts. It runs by "thermoacoustics" we simply apply external heat to a cylinder or tank (treat can come from the plasma core production and/or mirrors) with the Helium gas (which is a by-product of the hydrogen atoms colliding) inside the cylinder), as the gas heats up it generates the acoustic waves making enough heat to make steam and then it is used to generate electricity.
For cars the sound is converted into electricity, via steam. A microphone like devise, electo-acoustic transducer produces the sound waves. Which can be used to power cars without batteries. therefore no need to discard old batteries which cannot be charged, whereby electric cars without residual pollution later.
And/or use the helium directly as fuel. There considerable growth in demand for helium around the world, eg. medical, industrial and electronic use.
Re: Ocean/Seas (1. floors) Energy and/or 2. Hung from Above 1. We make (flatter) bladders that can be made of mix Teflon (for strength) and rubber for bounce back momentum when bent to much and too long, thus creating more bobbing frequency. The bladder can be filled with enough air to make it stable in water, neither too stringent floating up and/or less air in the hanging version (even slightly weighted at the bottom of the tip of each bladder unit), such that the bladders of the hanging version does not float buoyantly, but rather is the same density/mass as the water so it does not buoyantly float (in one direction and gets stuck there) but rather gets pushed from side to side (on a pivoting ball and socket - swaying) thus either pumping deep salt water (via deep pipe) to a platform and or seashore where the sea water can be used eg. (Gerard Voon's patented mirrors/boiler/turbine/fresh dienfected water) and/or desalination slat water membranes and/or used to grow (on floating barges) salt water tolerant plants such as mangrove and switch grass (salicornia) for biofuel/biomass...
2. Entire groupings of grids can be installed on the sea/ocean floors with pipes that are pumped powered by the bladders, with excess enegy stored in our platform and shipping vessel battery power plants above.
3. Alternatively a less buoyant version of the bladders can be hung upside down from floatation objects above, such as strung between platforms and/or barges and or bobbing grids.., the difference about our floating bladder bobbers and existing bobber grid technology is that the existing bobber grids partially float out of the water, making the that old technology vulnerable to high/strong waves, while our new bladder bobbers are except for solid neck are fully submersed underwater.
4. We could strategically place higher tidal spinning blades secured to posts that clear to the bobbing bladders, to catch the most wave power out of the ocean. We could also string cables from high posts to high posts (or between platforms) and hang spinning blades at frequent intervals, underwater. (GP 0.24%) Re: Floating-Hose Teflon Rubber Ringed 1. The hose is shaped (and/or helixical, square, round, rectangular, diamond and/or triangular... ) along its length like a shipping vessel such that the bottom is shaped like a hull (without the narrowing in absolute width on both ends.
2. The top is flat and is thicker with a rubber layer to maintain stability (spinning of the hose), at the mercy of the waves.
3. Along most of the length of the hose are a loose skin of thin Teflon and/or mixed with plastic and/or mixed with zip log material bags along the front end and then stronger material (eg. Teflon to Teflon/rubber mix on the turbine end).
4. Along its length are rings (whose size must balance its stiffness interfering with the wave squeezing the bulge - eg. large enough to allow the bulge to pass without disrupting (if too small, the rubber ring may bleed the bulge's force) also disrupting the squeezebility of the wave that is squeezing (bending the hose behind the bulge inwards) to result in being directed away from the hose (the vectors of the wave if the rubber rings are too big, may end up at or outwards of the perimeter of the rubber ring keeping in mind that the rubber rings may need to be wider than the alternate intervals of loose skin) while rubber rings their size and intervals are needed to provide support so the hose does not collapse inwardly.
5. Along its length in order maintain rigidity to keep the hose flexible with the waves while able to recover its orientation, (preventing collapsing and/or kinking, we line every sharp angle on the dissection of the perimeter of the hose all along the lengths with rubber (eg.
tube).
6. In the front of the hose is are flaps that open (can dip inwards in a curved gradual design to get water to siphon into the hole while the gaps between sharp corners allow water to pass to surround the the hose exterior length, thus providing squeezing pressure) outwards, such that waves inside the flap are directed into the hose opening, while wave flow outside the flaps directs flow towards the outside of the hose thus squeezing the bulge from outside the hose.(GP 0.25%) Re: Stirling Engine We could use helium waste (See pg. 165 Re: Fusion Reaction) from Fusion Reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood-to power Stirling Engine any and all mechanical and any and all things requiring power/energy...
On a large scale we could (Re: Battery Power Plant pg. 128 - for storage of the electricity produced and transport in large battery exchange programs with gas stations/parkades even delivery to homes/offices...any and all uses supplying fully charged batteries for used batteries like water cooler full for empty delivery and pick up, the delivery can even be like Automobile Association delivery to places where the member has run out of and/or low on low on energy) use helium waste (see pg. 165 Re: Fusion Reaction) from fusion reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood...
Re: Any and All contaminated land and Barren Land We could build solar panels and Gerard Voon's patented TALL GRAVITY TO
ELECTRICITY INVENTION, on empty land (eg. from mountaintop mining).
Description
DESCRIPTION
Re: Fusion Reaction We could use an intense plasma laser to start the reaction and keep it running...
18. First we start with the regular hydrogen atoms colliding creating helium and creating energy 19. Largest magnet ever tried surrounding the plasma.
20. The magnet can be one solid (thick walled) case surrounding the plasma in a vertically standing cylinder design, or change shape with to suit the roundness of the plasma so the magnet force is even.
21. In the bottom is a magnet floor (cradle possibly for stability having thick enough in its walls to support the magnets above) possibly with a small pool of water and/or source of water via nozzle such that the water clears the plasma, so it doesn't touch the plasma (rather it vaporizes because of the heat of the plasma).
22. Surrounding the outside of the magnet layer (the magnet's outer surface can be coated with a layer of ceramic to counter rust) is a huge boiler which is fed water (possibly salt water to produce disinfected water and fresh water), at bottlenecks, the boiler can be huge to absorb the heat from the plasma and also fast moving to keep any one contained area the salt water (possibly other liquids such as ethanol), from overheating (the expanding heat pressure turns the turbine).
23. There are large (robot controlled) slit/opening (such as sliding visors) at intervals from top to bottom that penetrate through the surrounding magnet that can be open and shut... closed when the plasma is not too cold and/or the salt water is too cold and open to cool off the plasma or heat the boiler more efficiently to expand heat pressure to turn turbine.
24. At the top can be an (oversized) roof platform with ceramic coating and and/or magnet also with open and (robot controlled) shut slits that increase or decrease heat into an exhaust. Above the roof is a boiler pool with exhaust that feed into a turbine. Salt water (and/or other liquid) is fed into the boiler. The roof is needed to be (possibly slide) opened especially when the pool of water below the plasma has vaporized and is causing increased expanded water pressure in the plasma core.
25. An extra layer of boiler can encapsulate the main boiler this extra layer of boiler can be made of ceramic on the outside to add extra layer from overheating the compartment holding the inner plasma chamber. The extra outer layer can also fill its outer chamber with salt water any and all liquids (even ethanol) to expand pressure to spin turbine (eg. and fresh/disinfected water).
26. Alternatively if the boiler is large enough (enough water sandwiched between plasma core (magnets) and the boiler's walls the inside of the boiler walls can be lined with nanotube solar panels (that can withstand the extreme heat.
27. Additionally the more close contact/exposure material is to the plasma core the more heat resistant the material must be (eg.
the magnets) therefore we will attempt to mix the magnet material the closer the more density per volume of magnet material mixed with carbon nano particles-tubes (even mix the molten magnet with diamond dust) used as heat sinks in electric motors to withstand motors' intense heat. The tiny structures embedded in materials regularly called upon to withstand extreme heat, such as those that form the exterior panels of airplanes and rockets. In the worse scenario we could mix and make diamond/nano particles-tubes shield in front of the magnets facing the plasma core... Since diamonds are so expensive we might need to play around with the sizes of the plasma core. The carbon nano particles-tubes are added as a cheap cutting cost measure to diamonds.
28. We could also layer a thin layer of either diamonds (container) and a thin layer of carbon nano particles-tubes (with openable slits to vent heat from the plasma core and introduce heat to the outer boilers). The layers of the diamonds and/or carbon nano particles-tubes insulate the magnet(s)...
29. Another material to explore is ceramics mixed with nanotubes The material shows electrical conductivity ten trillion times greater than pure alumina, and seven times that of previous ceramics made with nanotubes. Thermal properties, enable conducting heat in one direction, along the alignment of the nanotubes, but reflecting heat at right angles to the nanotubes, making it an attractive material for thermal barrier coatings. This seems the ideal low cost insulator to protect the magnets from overheating while conducting the magnets force back towards the plasma core.
30. On top of the roof (above the plasma core) is a boiler where salt water (And/or liquids such as ethanol) is entered at high volume to boil to steam to turn turbines with possible walls made of nanotubes that absorb heat and convert into energy.
(GP 0.24%) 31. Any and all components can be composed of ceramics, titanium, tungsten steel, carbon nano materials, magnets and/or diamonds (GP 0.1 %).
32. We could also use walls of water falling.
33. The walls of water falling unlike filling a choking/smothering the entire container in a tank/boiler (pool of) with water; can touch and cool off the magnets without smothering out the plasma core. In fact we could adjust the walls of water to vaporize before collecting at the bottom, so the is no rising level of pool of water on the floor of the boiler that surrounds/holds the magnets which in turn hole the plasma core within.
34. To keep one side from getting hotter than the other sides we could use more water on the overheated face to cool the hotter side...
One hydrogen source is from any and all metals (eg aluminium, zinc...), reacting with in a strong acid (eg. muriatic acid), producing hydrogen gas while crystal remains. The crystal can be used for any and all uses, from decorative, ornamental and any and all aesthetic, parts of walls, parts of interior furniture and fixtures, casings of electronics (and anything - objects -that are expensive are the slightest form of status and prestige symbol), jewelry, substitute metal and wood, eg. door knobs, sculptures, and decorative car interior/exteriors...
The helium output can be used to power cars, and it has no moving parts. It runs by "thermoacoustics" we simply apply external heat to a cylinder or tank (heat can come from the plasma core production and/or mirrors) with the Helium gas (which is a by-product of the hydrogen atoms colliding) inside the cylinder), as the gas heats up it generates the acoustic waves making enough heat to make steam and then it is used to generate electricity.
For cars the sound is converted into electricity, via steam. A microphone like devise, electo-acoustic transducer produces the sound waves. Which can be used to power cars without batteries, therefore no need to discard old batteries which cannot be charged, whereby electric cars without residual pollution later.
And/or use the helium directly as fuel. There considerable growth in demand for helium around the world, eg. medical, industrial and electronic use.
Re: Ocean/Seas (1. floors) Energy and/or 2. Hung from Above 5. We make (flatter) bladders that can be made of mix Teflon (for strength) and rubber for bounce back momentum when bent to much and too long, thus creating more bobbing frequency. The bladder can be filled with enough air to make it stable in water, neither too stringent floating up and/or less air in the hanging version (even slightly weighted at the bottom of the tip of each bladder unit), such that the bladders of the hanging version does not float buoyantly, but rather is the same density/mass as the water so it does not buoyantly float (in one direction and gets stuck there) but rather gets pushed from side to side (on a pivoting ball and socket - swaying) thus either pumping deep salt water (via deep pipe) to a platform and or seashore where the sea water can be used eg. (Gerard Voon's patented mirrors/boiler/turbine/fresh dienfected water) and/or desalination slat water membranes and/or used to grow (on floating barges) salt water tolerant plants such as mangrove and switch grass (salicornia) for biofuel/biomass...
6. Entire groupings of grids can be installed on the sea/ocean floors with pipes that are pumped powered by the bladders, with excess enegy stored in our platform and shipping vessel battery power plants above.
7. Alternatively a less buoyant version of the bladders can be hung upside down from floatation objects above, such as strung between platforms and/or barges and or bobbing grids... the difference about our floating bladder bobbers and existing bobber grid technology is that the existing bobber grids partially float out of the water, making the that old technology vulnerable to high/strong waves, while our new bladder bobbers are except for solid neck are fully submersed underwater.
8. We could strategically place higher tidal spinning blades secured to posts that clear to the bobbing bladders, to catch the most wave power out of the ocean. We could also string cables from high posts to high posts (or between platforms) and hang spinning blades at frequent intervals, underwater. (GP 0.24%) Re: Floating-Hose Teflon Rubber Ringed 7. The hose is shaped (and/or helixical, square, round, rectangular, diamond and/or triangular...) along its length like a shipping vessel such that the bottom is shaped like a hull (without the narrowing in absolute width on both ends.
8. The top is flat and is thicker with a rubber layer to maintain stability (spinning of the hose), at the mercy of the waves.
9. Along most of the length of the hose are a loose skin of thin Teflon and/or mixed with plastic and/or mixed with zip log material bags along the front end and then stronger material (eg. Teflon to Teflon/rubber mix on the turbine end).
10. Along its length are rings (whose size must balance its stiffness interfering with the wave squeezing the bulge - eg. large enough to allow the bulge to pass without disrupting (if too small, the rubber ring may bleed the bulge's force) also disrupting the squeezebility of the wave that is squeezing (bending the hose behind the bulge inwards) to result in being directed away from the hose (the vectors of the wave if the rubber rings are too big, may end up at or outwards of the perimeter of the rubber ring keeping in mind that the rubber rings may need to be wider than the alternate intervals of loose skin) while rubber rings their size and intervals are needed to provide support so the hose does not collapse inwardly.
11. Along its length in order maintain rigidity to keep the hose flexible with the waves while able to recover its orientation, (preventing collapsing and/or kinking, we line every sharp angle on the dissection of the perimeter of the hose all along the lengths with rubber (eg.
tube).
12. In the front of the hose is are flaps that open (can dip inwards in a curved gradual design to get water to siphon into the hole while the gaps between sharp corners allow water to pass to surround the the hose exterior length, thus providing squeezing pressure) outwards, such that waves inside the flap are directed into the hose opening, while wave flow outside the flaps directs flow towards the outside of the hose thus squeezing the bulge from outside the hose.(GP 0.25%) Re: Stirling Engine We could use helium waste (See pg. 165 Re: Fusion Reaction) from Fusion Reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood-to power Stirling Engine any and all mechanical and any and all things requiring power/energy...
On a large scale we could (Re: Battery Power Plant pg. 128 - for storage of the electricity produced and transport in large battery exchange programs with gas stations/parkades even delivery to homes/offices... any and all uses supplying fully charged batteries for used batteries like water cooler full for empty delivery and pick up, the delivery can even be like Automobile Association delivery to places where the member has run out of and/or low on low on energy) use helium waste (see pg. 165 Re: Fusion Reaction) from fusion reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood...
Re: Any and All contaminated land and Barren Land We could build solar panels and Gerard Voon's patented TALL GRAVITY TO
ELECTRICITY INVENTION, on empty land (eg. from mountaintop mining).
Re: Fusion Reaction We could use an intense plasma laser to start the reaction and keep it running...
18. First we start with the regular hydrogen atoms colliding creating helium and creating energy 19. Largest magnet ever tried surrounding the plasma.
20. The magnet can be one solid (thick walled) case surrounding the plasma in a vertically standing cylinder design, or change shape with to suit the roundness of the plasma so the magnet force is even.
21. In the bottom is a magnet floor (cradle possibly for stability having thick enough in its walls to support the magnets above) possibly with a small pool of water and/or source of water via nozzle such that the water clears the plasma, so it doesn't touch the plasma (rather it vaporizes because of the heat of the plasma).
22. Surrounding the outside of the magnet layer (the magnet's outer surface can be coated with a layer of ceramic to counter rust) is a huge boiler which is fed water (possibly salt water to produce disinfected water and fresh water), at bottlenecks, the boiler can be huge to absorb the heat from the plasma and also fast moving to keep any one contained area the salt water (possibly other liquids such as ethanol), from overheating (the expanding heat pressure turns the turbine).
23. There are large (robot controlled) slit/opening (such as sliding visors) at intervals from top to bottom that penetrate through the surrounding magnet that can be open and shut... closed when the plasma is not too cold and/or the salt water is too cold and open to cool off the plasma or heat the boiler more efficiently to expand heat pressure to turn turbine.
24. At the top can be an (oversized) roof platform with ceramic coating and and/or magnet also with open and (robot controlled) shut slits that increase or decrease heat into an exhaust. Above the roof is a boiler pool with exhaust that feed into a turbine. Salt water (and/or other liquid) is fed into the boiler. The roof is needed to be (possibly slide) opened especially when the pool of water below the plasma has vaporized and is causing increased expanded water pressure in the plasma core.
25. An extra layer of boiler can encapsulate the main boiler this extra layer of boiler can be made of ceramic on the outside to add extra layer from overheating the compartment holding the inner plasma chamber. The extra outer layer can also fill its outer chamber with salt water any and all liquids (even ethanol) to expand pressure to spin turbine (eg. and fresh/disinfected water).
26. Alternatively if the boiler is large enough (enough water sandwiched between plasma core (magnets) and the boiler's walls the inside of the boiler walls can be lined with nanotube solar panels (that can withstand the extreme heat.
27. Additionally the more close contact/exposure material is to the plasma core the more heat resistant the material must be (eg.
the magnets) therefore we will attempt to mix the magnet material the closer the more density per volume of magnet material mixed with carbon nano particles-tubes (even mix the molten magnet with diamond dust) used as heat sinks in electric motors to withstand motors' intense heat. The tiny structures embedded in materials regularly called upon to withstand extreme heat, such as those that form the exterior panels of airplanes and rockets. In the worse scenario we could mix and make diamond/nano particles-tubes shield in front of the magnets facing the plasma core... Since diamonds are so expensive we might need to play around with the sizes of the plasma core. The carbon nano particles-tubes are added as a cheap cutting cost measure to diamonds.
28. We could also layer a thin layer of either diamonds (container) and a thin layer of carbon nano particles-tubes (with openable slits to vent heat from the plasma core and introduce heat to the outer boilers). The layers of the diamonds and/or carbon nano particles-tubes insulate the magnet(s)...
29. Another material to explore is ceramics mixed with nanotubes The material shows electrical conductivity ten trillion times greater than pure alumina, and seven times that of previous ceramics made with nanotubes. Thermal properties, enable conducting heat in one direction, along the alignment of the nanotubes, but reflecting heat at right angles to the nanotubes, making it an attractive material for thermal barrier coatings. This seems the ideal low cost insulator to protect the magnets from overheating while conducting the magnets force back towards the plasma core.
30. On top of the roof (above the plasma core) is a boiler where salt water (And/or liquids such as ethanol) is entered at high volume to boil to steam to turn turbines with possible walls made of nanotubes that absorb heat and convert into energy.
(GP 0.24%) 31. Any and all components can be composed of ceramics, titanium, tungsten steel, carbon nano materials, magnets and/or diamonds (GP 0.1 %).
32. We could also use walls of water falling.
33. The walls of water falling unlike filling a choking/smothering the entire container in a tank/boiler (pool of) with water; can touch and cool off the magnets without smothering out the plasma core. In fact we could adjust the walls of water to vaporize before collecting at the bottom, so the is no rising level of pool of water on the floor of the boiler that surrounds/holds the magnets which in turn hole the plasma core within.
34. To keep one side from getting hotter than the other sides we could use more water on the overheated face to cool the hotter side...
One hydrogen source is from any and all metals (eg aluminium, zinc...), reacting with in a strong acid (eg. muriatic acid), producing hydrogen gas while crystal remains. The crystal can be used for any and all uses, from decorative, ornamental and any and all aesthetic, parts of walls, parts of interior furniture and fixtures, casings of electronics (and anything - objects -that are expensive are the slightest form of status and prestige symbol), jewelry, substitute metal and wood, eg. door knobs, sculptures, and decorative car interior/exteriors...
The helium output can be used to power cars, and it has no moving parts. It runs by "thermoacoustics" we simply apply external heat to a cylinder or tank (heat can come from the plasma core production and/or mirrors) with the Helium gas (which is a by-product of the hydrogen atoms colliding) inside the cylinder), as the gas heats up it generates the acoustic waves making enough heat to make steam and then it is used to generate electricity.
For cars the sound is converted into electricity, via steam. A microphone like devise, electo-acoustic transducer produces the sound waves. Which can be used to power cars without batteries, therefore no need to discard old batteries which cannot be charged, whereby electric cars without residual pollution later.
And/or use the helium directly as fuel. There considerable growth in demand for helium around the world, eg. medical, industrial and electronic use.
Re: Ocean/Seas (1. floors) Energy and/or 2. Hung from Above 5. We make (flatter) bladders that can be made of mix Teflon (for strength) and rubber for bounce back momentum when bent to much and too long, thus creating more bobbing frequency. The bladder can be filled with enough air to make it stable in water, neither too stringent floating up and/or less air in the hanging version (even slightly weighted at the bottom of the tip of each bladder unit), such that the bladders of the hanging version does not float buoyantly, but rather is the same density/mass as the water so it does not buoyantly float (in one direction and gets stuck there) but rather gets pushed from side to side (on a pivoting ball and socket - swaying) thus either pumping deep salt water (via deep pipe) to a platform and or seashore where the sea water can be used eg. (Gerard Voon's patented mirrors/boiler/turbine/fresh dienfected water) and/or desalination slat water membranes and/or used to grow (on floating barges) salt water tolerant plants such as mangrove and switch grass (salicornia) for biofuel/biomass...
6. Entire groupings of grids can be installed on the sea/ocean floors with pipes that are pumped powered by the bladders, with excess enegy stored in our platform and shipping vessel battery power plants above.
7. Alternatively a less buoyant version of the bladders can be hung upside down from floatation objects above, such as strung between platforms and/or barges and or bobbing grids... the difference about our floating bladder bobbers and existing bobber grid technology is that the existing bobber grids partially float out of the water, making the that old technology vulnerable to high/strong waves, while our new bladder bobbers are except for solid neck are fully submersed underwater.
8. We could strategically place higher tidal spinning blades secured to posts that clear to the bobbing bladders, to catch the most wave power out of the ocean. We could also string cables from high posts to high posts (or between platforms) and hang spinning blades at frequent intervals, underwater. (GP 0.24%) Re: Floating-Hose Teflon Rubber Ringed 7. The hose is shaped (and/or helixical, square, round, rectangular, diamond and/or triangular...) along its length like a shipping vessel such that the bottom is shaped like a hull (without the narrowing in absolute width on both ends.
8. The top is flat and is thicker with a rubber layer to maintain stability (spinning of the hose), at the mercy of the waves.
9. Along most of the length of the hose are a loose skin of thin Teflon and/or mixed with plastic and/or mixed with zip log material bags along the front end and then stronger material (eg. Teflon to Teflon/rubber mix on the turbine end).
10. Along its length are rings (whose size must balance its stiffness interfering with the wave squeezing the bulge - eg. large enough to allow the bulge to pass without disrupting (if too small, the rubber ring may bleed the bulge's force) also disrupting the squeezebility of the wave that is squeezing (bending the hose behind the bulge inwards) to result in being directed away from the hose (the vectors of the wave if the rubber rings are too big, may end up at or outwards of the perimeter of the rubber ring keeping in mind that the rubber rings may need to be wider than the alternate intervals of loose skin) while rubber rings their size and intervals are needed to provide support so the hose does not collapse inwardly.
11. Along its length in order maintain rigidity to keep the hose flexible with the waves while able to recover its orientation, (preventing collapsing and/or kinking, we line every sharp angle on the dissection of the perimeter of the hose all along the lengths with rubber (eg.
tube).
12. In the front of the hose is are flaps that open (can dip inwards in a curved gradual design to get water to siphon into the hole while the gaps between sharp corners allow water to pass to surround the the hose exterior length, thus providing squeezing pressure) outwards, such that waves inside the flap are directed into the hose opening, while wave flow outside the flaps directs flow towards the outside of the hose thus squeezing the bulge from outside the hose.(GP 0.25%) Re: Stirling Engine We could use helium waste (See pg. 165 Re: Fusion Reaction) from Fusion Reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood-to power Stirling Engine any and all mechanical and any and all things requiring power/energy...
On a large scale we could (Re: Battery Power Plant pg. 128 - for storage of the electricity produced and transport in large battery exchange programs with gas stations/parkades even delivery to homes/offices... any and all uses supplying fully charged batteries for used batteries like water cooler full for empty delivery and pick up, the delivery can even be like Automobile Association delivery to places where the member has run out of and/or low on low on energy) use helium waste (see pg. 165 Re: Fusion Reaction) from fusion reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood...
Re: Any and All contaminated land and Barren Land We could build solar panels and Gerard Voon's patented TALL GRAVITY TO
ELECTRICITY INVENTION, on empty land (eg. from mountaintop mining).
Claims
Claims Re: Fusion Reaction We could use an intense plasma laser to start the reaction and keep it running...
35. First we start with the regular hydrogen atoms colliding creating helium and creating energy 36. Largest magnet ever tried surrounding the plasma.
37. The magnet can be one solid (thick walled) case surrounding the plasma in a vertically standing cylinder design, or change shape with to suit the roundness of the plasma so the magnet force is even.
38. In the bottom is a magnet floor (cradle possibly for stability having thick enough in its walls to support the magnets above) possibly with a small pool of water and/or source of water via nozzle such that the water clears the plasma, so it doesn't touch the plasma (rather it vaporizes because of the heat of the plasma).
39. Surrounding the outside of the magnet layer (the magnet's outer surface can be coated with a layer of ceramic to counter rust) is a huge boiler which is fed water (possibly salt water to produce disinfected water and fresh water), at bottlenecks, the boiler can be huge to absorb the heat from the plasma and also fast moving to keep any one contained area the salt water (possibly other liquids such as ethanol), from overheating (the expanding heat pressure turns the turbine).
40. There are large (robot controlled) slit/opening (such as sliding visors) at intervals from top to bottom that penetrate through the surrounding magnet that can be open and shut.. . closed when the plasma is not too cold and/or the salt water is too cold and open to cool off the plasma or heat the boiler more efficiently to expand heat pressure to tum turbine.
41. At the top can be an (oversized) roof platform with ceramic coating and and/or magnet also with open and (robot controlled) shut slits that increase or decrease heat into an exhaust. Above the roof is a boiler pool with exhaust that feed into a turbine. Salt water (and/or other liquid) is fed into the boiler. The roof is needed to be (possibly slide) opened especially when the pool of water below the plasma has vaporized and is causing increased expanded water pressure in the plasma core.
42. An extra layer of boiler can encapsulate the main boiler this extra layer of boiler can be made of ceramic on the outside to add extra layer from overheating the compartment holding the inner plasma chamber. The extra outer layer can also fill its outer chamber with salt water any and all liquids (even ethanoi) to expand pressure to spin turbine (eg. and fresh/disinfected water).
43. Alternatively if the boiler is large enough (enough water sandwiched between plasma core (magnets) and the boiler's walls the inside of the boiler wails can be lined with nanotube solar panels (that can withstand the extreme heat.
44. Additionally the more close contact/exposure material is to the plasma core the more heat resistant the material must be (eg.
the magnets) therefore we will attempt to mix the magnet material the closer the more density per volume of magnet material mixed with carbon nano particles-tubes (even mix the molten magnet with diamond dust) used as heat sinks in electric motors to withstand motors' intense heat. The tiny structures embedded in materials regularly called upon to withstand extreme heat, such as those that form the exterior panels of airplanes and rockets. In the worse scenario we could mix and make diamond/nano particles-tubes shield in front of the magnets facing the plasma core... Since diamonds are so expensive we might need to play around with the sizes of the plasma core. The carbon nano particles-tubes are added as a cheap cutting cost measure to diamonds.
45. We could also layer a thin layer of either diamonds (container) and a thin layer of carbon nano particles-tubes (with openable slits to vent heat from the plasma core and introduce heat to the outer boilers). The layers of the diamonds and/or carbon nano particles-tubes insulate the magnet(s)...
46. Another material to explore is ceramics mixed with nanotubes The material shows electrical conductivity ten trillion times greater than pure alumina, and seven times that of previous ceramics made with nanotubes. Thermal properties, enable conducting heat in one direction, along the alignment of the nanotubes, but reflecting heat at right angles to the nanotubes, making it an attractive material for thermal barrier coatings. This seems the ideal low cost insulator to protect the magnets from overheating while conducting the magnets force back towards the plasma core.
47. On top of the roof (above the plasma core) is a boiler where salt water (And/or liquids such as ethanol) is entered at high volume to boil to steam to turn turbines with possible walls made of nanotubes that absorb heat and convert into energy.
(GP 0.24%) 48. Any and all components can be composed of ceramics, titanium, tungsten steel, carbon nano materials, magnets and/or diamonds (GP 0.1 %).
49. We could also use walls of water failing.
50. The walls of water falling unlike filling a choking/smothering the entire container in a tank/boiler (pool of) with water; can touch and cool off the magnets without smothering out the plasma core. In fact we could adjust the walls of water to vaporize before collecting at the bottom, so the is no rising level of pool of water on the floor of the boiler that surrounds/holds the magnets which in turn hole the plasma core within.
51. To keep one side from getting hotter than the other sides we could use more water on the overheated face to cool the hotter side...
One hydrogen source is from any and all metals (eg aluminium, zinc...), reacting with in a strong acid (eg. muriatic acid), producing hydrogen gas while crystal remains. The crystal can be used for any and all uses, from decorative, ornamental and any and all aesthetic, parts of walls, parts of interior furniture and fixtures, casings of electronics (and anything - objects -that are expensive are the slightest form of status and prestige symbol), jewelry, substitute metal and wood, eg. door knobs, sculptures, and decorative car interior/exteriors...
The helium output can be used to power cars, and it has no moving parts. It runs by "thermoacoustics" we simply apply external heat to a cylinder or tank (heat can come from the plasma core production and/or mirrors) with the Helium gas (which is a by-product of the hydrogen atoms colliding) inside the cylinder), as the gas heats up it generates the acoustic waves making enough heat to make steam and then it is used to generate electricity.
For cars the sound is converted into electricity, via steam. A microphone like devise, electo-acoustic transducer produces the sound waves. Which can be used to power cars without batteries, therefore no need to discard old batteries which cannot be charged, whereby electric cars without residual pollution later.
And/or use the helium directly as fuel. There considerable growth in demand for helium around the world, eg. medical, industrial and electronic use.
Re: Ocean/Seas (1. floors) Energy and/or 2. Hung from Above 9. We make (flatter) bladders that can be made of mix Teflon (for strength) and rubber for bounce back momentum when bent to much and too long, thus creating more bobbing frequency. The bladder can be filled with enough air to make it stable in water, neither too stringent floating up and/or less air in the hanging version (even slightly weighted at the bottom of the tip of each bladder unit), such that the bladders of the hanging version does not float buoyantly, but rather is the same density/mass as the water so it does not buoyantly float (in one direction and gets stuck there) but rather gets pushed from side to side (on a pivoting ball and socket - swaying) thus either pumping deep salt water (via deep pipe) to a platform and or seashore where the sea water can be used eg. (Gerard Voon's patented mirrors/boiler/turbine/fresh dienfected water) and/or desalination slat water membranes and/or used to grow (on floating barges) salt water tolerant plants such as mangrove and switch grass (salicornia) for biofuel/biomass...
10. Entire groupings of grids can be installed on the sea/ocean floors with pipes that are pumped powered by the bladders, with excess enegy stored in our platform and shipping vessel battery power plants above.
11. Alternatively a less buoyant version of the bladders can be hung upside down from floatation objects above, such as strung between platforms and/or barges and or bobbing grids.., the difference about our floating bladder bobbers and existing bobber grid technology is that the existing bobber grids partially float out of the water, making the that old technology vulnerable to high/strong waves, while our new bladder bobbers are except for solid neck are fully submersed underwater.
12. We could strategically place higher tidal spinning blades secured to posts that clear to the bobbing bladders, to catch the most wave power out of the ocean. We could also string cables from high posts to high posts (or between platforms) and hang spinning blades at frequent intervals, underwater. (GP 0.24%) Re: Floating-Hose Teflon Rubber Ringed 13. The hose is shaped (and/or helixical, square, round, rectangular, diamond and/or triangular...) along its length like a shipping vessel such that the bottom is shaped like a hull (without the narrowing in absolute width on both ends.
14. The top is flat and is thicker with a rubber layer to maintain stability (spinning of the hose), at the mercy of the waves.
15. Along most of the length of the hose are a loose skin of thin Teflon and/or mixed with plastic and/or mixed with zip log material bags along the front end and then stronger material (eg. Teflon to Teflon/rubber mix on the turbine end).
16. Along its length are rings (whose size must balance its stiffness interfering with the wave squeezing the bulge - eg. large enough to allow the bulge to pass without disrupting (if too small, the rubber ring may bleed the bulge's force) also disrupting the squeezebility of the wave that is squeezing (bending the hose behind the bulge inwards) to result in being directed away from the hose (the vectors of the wave if the rubber rings are too big, may end up at or outwards of the perimeter of the rubber ring keeping in mind that the rubber rings may need to be wider than the alternate intervals of loose skin) while rubber rings their size and intervals are needed to provide support so the hose does not collapse inwardly.
17. Along its length in order maintain rigidity to keep the hose flexible with the waves while able to recover its orientation, (preventing collapsing and/or kinking, we line every sharp angle on the dissection of the perimeter of the hose all along the lengths with rubber (eg.
tube).
18. In the front of the hose is are flaps that open (can dip inwards in a curved gradual design to get water to siphon into the hole while the gaps between sharp corners allow water to pass to surround the the hose exterior length, thus providing squeezing pressure) outwards, such that waves inside the flap are directed into the hose opening, while wave flow outside the flaps directs flow towards the outside of the hose thus squeezing the bulge from outside the hose.(GP 0.25%) Re: Stirling Engine We could use helium waste (See pg. 165 Re: Fusion Reaction) from Fusion Reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood ...to power Stirling Engine any and all mechanical and any and all things requiring power/energy...
On a large scale we could (Re: Battery Power Plant pg. 128 - for storage of the electricity produced and transport in large battery exchange programs with gas stations/parkades even delivery to homes/offices...any and all uses supplying fully charged batteries for used batteries like water cooler full for empty delivery and pick up, the delivery can even be like Automobile Association delivery to places where the member has run out of and/or low on low on energy) use helium waste (see pg. 165 Re: Fusion Reaction) from fusion reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood...
Re: Any and All contaminated land and Barren Land We could build solar panels and Gerard Voon's patented TALL GRAVITY TO
ELECTRICITY INVENTION, on empty land (eg. from mountaintop mining).
35. First we start with the regular hydrogen atoms colliding creating helium and creating energy 36. Largest magnet ever tried surrounding the plasma.
37. The magnet can be one solid (thick walled) case surrounding the plasma in a vertically standing cylinder design, or change shape with to suit the roundness of the plasma so the magnet force is even.
38. In the bottom is a magnet floor (cradle possibly for stability having thick enough in its walls to support the magnets above) possibly with a small pool of water and/or source of water via nozzle such that the water clears the plasma, so it doesn't touch the plasma (rather it vaporizes because of the heat of the plasma).
39. Surrounding the outside of the magnet layer (the magnet's outer surface can be coated with a layer of ceramic to counter rust) is a huge boiler which is fed water (possibly salt water to produce disinfected water and fresh water), at bottlenecks, the boiler can be huge to absorb the heat from the plasma and also fast moving to keep any one contained area the salt water (possibly other liquids such as ethanol), from overheating (the expanding heat pressure turns the turbine).
40. There are large (robot controlled) slit/opening (such as sliding visors) at intervals from top to bottom that penetrate through the surrounding magnet that can be open and shut.. . closed when the plasma is not too cold and/or the salt water is too cold and open to cool off the plasma or heat the boiler more efficiently to expand heat pressure to tum turbine.
41. At the top can be an (oversized) roof platform with ceramic coating and and/or magnet also with open and (robot controlled) shut slits that increase or decrease heat into an exhaust. Above the roof is a boiler pool with exhaust that feed into a turbine. Salt water (and/or other liquid) is fed into the boiler. The roof is needed to be (possibly slide) opened especially when the pool of water below the plasma has vaporized and is causing increased expanded water pressure in the plasma core.
42. An extra layer of boiler can encapsulate the main boiler this extra layer of boiler can be made of ceramic on the outside to add extra layer from overheating the compartment holding the inner plasma chamber. The extra outer layer can also fill its outer chamber with salt water any and all liquids (even ethanoi) to expand pressure to spin turbine (eg. and fresh/disinfected water).
43. Alternatively if the boiler is large enough (enough water sandwiched between plasma core (magnets) and the boiler's walls the inside of the boiler wails can be lined with nanotube solar panels (that can withstand the extreme heat.
44. Additionally the more close contact/exposure material is to the plasma core the more heat resistant the material must be (eg.
the magnets) therefore we will attempt to mix the magnet material the closer the more density per volume of magnet material mixed with carbon nano particles-tubes (even mix the molten magnet with diamond dust) used as heat sinks in electric motors to withstand motors' intense heat. The tiny structures embedded in materials regularly called upon to withstand extreme heat, such as those that form the exterior panels of airplanes and rockets. In the worse scenario we could mix and make diamond/nano particles-tubes shield in front of the magnets facing the plasma core... Since diamonds are so expensive we might need to play around with the sizes of the plasma core. The carbon nano particles-tubes are added as a cheap cutting cost measure to diamonds.
45. We could also layer a thin layer of either diamonds (container) and a thin layer of carbon nano particles-tubes (with openable slits to vent heat from the plasma core and introduce heat to the outer boilers). The layers of the diamonds and/or carbon nano particles-tubes insulate the magnet(s)...
46. Another material to explore is ceramics mixed with nanotubes The material shows electrical conductivity ten trillion times greater than pure alumina, and seven times that of previous ceramics made with nanotubes. Thermal properties, enable conducting heat in one direction, along the alignment of the nanotubes, but reflecting heat at right angles to the nanotubes, making it an attractive material for thermal barrier coatings. This seems the ideal low cost insulator to protect the magnets from overheating while conducting the magnets force back towards the plasma core.
47. On top of the roof (above the plasma core) is a boiler where salt water (And/or liquids such as ethanol) is entered at high volume to boil to steam to turn turbines with possible walls made of nanotubes that absorb heat and convert into energy.
(GP 0.24%) 48. Any and all components can be composed of ceramics, titanium, tungsten steel, carbon nano materials, magnets and/or diamonds (GP 0.1 %).
49. We could also use walls of water failing.
50. The walls of water falling unlike filling a choking/smothering the entire container in a tank/boiler (pool of) with water; can touch and cool off the magnets without smothering out the plasma core. In fact we could adjust the walls of water to vaporize before collecting at the bottom, so the is no rising level of pool of water on the floor of the boiler that surrounds/holds the magnets which in turn hole the plasma core within.
51. To keep one side from getting hotter than the other sides we could use more water on the overheated face to cool the hotter side...
One hydrogen source is from any and all metals (eg aluminium, zinc...), reacting with in a strong acid (eg. muriatic acid), producing hydrogen gas while crystal remains. The crystal can be used for any and all uses, from decorative, ornamental and any and all aesthetic, parts of walls, parts of interior furniture and fixtures, casings of electronics (and anything - objects -that are expensive are the slightest form of status and prestige symbol), jewelry, substitute metal and wood, eg. door knobs, sculptures, and decorative car interior/exteriors...
The helium output can be used to power cars, and it has no moving parts. It runs by "thermoacoustics" we simply apply external heat to a cylinder or tank (heat can come from the plasma core production and/or mirrors) with the Helium gas (which is a by-product of the hydrogen atoms colliding) inside the cylinder), as the gas heats up it generates the acoustic waves making enough heat to make steam and then it is used to generate electricity.
For cars the sound is converted into electricity, via steam. A microphone like devise, electo-acoustic transducer produces the sound waves. Which can be used to power cars without batteries, therefore no need to discard old batteries which cannot be charged, whereby electric cars without residual pollution later.
And/or use the helium directly as fuel. There considerable growth in demand for helium around the world, eg. medical, industrial and electronic use.
Re: Ocean/Seas (1. floors) Energy and/or 2. Hung from Above 9. We make (flatter) bladders that can be made of mix Teflon (for strength) and rubber for bounce back momentum when bent to much and too long, thus creating more bobbing frequency. The bladder can be filled with enough air to make it stable in water, neither too stringent floating up and/or less air in the hanging version (even slightly weighted at the bottom of the tip of each bladder unit), such that the bladders of the hanging version does not float buoyantly, but rather is the same density/mass as the water so it does not buoyantly float (in one direction and gets stuck there) but rather gets pushed from side to side (on a pivoting ball and socket - swaying) thus either pumping deep salt water (via deep pipe) to a platform and or seashore where the sea water can be used eg. (Gerard Voon's patented mirrors/boiler/turbine/fresh dienfected water) and/or desalination slat water membranes and/or used to grow (on floating barges) salt water tolerant plants such as mangrove and switch grass (salicornia) for biofuel/biomass...
10. Entire groupings of grids can be installed on the sea/ocean floors with pipes that are pumped powered by the bladders, with excess enegy stored in our platform and shipping vessel battery power plants above.
11. Alternatively a less buoyant version of the bladders can be hung upside down from floatation objects above, such as strung between platforms and/or barges and or bobbing grids.., the difference about our floating bladder bobbers and existing bobber grid technology is that the existing bobber grids partially float out of the water, making the that old technology vulnerable to high/strong waves, while our new bladder bobbers are except for solid neck are fully submersed underwater.
12. We could strategically place higher tidal spinning blades secured to posts that clear to the bobbing bladders, to catch the most wave power out of the ocean. We could also string cables from high posts to high posts (or between platforms) and hang spinning blades at frequent intervals, underwater. (GP 0.24%) Re: Floating-Hose Teflon Rubber Ringed 13. The hose is shaped (and/or helixical, square, round, rectangular, diamond and/or triangular...) along its length like a shipping vessel such that the bottom is shaped like a hull (without the narrowing in absolute width on both ends.
14. The top is flat and is thicker with a rubber layer to maintain stability (spinning of the hose), at the mercy of the waves.
15. Along most of the length of the hose are a loose skin of thin Teflon and/or mixed with plastic and/or mixed with zip log material bags along the front end and then stronger material (eg. Teflon to Teflon/rubber mix on the turbine end).
16. Along its length are rings (whose size must balance its stiffness interfering with the wave squeezing the bulge - eg. large enough to allow the bulge to pass without disrupting (if too small, the rubber ring may bleed the bulge's force) also disrupting the squeezebility of the wave that is squeezing (bending the hose behind the bulge inwards) to result in being directed away from the hose (the vectors of the wave if the rubber rings are too big, may end up at or outwards of the perimeter of the rubber ring keeping in mind that the rubber rings may need to be wider than the alternate intervals of loose skin) while rubber rings their size and intervals are needed to provide support so the hose does not collapse inwardly.
17. Along its length in order maintain rigidity to keep the hose flexible with the waves while able to recover its orientation, (preventing collapsing and/or kinking, we line every sharp angle on the dissection of the perimeter of the hose all along the lengths with rubber (eg.
tube).
18. In the front of the hose is are flaps that open (can dip inwards in a curved gradual design to get water to siphon into the hole while the gaps between sharp corners allow water to pass to surround the the hose exterior length, thus providing squeezing pressure) outwards, such that waves inside the flap are directed into the hose opening, while wave flow outside the flaps directs flow towards the outside of the hose thus squeezing the bulge from outside the hose.(GP 0.25%) Re: Stirling Engine We could use helium waste (See pg. 165 Re: Fusion Reaction) from Fusion Reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood ...to power Stirling Engine any and all mechanical and any and all things requiring power/energy...
On a large scale we could (Re: Battery Power Plant pg. 128 - for storage of the electricity produced and transport in large battery exchange programs with gas stations/parkades even delivery to homes/offices...any and all uses supplying fully charged batteries for used batteries like water cooler full for empty delivery and pick up, the delivery can even be like Automobile Association delivery to places where the member has run out of and/or low on low on energy) use helium waste (see pg. 165 Re: Fusion Reaction) from fusion reactors and/or gasoline, kerosene, diesel, vegetable oil, hydrogen, even wood...
Re: Any and All contaminated land and Barren Land We could build solar panels and Gerard Voon's patented TALL GRAVITY TO
ELECTRICITY INVENTION, on empty land (eg. from mountaintop mining).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA2681645A CA2681645A1 (en) | 2009-10-29 | 2009-10-29 | New energies |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA2681645A CA2681645A1 (en) | 2009-10-29 | 2009-10-29 | New energies |
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| Publication Number | Publication Date |
|---|---|
| CA2681645A1 true CA2681645A1 (en) | 2011-04-29 |
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ID=43923093
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA2681645A Abandoned CA2681645A1 (en) | 2009-10-29 | 2009-10-29 | New energies |
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110441242A (en) * | 2019-08-14 | 2019-11-12 | 郑州大学 | Gas detecting system and method based on diamond micro-cantilever |
| CN111204831A (en) * | 2020-01-19 | 2020-05-29 | 陕西科技大学 | CNF-based homologous heterogeneous photothermal material for seawater desalination and preparation method thereof |
-
2009
- 2009-10-29 CA CA2681645A patent/CA2681645A1/en not_active Abandoned
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110441242A (en) * | 2019-08-14 | 2019-11-12 | 郑州大学 | Gas detecting system and method based on diamond micro-cantilever |
| CN111204831A (en) * | 2020-01-19 | 2020-05-29 | 陕西科技大学 | CNF-based homologous heterogeneous photothermal material for seawater desalination and preparation method thereof |
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