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US20050120715A1 - Heat energy recapture and recycle and its new applications - Google Patents

Heat energy recapture and recycle and its new applicationsDownload PDF

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Publication number
US20050120715A1
US20050120715A1US11/039,624US3962405AUS2005120715A1US 20050120715 A1US20050120715 A1US 20050120715A1US 3962405 AUS3962405 AUS 3962405AUS 2005120715 A1US2005120715 A1US 2005120715A1
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United States
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water
air
heat
deuterium
fusion
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US11/039,624
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Gaudencio Labrador
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CHRISTION SCHOOL OF Tech CHARITABLE FOUNDATION TRUST
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CHRISTION SCHOOL OF Tech CHARITABLE FOUNDATION TRUST
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Priority claimed from US08/999,729external-prioritypatent/US6327994B1/en
Priority claimed from US09/137,499external-prioritypatent/US6293121B1/en
Application filed by CHRISTION SCHOOL OF Tech CHARITABLE FOUNDATION TRUSTfiledCriticalCHRISTION SCHOOL OF Tech CHARITABLE FOUNDATION TRUST
Priority to US11/039,624priorityCriticalpatent/US20050120715A1/en
Publication of US20050120715A1publicationCriticalpatent/US20050120715A1/en
Priority to AP2007004109Aprioritypatent/AP2007004109A0/en
Priority to US11/795,835prioritypatent/US8051637B2/en
Priority to PCT/US2005/026793prioritypatent/WO2006078315A1/en
Priority to EP05779535Aprioritypatent/EP1851418A4/en
Priority to AU2005325208Aprioritypatent/AU2005325208B2/en
Priority to EA200701538Aprioritypatent/EA200701538A1/en
Priority to CA002599414Aprioritypatent/CA2599414A1/en
Priority to CNA2005800492077Aprioritypatent/CN101146981A/en
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Abstract

What has been created is a plurality and a variety of processes and a variety of devices correspondingly supportive to each process, wherein, a new partnership between; (1) a heat absorbing radiator compressed air pipes/tubes and (2) a gas turbine engine or a reciprocating piston engine,—is used to recapture and reconvert the, otherwise wasted, heat energies expelled by engines, by factories, by smelting plants, by distillation plants, by chillers/coolers/freezers, by cooking ovens, by lamps/stoves, by trash burners, and the heat energies created by the solar heat on the desert/ocean water,—into electric power and finally into hydrogen-deuterium fuel,—by having the engine's tailpipes submerged in cold compressed air inside the heat absorbing radiator pipes in reverse air flow, to further drive and re-drive the same engine; wherein, in order to capture fusion heat energy the hydrogen bomb is detonated in the deep ocean to catch the flames by the water and the hot water is used to energize the compressed air inside the heat absorbing radiator pipes; wherein, in order to produce fusion energy, an abundant electric arc is passed across liquid deuterium or across gaseous deuterium by the electro-plasma torch and sparkplug in the internal combustion engine, and by detonating a dynamite inside a liquid deuterium; wherein diamond is produced by placing carbon inside the hydrogen bomb; and wherein, deuterium fusion flame is used first in smelting glass to large sizes before running an engine.

Description

Claims (58)

1. A plurality of new processes for maximizing benefits from fuels and/or from heat sources/supplies, and a plurality of corresponding new devices in support of the new processes, all inter-related to form part/component for and appurtenant to and assembled into a power plant, for the production of electricity, hydrogen, deuterium, all kinds of fuels, glass, ceramics, metals, distilled water, drinking water, irrigation water, and other concomitant products,
wherein, a heat-hungry cold humid compressed air is made to undergo thru low temperature first stage, thru high temperature second stage, and thru super-high temperature third stage scavenger heating processes before it is finally released to pass thru a gas power exhaust turbine, and exits thru a main exhaust chimney;
wherein, for its energy scavenger mission, and as a first stage heating up of the compressed air while still cold, a plurality of low temperature heat emitting radiator tubes of:—freezers, chillers/coolers, air conditioners, refrigeration units, dehumidifiers, food processing/cooking/barbecue ovens, stoves, and lamps,—are submerged or inserted to crisscross the flow of compressed air inside heat absorbing radiator pipes/tubes which are also exposed to solar heat, solar traps, direct sunlight, warm water on the tropical ocean, warm atmospheric air of summer, warm air in the tropical regions, hot air from the fireplaces, hot air in the attic of houses, warm water from hot springs, warm waters from volcanic lakes, hot air created by all kinds of lamps, hot air created by the kitchen stoves, warm waters/steam created by underwater detonation of hydrogen bomb or other bombs, condensation devices/towers, and other heat sources;
wherein, as a first stage heating of the compressed air while still cold, the cold compressed air is used to condense the hot steam expelled by fuel cells, by steam engines, and by steam turbines—in reverse flow, by inserting individual steam exhaust heat-emitting tubes into/inside each corresponding heat-absorbing cold compressed-air radiator tubes,—in order to recapture the heat energy from the steam, and to recycle the distilled water into the boiler, into the electrolysis machine to re-feed the fuel cells and into drinking water;
wherein, as a first stage heating of the compressed air while still cold, a plurality of cold heat-absorbing radiator pipes/tubes are placed crisscrossing the air flow inside the downstream section of the exhaust tailpipe/chimney of the subject power plant,—in order to condense the steam, recapture the water that has been sprayed into the intake mouth of the compressor, and to recycle the heat energy;
wherein, the first stage cold compressed air duct/header pipe from a compressor of the power plant, has multiple branches, each provided with shut-off gate valves, each branch communicated to a plurality of heat energy absorbing radiator pipes/tubes,—for free selection of the various available heat sources of lower temperature at regulated air flow;
wherein, before compression, as a new process of making the air more compact, more dense, more humid, more heat-hungry, more turbo-charged, and to have more expanding power, the air is passed thru cold foggy tunnels being mist sprayed with water, and distilled water is also mist sprayed at the intake mouth of the compressor;
wherein, for second stage heating of the compressed air, and for maximum utilization and maximum commercialization of the created partnership between the turbine engine and the heat absorbing/collector pipes or tubes of my prior arts,—the heat collector pipes/tubes are used to absorb heat energy from:—solar heat on land as well as on the ocean, solar heat from solar traps, heat energy from the fireplaces, trash burners, geothermal heat sources, cooking ovens, exhaust chimneys of power plants, exhaust tailpipes and hot-air/water of cooling systems of various kinds of engines, warm waters of the ocean, warm water of geothermal lakes, warm grounds of the desert, warm air of the summer atmosphere or tropical regions, warm air from inside the attic of houses, hot air/water from cooling systems of nuclear power plants, hot air from smelting plants, hot air from glass/ceramic smelting ovens, warm air from factories, hot water and steam created by underwater and underground detonation of hydrogen bombs, or other bombs, hot gases/steam created by electric plasma torch, hot gases created by fusion torch fueled by deuterium, hot gases created by air-blast burning of powdered organic matter, powdered charcoal, powdered cocks, powdered wood/news-paper, dried grass/leaves, carbon, incinerators, and all other heat energy sources;
wherein, for maximum recovery/recapture/recycle from the various heat sources/suppliers, the hot air/steam/water are confined/forced to run thru various types/kinds of tubes/pipes/conduits/air-ducts placed inside the heat absorbing pipes/tubes,—in order that the heat energy is in close encounter/contact with the cold compressed air inside the pipes/tubes that absorbs the heat energy;
wherein, as a second stage heating of the compressed air, smelting plant furnaces are submerged in compressed air inside large pipes/tunnels,—and the compressed air is in reverse flow against the flow of the annealing process;
wherein, for maximum absorption of heat energy, the individual branches of heat emitting pipes/tubes that contain warm/hot air/steam/water are submerged in running cold compressed air inside each corresponding individual heat absorbing radiator tubes/pipes in reverse flow;
wherein, the hot upstream section of the heat energy supply pipes/tubes are place inside the hot down stream section of the heat energy absorbing pipe, while the downstream section of the heat energy supply pipe is placed inside the cold upstream section of the heat absorbing compressed air pipe in reverse flow;
wherein, for easier construction, a plurality of hot radiator tubes containing hot compressed air are coiled in zigzag form across the flow of cold compressed air inside a large heat absorbing pipe, the hot zigzag tubes being started at the down stream end of the heat absorbing pipe;
wherein, the various first stage branches of the heat collector radiator pipes/tubes are communicated to a central header air duct/pipe which serves as depository from the various first stage branches and which also serves as hub for the second stage heat absorbing branches into the higher temperature heat energy supplies and sources;
wherein, among the higher temperature second stage heat energy supplies and sources are: exhaust tailpipes of internal combustion engines, exhaust chimneys of gas turbine engines, smelting ovens for metals, smelting ovens for glass/ceramics, annealing lehr of glass, exhaust pipes from fuel cells, Geothermal wells, exhaust pipes from engines fueled by hydrogen-deuterium-triterium, exhaust chimneys of fusion smelting ovens fired by electro plasma torches, exhaust chimneys from smokeless trash burners, exhaust chimneys fueled by coke, cool, wood, charcoal, and organics, hot steam from underwater detonation of hydrogen bomb—by means of electric arc, by means of confined dynamite into the liquid deuterium, and by means of compression by drop hummer,—into which high temperatures, a plurality of heat absorbing radiator pipes/tubes are submerged and the hot radiator pipes are inserted inside the cold heat collector pipes,—in the process of collecting heat energy to run the gas turbine;
wherein, after the compressed air has been pre-heated thru the first stage, the heat collector pipes/tubes are divided into plurality of routes, branches, and small tubes, and are exposed to higher temperature heat energy supplies listed in the preceding paragraphs, including into the tail/pipe and exhaust chimneys of the same gas turbine engine to which the same heat collector pipe is in partner with;
wherein, all the second stage higher temperature heat collector pipes are communicated to deposit hot compressed air into a 3rdstage heating central header power duct/pipe, in which the hot compressed air is further subjected to a hydrogen-deuterium electro-plasma fusion torch to provide more heat into the compressed air;
wherein, to prevent meltdown of the 3rdstage heating pipe, same pipe is enclosed/engulfed by a larger pipe which contains/supplies high pressure cold high humidity water-misted-air that gets into the down stream end of the 3rdstage heating pipe, for more expanding power of the 3rdstage header power pipe;
wherein, the hydrogen-deuterium fuel is super pre-heated thru the engines tail pipe and thru it's own plasma flames before it gets out from the fuel tube and then into exposure to electric arc environment at the plasma oven to attain fusion firing in the third stage heating inside the central hot air header;
wherein, in the effort to maximize benefit from hydrogen-deuterium as fuel, same fuel is passed thru fusion reaction processes instead of just reacting it with oxygen;
wherein, in the effort to capture the heat energy produce by the hydrogen bomb, it is detonated in deep waters to trap the fusion heat into lower temperature in the water to produce steam and hot water,—as means to create more heat sources;
wherein, the down stream end of the 3rdstage central hot air header duct is communicated into the intake of the exhaust Power Turbine to push the blades of the turbine in full power and effect, same turbine drives the compressor that compresses air into the whole heat absorbing radiator pipes/tubes systems of the power plant, and same power turbine also drives an electric generator, without regulating the voltage output—hereby extremely emphasized;
wherein, the electric generator is made to produce direct current used to run multiples of electrolysis machines which do not require a steady voltage,—to re-supply the Power Plant with hydrogen-deuterium fuel which is stored for commercial world market for various engines, desalination, and other purposes, and for fuel of the succeeding fusion reactions in this subject power plant;
wherein, a major portion of the branches in the 2ndstage heating of the heat energy collector pipes are placed inside of and parallel with the main exhaust chimney, in multiple tubes, to recapture the heat expelled by the power turbine;
wherein, a plurality of tailpipes, from a plurality of internal combustion piston engines, are inserted into and made to expel hot gases into the upstream section of the exhaust chimney of the gas turbine engine in order to recapture the tailpipe heat energy of the internal combustion engines;
wherein, the internal combustion piston engines, gasoline/diesel, are provide with at least two hybrid long electric arc sparkplugs in each chamber, and are fed with hydrogen/deuterium to attain fusion inside each chamber to produce more heat, and the electrolysis machines are driven by the engine's DC generators directly without voltage regulator to produce hydrogen/deuterium being fed into same engines to reduce gas/diesel consumption—for more mileage per gallon of fuel;
wherein, the generated DC is directly passed thru the electrolysis machines for production of hydrogen/deuterium fuels, and also directly passed thru the coils of the magnets of the electric generators,—before connection to the power-grid;
wherein, a plurality of heat absorbing radiator tubes/pipes are placed inside the exhaust chimney of the power plant:—1. to drive a reciprocating piston engines which drives a compressor that supplies compressed air into its own heat collector pipes, such as a steam engine or a sterling engine, 2. to drive/run a secondary gas turbine engine that generates DC electricity and, 3. to provide hot air for heating buildings and houses;
wherein, a wood/trash distillation oven is placed inside the downstream section of the exhaust chimney of the power turbine and the distillate organic gas is superheated and fed as torch fuel to burn lumps of cool and lumps of organics into the combustion chamber inside the central hot air duct for 3rdstage heating;
wherein, a water boiler is placed into the downstream section of the exhaust chimney to distill heavy water for used in the electrolysis that produce deuterium for the fusion processes for the production of heat energy;
wherein, in the process of condensation, the heat energy from the hot water vapor is recaptured by the first-stage heat absorbing pipes to pre-heat the cold compressed air of the power plant;
wherein, a conveyor being loaded with trash is placed inside the downstream section of the chimney to dry the trash—that serve as fuel for the power plant;
wherein, in order to detonate a hydrogen bomb underwater to produce more heat for the power plant, the liquid deuterium is confined in a glass capsule provided with multiple electrodes, and the glass is enclosed by strong steel container without air gap, and the electrodes are connected by highly insulated electric wire conductors to the main high voltage DC electric source, in order to fire abundant electric arc thru and across the liquid deuterium by remote control;
wherein further, in order to detonate a hydrogen bomb underwater in the efforts to produce more heat to run the power plant, the liquid deuterium is contained in a soft metal container which is surrounded by abundant charge of dynamite which is in turn contained by a strong steel container of about 6 to 12 inches thick, and then the dynamite is blasted by remote control wires,—to effect violent implosion upon the liquid deuterium;
wherein, in order to detonate a hydrogen bomb, liquid deuterium in soft metal container is compressed by a drop hummer that blast a dynamite on top of the deuterium,—in the efforts to create more heat supplies for the power plant;
wherein further, in order to detonate a hydrogen bomb underwater to produce more heat energy to run the power plant, the distilled heavy water is confined in a forced electrolysis chamber without air gas/space to make sure there is zero chance of expansion during the process of electrolysis, and the water is colored so that the separation line of the liquid deuterium above the water is visible, and then the liquid deuterium is heated up by electric arc until fusion is attained;
wherein, the water vapor from the underwater detonation of hydrogen bomb is condensed into drinking water and into irrigation water-by the heat collector pipes/tubes, while the helium gas is compressed inside pressure container;
wherein, in the efforts to produce more heat energy to run the power plant, a ball of compacted charcoal, graphite, and carbon, enclosed/wrapped in soft metal, is placed at the lower section of the liquid deuterium before detonation—in order to melt and compact the carbon during the fusion blast and solidify into crystals of diamonds upon cooling, the diamond serving as among the principal by-products of hydrogen bomb detonation in deep waters;
wherein, in the effort to used the ocean for deep water hydrogen bomb detonation, the power plant/house is made floating on the ocean, carried by/ridding on an ocean platform made of crisscrossing empty pipes/bamboos, and crisscrossing stiff walls with top cover plate forming an empty box to trap air and to contain various kinds of air containers, empty bottles, sausages of air containers, pipes and bamboos, same platform serving also as carrier for agricultural lands, power house, habitation homes/buildings, and for floating ocean windmill farms;
wherein, a secondary gas turbine engine, run by recaptured heat from the exhaust chimney or tail pipe of the main engine, is used to compress air to turbo-charge the main engine and to produce more hydrogen/deuterium fuels;
wherein, the cold water at the ocean bottom is used to cool the air before getting into the compressor, and then, the warm waters on the ocean's surface is used to pre-heat the compressed air after coming out of the compressor by means of the heat absorbing radiator tubes and pipes,—as means to provide more heat energy supply to the subject power plant;
wherein, a solar trap covers the ocean surface to hold more solar heat into the ocean waters and to prevent the wind from stealing the heat energy from the ocean, serving as means to provide more heat energy for the power plant;
wherein, to produce more heat energy supplied to the power plant, hydrogen bombs are detonated underwater in sustained firing by a submarine boat loaded with abundant torpedoes that carry hydrogen bombs which are fired upon an underwater target impact wall in regular succession to boil the ocean water directly under the floating power plant;
wherein, in the efforts to produce more heat energy supplied to the power plant, underwater detonation of hydrogen bombs in regular sustained firing is done by an underwater large cannon gun fixed in place which regularly fires large deuterium bullet bombs upon an underwater target impact wall built deep in the river bank or sea coastline.
wherein, further, in the efforts to produce more heat supply for the power plant, the deuterium bullets are made into regular size bullets that fits a hand gun or a machine gun which fires to detonate fusion bullets at regular intervals upon a target impact wall in a dry enclosed oven into which a pump shoots liquid deuterium or capsules to maintain continuous fusion flame inside the furnace;
wherein, further, in the efforts to produce more heat supply for the power plant, an electro-fusion plasma torch is submerged in distilled water to prevent short circuit of the high voltage DC supply and to prevent meltdown of the torch serving as boiler while in the process of smelting various kinds of materials—including molded/cast large sections of house/building components and house cubicles made of glass, to name a few, and the smelting heat energy is recaptured by the heat absorbing compressed air in radiator pipes/tubes;
wherein, further, to produce more heat energy for the power plant, a pump-gun shoots high pressure deuterium just in time into the fusion flame created inside the fusion plasma torch to subject the new deuterium to the high temperature to attain continuous fusion reaction without too much electric arc consumed;
wherein, further, to produce more heat energy for the power plant, hydrogen gas jet is blown upon a molten sand/rock and/or metallic ore to reduce the materials into pure/refined form of glass/ceramics or metals, in which smelting process, the hydrogen is oxidized by grabbing the oxygen from the ore, thereby producing large amounts of heat which is absorbed by the heat-absorbing radiator pipes;
wherein, further, to produce more heat energy for the power plant, the oxygen air supply for a trash burner is pre-superheated thru tubes submerged into the fire before the oxygen air is released near the fuel by pressure nuzzles at the end or at the top of the trash, the oxygen tubes having multiple side nuzzles to distribute the oxygen around the combustion chamber to burn all gas fumes;
wherein, further, to produce more heat energy for the power plant, a catalytic converter oven heated by the hydrogen/deuterium electro-plasma torch—is made to form part of the main third stage heating power pipe before the power turbine,—to recapture the heat energy produced by the catalytic converter; comprising:
a power exhaust turbine, as prime mover, connected to a drive shaft, having an air inlet and an air outlet connected to a main exhaust chimney;
a turbine compressor driven by the power turbine thru the drive shaft, having an air intake mouth and an air outlet;
an electric generator driven by the power turbine thru the drive shaft, having magnets with variable magnetic field, made to produce direct current, placed in-between the turbine compressor and the power turbine;
the power turbine, by way of the drive shaft, drives the compressor and the electric generator, thereby forming a power plant assembly;
a main first stage header cold air duct having an inlet communicated to the outlet of the turbine compressor, serving to contain cold compressed air produced by the compressor, and having a plurality of outlets;
a plurality of major pipe branches, each having control gate valves, each having an inlet and an outlet, and each inlet connected to the corresponding outlet of the main header cold air duct;
an assembly of parallel, multiple, first stage heat absorbing radiator pipe tubes, having an inlet communicated to the outlet of each major pipe branch, and having an outlet;
a steam engine and a fuel cell communicated to contribute hot exhaust steam into a common steam header tail pipe having multiple outlets;
a plurality of heat emitting hot steam tubes, each tube having inlets connected to each outlet of the header tail pipe, serving as branches of the steam engine's tail pipe, each having a downstream end;
each hot tube inserted into the downstream end of each corresponding individual heat absorbing radiator tube in reverse airflow, and coming out at the upstream end of each heat absorbing tube;
a distilled water receiving header pipe communicated to the downstream ends of the hot steam tubes, having an outlet;
a distilled water storage tank communicated with the outlet of the distilled water header pipe, serving as distilled water storage which supplies distilled water to a boiler of the steam engine, and to a water misting device at the air intake mouth of the compressor, for turbo-charging;
a plurality of low temperature heat energy supplies, some of which are solar, warm water of the ocean, warm grounds and air of the desert, exhaust from chillers, freezers, fireplaces, geothermal heat, including but not limited to hot water created by under water detonation of hydrogen bomb, to name a few, into which the first stage heat absorbing radiator tube assemblies in the other branches are exposed to;
a hot main second stage header air duct having a plurality of inlets into which the outlets of the assemblies of the first stage heat absorbing radiators are communicated to, and having a plurality of outlets;
a plurality of assemblies of second stage heat absorbing radiator pipes/tubes having inlets communicated to each corresponding outlet of the hot main second stage header air duct, serving as second stage branches, and each having an outlet;
a plurality of high temperature second stage heat energy supplies and sources, some of which are already listed in the preceding paragraphs, including but not limited to, hot steam from underwater detonation of hydrogen bomb, hot air from smelting plants, hot air from organic trash smokeless burners, hot air from engines and power plants main exhaust chimneys, etc.,—into which, each corresponding branch assembly of second stage heat absorbing radiator pipes/tubes is exposed to;
a plurality of the second stage heat absorbing radiator pipes placed inside of, parallel to, and along the length of the main heat exhaust chimney in reverse air flow,—to collect energy from the chimney and made to discharge hot air into the third stage heating header hot air duct;
a third stage header hot air duct, having multiple inlets communicated to the outlets of the second stage heat absorbing radiator pipe assemblies, and having an outlet;
a plurality of high temperature heat energy supplies, some of which are charcoal/coke/coal burners, powdered carbon blast burners, gas/oil/organic gas burners, hydrogen/deuterium electro-plasma fusion reactor,—placed inside the third stage header hot air duct for final super-heat up and power boasting upon the compressed air;
the outlet of the third stage header hot air duct connected and communicated to the air inlet of the power exhaust turbine;
a multi-coil main heat exhaust chimney, having an inlet connected and communicated to the air outlet of the exhaust power turbine, serving as exhaust main tailpipe of the power plant, and having an outlet;
a reciprocating piston hot gas engine driving a push and pull electric generator, having;
a piston rod interconnecting a larger power piston with a smaller compression piston driven by the larger piston;
each piston fitted with appropriate size of chamber, each chamber having reciprocating valves, and having an inlet and an outlet;
an assembly of heat absorbing radiator tubes placed inside the main exhaust chimney, having a header inlet pipe and a header outlet pipe;
the inlet header pipe pierces the chimney and communicated to the outlet of the compression chamber;
the outlet header pipe pierces the chimney upstream of the inlet header pipe and communicated to the inlet of power chamber;
the hot air exhaust from the power piston is communicated to the second stage header hot air duct for recycle of the heat energy;
a plurality of hybrid internal combustion engines fueled with hydrogen-deuterium, made to produce more heat energy for the power plant, provided with long-arc sparkplugs, made to produce hydrogen-deuterium fuel, each having a hot tailpipe that pierced into the main exhaust chimney to contribute hot gases into the chimney for heat energy recycle;
at least one hybrid sparkplug, having multiple prong anode adjusted to have long-arc jump of about one centimeter spark arc jump or no anode at all,—installed in each combustion chamber of the IC engines to create fusion fire by the deuterium fuel,—to produce more heat energy for the power plant;
at least two of the longitudinal second stage heat absorbing pipes made to discharge hot compressed oxygen-air into the charcoal/coke/cool burning chamber;
an assembly of heat absorbing radiator tubes, placed inside the chimney, having an inlet and an outlet header pipe, each header pipe pierces out thru the chimney and correspondingly communicated to an outside turbine compressor and to an outside power turbine.—to run a secondary, power plant;
a distractive distillation chamber for wood and organics placed inside the chimney, having and inlet door and an outlet pipe that pierced out thru the chimney to exit organic vapor supply by pipe for torch fuel into the trash, coke, coal burner,—to produce more heat energy for the power plant, and as a heat recycle process;
the wood distillation chamber produces charcoal used in the smelting plants for glass and steel to further produce heat energy for the subject power plant;
a horizontal axis carousel bucket looped chain conveyor loaded with trash for drying,—placed inside the down stream end of the chimney—for more fuel;
an upper inlet door and a lower exit door at the elbow bend of the chimney, made for loading trash on the carousel, and for unloading trash down into a bin;
a plurality of hybrid cyclone dust separators having in inlet air duct air-tightly connected and communicated to the main chimney's outlet thru a common header air duct connector, and having an outlet;
each cyclone dust separator comprising;
a vertical axis drum body, having a top lip, a bottom lip located at a distance equal to its own diameter below its top lip, and having an inside wall;
a top cover plate air-tightly fastened to the top lip of the drum, having a large central hole, and a bottom face;
a vertical air exit chimney, serving as a continuation of the main exhaust chimney, having an open bottom below the top of the drum at about at least two thirds of the height of the drum, air tightly attached thru the center hole of the top cover plate, having an open top end air outlet;
a spacious bottom chamber created by a bottom cover air tightly fastened to the bottom lip of the drum, having a bottom door exit for dirt;
a plurality of spaced radial vertical instilling walls, having a top edge attached to the bottom face of the top cover plate, an outer vertical edge attached to the inside walls of the drum, a bottom edge attached to the bottom cover of the drum, and an inner vertical edge set backed at about at least four times the diameter of the vertical air exit chimney;
the instilling walls having a horizontal width of at least two-third of its height to make a spacious instilling chamber for the dust to settle down; and
a plurality of outwardly inclined floors attached to and in-between the radial vertical walls, in multilevel floors;
a horizontal zigzag smoke cleaning chimney, having an elbow inlet air-tightly communicated to the open top end air outlet of the cyclone's exit chimney, and having an air outlet, and serving as continuation of the main chimney, comprising;
a flat floor, a flat roof, and side walls interconnecting the floor with the roof, forming a box air-duct;
a series of roof air deflector walls, spacedly attached hanging from the roof across the air flow, with at least two feet clear from the floor;
a series of floor air deflector walls erected on the floor and in-between the roof deflector walls, across the air flow, with at least two feet clear from the roof;
a rough surface sheet attached to the roof facing down, serving as ceiling;
a rough surface sheet facing the air flow attached to the walls and floors;
a high pressure water pipe attached to the ceiling lengthwise, having multiple transverse branches and multiple downward branches;
a plurality of water mist spray nuzzles facing the rough surface walls and ceilings, spacedly communicated to the branches of the water pipe;
the floor inclined to one side, having a waste water collection gutter that drops the water down thru a drain hole;
a horizontal spiral chimney, serving as dust collector and smoke cleaner, having an inlet air-tightly communicated to the air outlet of the zigzag chimney, comprising:
a large elongated air pipe/duct, made long enough depending upon the quality of exiting air out from it, having an outlet;
a spiral fin attached to and around a central straight closed pipe that serve as support structure of the fin, forming a fin assembly;
the fin assembly inserted and placed centrally and longitudinally inside the large air pipe;
a plurality of pressurized longitudinal water pipes, having misting nuzzles, attached to every quarter along the central pipe structure, to wet all the internal walls of the spiral chimney, to catch the smoke and dust;
a tall vertical chimney to create vacuum, having an inlet air-tightly communicated to the outlet of the spiral chimney, and having an outlet serving as final exit of the waste air of the power plant;
a plurality forced electrolysis machines, without allowance for gas expansion, that produce liquid deuterium directly without compressor, driven by the DC current output by the power plant; and
a hybrid bottle container serving to store the liquid deuterium produced by the force electrolysis machine, having water serving as sealant at the inlet and outlet, and having a bent outlet pipe with an inlet submerged in water,—to remove leakage of hydrogen fuel,—as hydrogen dissolves all organic seals.
14. A new apparatus used for maximizing benefits from deuterium fuel by detonating a hydrogen bomb in deep water in accordance with claim-1 or claim-13, wherein, an abundant electric arc is passed thru across the liquid deuterium, comprising;
a hydrogen bomb of liquid deuterium contained in a glass and ceramics, and non-conductive container having at least two holes on opposite sides;
a metallic electrical conductor, molten and baked as plug into each hole, serving as positive-negative electrodes, and serving as electrical contact points at both sides of the container;
a pair of rail wheels attached to each side of the container serving to carry it on rails;
a pair of heavy steel inclined rail track, serving to carry the bomb by its wheels and to conduct electric direct current, and having at least one electrical contact points at each lower end of the rails which extends to the middle of the detonation water;
a feeding underwater port made of large pipe containing the rail track, having two spaced alternating air tight gate values thru which the bomb are successively fed by rolling down the rail, and down to the detonation spot;
an electrical insulator in the form of ceramics/glass baked-coated around each rail to prevent short circuit thru the water;
a vertical dry service manhole communicated to the feeding port, having stairs ways and high voltage power supply heavy cable wires and an elevator, serving as access to the feeding port;
a heavy current main switch, above the manhole and above the water, serving to detonate the bomb upon it gets to the contact points at the ends of the rail;
a large high voltage capacitor connected to the electric cable wires supporting electric power for the electric arc inside the bomb;
a heat insulator flexible containment wall surrounding the detonation water, having embedded empty air containers, to make the wall float on water, and serving as support posts to the upper structures;
a corrugated multi-hole flame distributor dome placed in the deep detonation water but spaciously above the detonation spot and within the containment walls;
a deepwater platform, serving as containment floor, upon which the heat insulator walls, and the distributor dome are erected, placed well below the detonation spot, serving as heat insulator separating the hot water from the ordinary cold water in the deep;
a plurality of rubber tubes with compressed air attached/laid on the middle section of the floor made flexible to absorb the shock of the blast;
a crisscrossing array of salt resistant walls, forming boxes under the floor, serving as main structure of the water platform in which glass is used as among the salt resistant materials for the walls, some in the form of pipes for floating;
a heat insulator laid on top of the floor surrounded by the containment wall;
a metallic/glass/ceramics plate, resistant to salt action, placed and air-tightly attached to cover the top of the boxes formed by the crisscrossing walls;
the boxes having no air leaks, serving as floater for the whole apparatus;
a plurality of empty waste bottles, bamboos, pipes, and other air containers,—all filled up with compressed air, placed inside the boxes to make sure there are floaters even the air escapes out of the boxes;
the underwater platform extended outside the containment walls serving as anti-oscillation wide-face device against the action of the water waves;
a rain water and distilled water placed to fill up the tank formed by the containment walls, serving as electrical insulator for the electric arc, and also serving as catcher for the fusion flames;
an air inlet and air release valve provided on each floater pipe in the underwater platform, to adjust the submergence of the apparatus;
a gas turbine engine, having an exhaust power turbine, that drives a turbine air compressor, and also drive electric generator that produce direct current, the power turbine and the compressor turbine having an inlet and an outlet;
an electrolysis machine that produce deuterium and hydrogen in liquid form directly by confined electrolysis,—which is run by the direct current and connected to the generator;
a header cold compressed air pipe having an inlet communicated to the outlet of the turbine compressor, and having multiple outlet branches;
a plurality of multi-coil pipes heat absorbing radiator, having lower coil and upper coil, each having an inlet communicated to some of the branches and filled up with compressed air by the compressor, and communicated to exit the compressed air thru the exhaust power turbine;
a plurality of the heat absorbing radiator pipes, having an inlet communicated to some of the outlet branches of the cold compressed air header pipe, and extended down into the hot boiling waters, and having an outlet;
a hot air header pipe having an inlet communicated to the outlets of the heat absorbing radiator pipes, and having an outlet communicated to the inlet of the exhaust power turbine;
an exhaust header tailpipe from the exhaust power turbine, having branches communicated to multi-pipe heat emitting radiator pipes;
a plurality of multi-coil pipe heat emitting radiator pipes correspondingly coiled and individually inserted into inside each of the heat absorbing radiator pipes,—in reverse air flow;
an upward exhaust chimney outside the radiators, communicated to and serving as terminal header pipe for the heat emitting radiator pipes;
an electro plasma fusion oven installed into the down stream end section of the heat absorbing header radiator pipes, to add power to the compressed air;
the multi-coil heat absorbing radiator pipes extended over and above the boiling hot water above the detonation spot, wherein the lower are exposed directly to the rising steam, while the cooler upper coils are exposed to the upper cooler steam;
an extension of the containment wall above the water, enclosing the rising steam, pierced on one side by the heat absorbing radiator pipes, serving as a steam chamber, having a top cover;
a multiple hanger structure supporting the heat absorbing radiator pipes attached to the top cover of the steam chamber;
a least one lower temperature steam concentration header pipe communicated thru the top cover of the steam chamber, having an outlet;
a distilled water supply tank, outside the steam chamber, elevated above the ocean water, having an upper inlet, and having a lower outlet main pipe communicated to the boiler detonation chamber by piercing thru containment wall;
an automatic water supply valve regulated by a floater pipe, placed floating in the boiler chamber;
the floater pipe contains water to have enough weight to pull up the water supply valve by a rope thru pulleys above the tank;
a plurality of carrier floater in the form of sausages of empty bottles, air containers, bamboos, and pipes,—attached to carry the apparatus and the water supply tank above the ocean water;
a plurality multi-coil condensation pipes communicated to the outlet of the steam exhaust header pipe, exposed to the cold wind having multiple bottom coil water outlets;
each condensation coil pipe having an outlet;
a condensation box chamber communicated to the outlets of the condensation coil pipes, having a bottom outlet, lower side end outlet for steam, and an upper side end outlet for helium and having a plurality of perforations on two side walls facing the wind;
a water receiving pipe communicated to each bottom coil water outlet of each condensation pipe, and having an outlet communicated to the condensation box chamber;
a plurality of horizontal wind pipes piercing thru the perforations of and across the condensation box chamber serving to further condense the excess steam;
the wind pipe attached to the perforated side walls by welds and clamp-knots to prevent water leaks;
a compressor pump communicated to the upper outlet of the box to suck and to compress helium from the condensation box, having an outlet;
a helium tank communicated to the outlet of the compressor pump, serving to receive helium gas produced by the hydrogen bombes, having a regulated shut-of value;
a water drop-off having a gate value communicated to the bottom water outlet of the condensation box, having an outlet;
a distilled water tank, having a top communicated to the outlet of the drop-off pipe, and having a gated bottom outlet pipe communicated to the upper inlet of the water supply tank;
at least one electrolysis machine producing deuterium fuel for the succeeding hydrogen bombs; and
an underwater DC transmission line feeding a step-up transformer coupled with an inverter to match the power to the utility grid.
15. A glass/ceramics smelting plant use to maximize benefits from hydrogen-deuterium fuel in accordance with claim-1, wherein, sand and other glass materials are molten into liquid by means of deuterium electro-plasma fusion torch, and the heat energy from the furnace and annealing lehr is recaptured by submerging the whole furnace and annealing lehr into a flowing cold compressed air inside a large heat absorbing air duct which supplies the resulting hot oxygen air into another organic trash smokeless second burning furnace used to smelt glass/ceramics inside another heat absorbing large containment compressed air duct chamber that supplies the resulting hot air flowing into an engine's tailpipe/chimney which engulfs the high-air pressure heat-absorbing radiator pipes from a gas turbine compressor being driven by a power exhaust turbine.
27. A new apparatus for maximizing benefits from fuel in accordance with claim-1, wherein, the oxygen air supply is pre-supper heated and distributed into the flames and into the trash fuel by a plurality of multi-nuzzle burner pipes tapering into the combustion chamber, and wherein, the trash is burned from the top or from one end of the trash pile, comprising:
a combustion chamber drum made wide enough to accommodate an array of oxidizer-burner pipes, having oxygen inlet perforations at its upper/outer section, having a trash-end lip, an air inlet end with perforated cover plate, and a side exhaust hot air outlet;
a plurality of elongated oxidizer-burner tapering perforated pipes arranged parallel together vertically or horizontally in even spacing, having an inlet communicated to each corresponding perforation hole of the cover plate of the combustion chamber, and each having an end outlet nuzzle;
a fresh oxygen air supply duct/pipe spaciously surrounding the combustion chamber, having a bottom air inlet way down below the combustion chamber, having an outlet made spaciously beyond the cover plate of the combustion chamber, and having a trash entrance door;
a heat insulator outside the oxygen-air supply duct/pipe around the vicinity of the combustion chamber;
a plurality trash burning container/drum, each having an outer lip fitted to air-tightly cover the trash-end lips of the combustion chamber, having closed bottom plate and filled up with compacted trash;
a conveyor and merry-go-round carousel spacedly holding the trash containers in individual holders equipped with feeding arms which successively push each trash container to cover the trash-end lip of the combustion chamber, and to pull out the trash drum when empty;
a trash loading been at the other side of the carousel serving to load and compact trash on each trash drum;
a gas torch tube coiled around the combustion chamber containing gas fuel from distilled wood/organics, serving to start firing the trash until ignition is sustained; and
a heat energy exhaust duct/pipe/manifold having an inlet communicated to the heat exhaust outlet of the combustion chamber, and having an outlet communicated to a common chimney with other heat energy supplies.
28. A new process of storing electric power in the efforts of maximizing benefits from fuels in accordance with claim-1 or claim-11 or claim-22,
wherein, electric power is stored in the form of hydrogen-deuterium fuel by using DC electric power to produce the fuel thru the process of electrolysis;
wherein, the distilled water or heavy water is placed inside a force electrolysis apparatus without allowance for expansion so that the evolving deuterium is directly in the form of liquid, with out spending additional energy to compressed it, same liquid rising up above the water into the storage chamber which is an up-side-down large glass bottle;
wherein, a shut-off gate valve is provided at the neck of the bottle, and another outlet pipe with gate valve is installed piercing the neck of the bottle above the shut-off gate valve,
wherein, the shut-off value and the outlet pipe are submerged in water sealant, as it is hereby extremely emphasized, to isolate the organic seals at the valves from being dissolve by the hydrogen-deuterium,
wherein, the inlet section of the outlet pipe is sufficiently bent to hide the inlet mouth into the water sealant by rotating the bent inlet down into the water, and
wherein, the hydrogen-deuterium is reconverted back into electric power thru fusion reaction in the engine's chamber, thereby the electric power used in producing the deuterium is recovered 1000 times more energy,—hereby extremely emphasized.
29. A new process for maximizing benefits from fuels in accordance with claim-1 or claim-15, and in the efforts to maximize benefits from hydrogen-deuterium fuel, wherein, the energy of a fusion plasma electric torch is used first to smelt glass/ceramics/metals in a furnace having a heat energy exhaust contained/surrounded by a third stage heating power air duct that contains a running compressed air to absorb all the heat energy into the power turbine; and
Wherein, the molten glass is poured into molds:
1. to produce extra-large bottles/cubicles, having windows/doors,—used for homes/houses;
2. to produce large structural parts/sections for houses and buildings walls, roofs, floors, large post, girders, structural beams, stairways,—with embedded reinforcing steel bars;
3. to produce extra-large containers, including, water tanks, swimming pools, fishponds, floating swimming pools on the ocean, vacuum chambers for water desalination, underwater chambers for ocean housing human settlement, chambered underwater floating train transportation for people/gas/water/fuel/food, sub-surface underwater shuttle bus, floating pipe hulls for double hull boats, floating sea walls, water waves energy traps/converter, and carrier floaters for floating airports, floating platforms, and floating windmill platforms and power plants, and the annealing heat is recaptured by compressed air pipes.
31. A new solar heat collector used for maximizing benefits from heat energy supplier/sources, in accordance with claim-1, wherein, a transparent roof is spacedly laid over above another transparent roof to have a good air space in between, so that the cold blowing wind is prevented to touch the lower roof, the wind is prevent to steal the solar heat that got into the box below the transparent roofs; and
wherein, a plurality of metallic/plastic 2-sided mirrors or sunlight reflector in the form of narrow strips are horizontally and spacedly laid standing on a North-South orientation held by a mechanism so that the mirrors are tilted to the East in the morning and tilted to the West in the afternoon in order to increase the sunlight incidence into the transparent roof to harvest more solar heat,—this apparatus is named solar trap in my preceding patents, into which box the heat energy absorbing radiator pipes are exposed to, and which trap is used to make the ocean water warmer.
33. A new structural design for constructing an ocean platform that carry power fusion energy power plants, transmission tower lines, ocean windmills, ocean homes and buildings, desalination apparatus, agricultural settlements, and solar traps,—in the efforts to maximize utilization of the heat energy of the warm waters of the ocean, the solar heat, and maximum benefits from fuel,—in accordance with claim-1 or claim-31,
Wherein, a plurality of parallel pipes/chambers laid side by as first layer are inter-clipped together by another layer of pipes/chambers laid side by side on top of and perpendicular to the first layer of pipes, thereby forming a rigid platform;
Wherein, the upper layer of pipes is over-lain by metallic plates, glass/concrete slabs, serving as rigid floor for airports, transportation, power plants, buildings, human settlement, and agricultural land;
Wherein, a plurality of air-cooling pipes are submerged in cold water brought up by water pumps from the ocean deep;
Wherein, the cold air, after being mist sprayed with water, is feed into a compressor which drives the cold compressed air into a plurality of heat absorbing radiator pipes submerged into the warm waters on the surface of the ocean to provided heat-expanding power to the compressed air;
Wherein, the resulting hot compressed air is accumulated to a hot header pipe communicated to the inlet of a power exhaust turbine that drives the compressor and an electric generator, thereby forming a power plant;
Wherein, a plasma torch is fired inside the hot header pipe to provide more expanding power of the compressed air;
Wherein, the exhaust chimney from the power turbine is coiled underwater below the solar trap to heat up the water that heats up the compressed air inside the heat absorbing radiator pipes;
Wherein, the transparent roofs that trap the solar heat into the ocean water are in the form of transparent empty pipes and thin transparent bottles floating on the water laid close to each other side-by-side to exclude the cold wind from touching the warm ocean water;
Wherein, a plurality of evenly spaced strips of shinny metallic solar reflectors are adjustably attached on top of the solar trap roof and manipulated to drive the sunlight down into the solar trap and down into the ocean water;
Wherein, the heat absorbing pipes are set into the warm waters of the ocean below the solar trap pipes; and
Wherein, the power plant is loaded on the ocean platform.
34. A new structural design for an ocean transportation used as a shuttle boat in the efforts to maximize benefits from fuel and maximum utilization of the hybrid fusion engine of claim-1 or claim-2, and from the heat energy of the warm waters of the ocean as source of heat energy, in accordance with claim-1 or claim-33, comprising;
a plurality of horizontal bamboos stacked and clipped together to a vertical thin rear post on one side, and another similar stack of bamboos clipped together on the other side of same post, with all butts on same post;
a pair of boards or metal/plastic plates disposed vertically inclined, having each outer edge jointed together and the inner edges disposed apart and attached enclosing the vertically stacked butts of the bamboos,—serving as pointed nose at the rear of the boat;
a front thin post located at the two-third point of the bamboos, serving to clip together the two stacks of bamboos near the tips;
a flat rope and multiple string/wire clip tied near the tips of the bamboos to form a pointed hull of a boat;
a strong rope/wire attached to the wire clip near the tip and tautly attached to the post clip at the butt of the bamboos, in order to bend up the tip of the bamboos to form a first bent-up bamboo hull, having a top and a butt;
a second hull similar to the first hull, coupled with the first bamboo hull;
a rear transverse structure inter-connecting the two hulls together at the rear post by the top of the hulls;
a front transverse structure interconnecting the two hulls together at the two-thirds point front post by the top of the hulls; and
a flat deck of the bamboos laid on top inter-connecting the two hulls; and
the boat used for carrying passengers, water, and other cargoes by providing it with a hybrid fusion engine in accordance with claim-1 or claim-2 for power propulsion, and by attaching to it a flying kite as sail,—in the efforts to service the ocean floating power plants.
35. A new design for a home/house/building for humans and livestock in the efforts to maximize benefits from fuels, and to maximize the utilization and benefits from the hybrid fusion engine in accordance with claim-1 or claim-33,
wherein, to meet the requirement to have cold air and high humidity air in order to make the air more hungry for heat energy and to provide more expanding power for the compressed air, the house/home is used as a cooling and humidifying vacuum chamber tunnel;
wherein, all the windows and doors are closed and made sure that there are no in-coming air leaks thru the walls, windows, doors, floors, roofs and ceiling;
wherein, a misting port is created at one end of the building having a window provided with air throttle to limit entrance of fresh air,—in order to create a partial vacuum effect inside the building/house to speed up evaporation and to speed up cooling process;
wherein, an outlet port is created at the opposite end of the building to which the air intake manifold, of a turbine vacuum and compressor pump for a home electric generator unit,—is air tightly fitted with and attached to,—in order to suck-vacuum air from the building and to make the whole building cool and dry;
wherein, the heat hungry cold compressed air output from the compressor is used as scavenger to pick up heat energy from a heat source for conversion into mechanical energy to power the vacuum/compressor pump;
wherein, a plurality of air partial vacuum air ducts branching out from the misting port are made to discharge cold humid air into the various rooms in partial vacuum;
wherein, a sump serving as brine/salt collector is provided into the misting port; and
wherein, the house/building is built to be structurally strong against implosion, some being arc structures, large cylindrical chambers, and inflated arc structures.
40. A new device for obtaining maximum benefits from hydrogen-deuterium fuel and for maximum commercialization of the new process discovered and/or invented, in accordance with claim-1,
wherein, the hydrogen-deuterium fuel is made to undergo thermonuclear fusion reaction process thru a plasma torch device instead of burning same fuel by ordinary oxidation,—in order to maximize heat energy produced out of the fuel;
wherein, to prevent short circuiting of the high voltage electric arc supply, the thermonuclear fusion chamber plasma torch is constructed out of non-conductive materials, some of which are glass, and ceramics, to mane a few;
wherein, distilled water is used as electric insulator that surrounds the plasma reactor chamber and at the same time acting as cooling agent for the chamber by boiling into steam;
wherein, the reactor boils the cooling distilled water, and the steam of which is used to heat up compressed air for the engine;
wherein, additional deuterium is injected into the fusion chamber while the fusion fire is still in the chamber in order to sustain the fusion fire without additional electric arc; and
wherein, the fusion fire is directed to melt various materials, some of which are glass and ceramics for molding large sections of structures and cubicles for houses and buildings, in a monolithic pour,—seeFIG. 26.
42. A new device for maximum benefits from fuel and maximum utilization of the hybrid fusion engine, in accordance with claim-1,
wherein, the fusion fire is used to smelt glass/ceramics and poured into molds monolithically formed into chambers, cubicles and structural sections of houses and building;
wherein, the molded glass cubicles are assembled to form houses and buildings having roof tops with upward monolithic walls formed to hold water into fishponds and agricultural lands filled up with live fish and water plants on the roof tops, comprising:
a smelting plant for glass/ceramics, having various kinds of molds for the production of chambers, building cubicles/structures;
a fusion plasma torch fueled with deuterium, installed and set up to fire and melt gravel and sand for molding into various shape;
a horizontal net is framed and stretched at least one foot above the floor to prevent the fishes from agitating the mud and waste matters on the floor to keep the water clear/clean; and
wherein, a fusion engine is used to filter the water, remove the waste materials dropped by the fish, and the waste materials are used to serve as fertilizer for the farmland,—seeFIG. 21.
43. A new device for maximum benefits from fuel and maximum utilization of the hybrid fusion engine in accordance with claim-1, wherein, a water agricultural shallow tank/box bed for growing algae coupled with a shallow filter tank is constructed floating on water or freshwater lake, carried by various kinds of floater devices, and having an underwater floor filled up with fertile soil or fish/chicken manure, for the production of algae, comprising:
a larger tank/box bed filled with a layer of fertile soil, enclosed by water tight walls/floor to prevent intrusion of outside muddy water and to prevent escape of the clear water;
a water made brackish and diluted with small percent of salt placed filling the tank to a deep of at least two feet;
a second smaller tank with water tight floor and walls, integrally attached to the larger tank, having a floor filled up with layers of coarse gravel, pea gravel, sand, and fine soil, serving as water filter;
a water gate between the two tanks allowing filtered clear water to get back to the larger tank;
the floor of the larger tank being continuous and extended to and serving as floor of the smaller tank, and having a bottom face;
a plurality of crisscrossing walls under-laying the floor and air-tightly attached to the bottom face of the floor,—forming a plurality of box air tanks—as floaters carrying the tanks;
a water pump, a plurality of suction pipes, and a plurality of discharge pipes,—all assembled together to transfer/filter the water to make it clear and returned back to the larger tank;
a good appropriate variety of algae and water plants planted on the fertile soil/mud on the floor for food production;
a compressor assembled with discharge pipes set up to supply atmospheric compressed air to the under-laying box air tanks thru distribution nipples, and to supply carbon dioxide to the algae;
a plurality of cages filled with fish and placed into the water around the suction perforated nipples to supply carbon dioxide for the growing algae;
a plurality of vacuum chambers attached to the side walls of the tanks, serving to carry the tanks, and further serving vacuum food dryer to dry the algae; and
a hybrid fusion engine set up to drive the compressors, water pumps, and the vacuum pumps,—seeFIG. 27.
44. A new device for maximum benefits from fuel and for maximum utilization of the hybrid fusion engine, in accordance with claim-1,
wherein, an agricultural shallow bed floating on water for growing algae is made having screen/net sidings to allow the algae to grow outward thru the screen to enable the fish to eat the tips of the algae protruding outside the screen;
wherein, the soil floor of the bed is submerged at more or less one foot under the water surface to exposed the fertile soil bed for abundant sunshine and atmospheric air for carbon dioxide supply;
wherein, the water is supplied with carbon-dioxide for growing the algae and with oxygen for growing the fishes by introduction of the tiny bubbles of compressed air from the atmosphere;
wherein, the beds are arranged row-by-row at an even spacing such that a maintenance man can paddle his small boat in between the beds to harvest the algae and to plant some more algae; and
a hybrid fusion engine set up to drive an air compressor to supply aeration into the water to supply oxygen for the fishes and carbon dioxide for the algae,—seeFIG. 29.
45. A new device for maximum benefits from fuel and maximum utilization of the hybrid fusion engine in accordance with claim-1, wherein, carbon is molten at high pressure to convert it into diamond and the heat used is absorbed to run a fusion engine, comprising:
a ball of compacted carbon enclosed by compacted fire brick/clay materials;
a thick strong spherical steel, having a top and opposite sides, serving as pressure containment enclosing the clay, and snugly sited on a solid footing;
a dovetail hole made on opposite sides of the steel containment;
a dovetail/frustum glass/ceramic electrical insulator bushing fitted thru each dovetail hole;
a high melting point metal electrode fitted thru and into each bushing;
each electrode extended inward holding the carbon in a compacted state;
a high melting point metallic cylindrical piston, having a top, tight-fitly piercing thru the top of the spherical steel container, and extended down to press compress the molten carbon;
a solid heavy weight sitting on top of the cylinder piston, serving to push down the piston in the effort to compact the molten carbon while in the process of cooling and crystallization;
a large block of capacitor sitting on the solid weight serving as energy bank of DC power, and as additional weight;
a couple of large heavy cable conductor wire inter-connecting the terminals of the capacitor with the electrodes to drive heavy electric current/arcs across the compacted carbon; and
a large pipe containing cold compressed air engulfing the steel pressure containment sphere, to recapture the heat energy during the process of annealing,—seeFIG. 16.
46. A new device for maximum benefits from fuel and maximum utilization of the hybrid fusion engine in accordance with claim-1, wherein, a floating platform serves as human settlement floating on water with complete utilities and food production industries, comprising:
a deep water tank coupled with a shallow water tank carried by various kinds of floaters, including bamboos, empty used containers, pipes, and crisscrossing walls, to name a few, made floating on a body of water or ocean;
a higher elevation platform integrally connected to the water tanks, serving as support base for a house or building as home on the ocean;
a hybrid fusion engine installed beside the building on the higher platform supplying power for the whole platform;
a plurality of selected species of fishes are placed to grow into the deep water tank, making it a fishpond;
a sand filter placed on the floor of the shallow water tank;
a fertile soil made up of waste matters from the fish and other manures placed on the sand filter of the shallow tank;
a assembly of perforated pipe covered by a layer of gravel serving to return the filtered water back into the fishpond;
a selected species of algae and water plants planted on the soil of the shallow water tank, producing food for the fishes;
a floor having valleys and ridges installed at the bottom of the fishpond, the valleys of which serving to accumulate droppings or waste maters from the fish;
a horizontal screen net framed and stretched about one foot above and across the floor of the fishpond preventing the fish from agitating the muddy waste matters on the floor;
a wide-face bladed windmill erected between the fishpond and the algae pond serving to pump out turbid water and waste matter from the fishpond and transfer it into the algae pond for fertilizer and clearing of the fishpond water;
the windmill further serving to save fuel for the fusion engine during strong winds;
a water wave vertical impact wall attached to one side of the platform facing the water waves;
a water wave energy converter, having a chamber, valves, and power turbine, attached to the upper section of the impact wall, helping to produce energy for the whole platform; and
an anchor attached to the ocean floor, holding the platform against the wind,—seeFIG. 18.
47. A new apparatus for obtaining maximum benefits from hydrogen-deuterium and from other fuels and for maximum utilization of the hybrid fusion engine in accordance with claim-1,
wherein, a plurality of deuterium fueled fusion engines are used to power giant air-compressors and air blowers that drive strong concentrated upward winds that carry sprayed waters up in the sky for purposes of rapid evaporation and desalination for the production of irrigation and drinking water;
wherein, a plurality of giant propellers/air blowers are horizontally arranged side-by-side a few feet above the water and disposed to drive large quantities of strong concentrated upward winds;
wherein, a plurality of evenly spaced water atomizer nuzzles are horizontally arranged above the air blowers and disposed to spray low grade or salt water along with the upward wind;
wherein, the giant air compressors are connected by pipes to supply compressed air into each of the atomizer nuzzles;
wherein, each of the nuzzles are communicated by pipes to suck from the low grade/salt water;
wherein, the whole apparatus is set floating on a body of water and supported by means of low cost platforms resting on low cost floaters, among which are wasted containers, bamboos, empty pipes, inflated devices, and crisscrossing walls, to name a few;
wherein, the resulting cloud/water vapor is enclosed by balloon walls floating up in the sky or inflated tents/tunnels, and is collected by large inflated suction trunks/pipes made floating up in the sky;
wherein, the water vapor is driven by compressors and released as high pressure tiny bubbles into cold waters to effect rapid condensation; and
wherein, the resulting upward strong wind is utilized by sky gliders and parachuters for sky lifting and gliding down in a merry-go-round going back to the upward strong wind to get lifted again and again,—for purposes of tourist attraction in a resort.
48. A new food production apparatus on land for obtaining maximum Benefits from hydrogen-deuterium and other fuels and for maximum utilization of the new hybrid deuterium fueled fusion engine, in accordance with claim-1,
wherein, a plurality of jointed flat impervious sheets are laid on flat grounds, having outer edges raised a few feet above the ground, serving as water container and forming a water pool, a fishpond, and a water filter;
wherein, the fishpond is formed into a circular pool serving as a vortex dirt separator by driving the water in a merry-go-round circular motion to concentrate the dirt and waste matters from the fish into the center of the pool for easy collection by a suction pipes;
wherein, an air compressor is installed and set to provide aeration in the form tiny bubbles into the ponds;
wherein a water pump is installed to collect, by suction pipes set at the center of the pool, the waste matters dropped by the fishes, and discharges the waste matters on the filter pond;
wherein, the filter pond is underlain by an impervious layer/sheet to return the clean filtered water back into the fishpond; and
wherein, the filter pond is used for planting and growing water plants and algae to produce feed back to the fishpond; and
wherein, a hybrid deuterium fusion engine is installed to provide power for the whole facility;
wherein, wide-face bladed windmills are used as supplementary power for the facility, and used to produce deuterium fuel,—seeFIG. 19.
50. A new device for obtaining maximum benefits from fuel and for maximum utilization of the hybrid fusion engine in accordance with claim-1,
wherein, a chamber in the form of a fish is provided with wheels and with a fusion fueled engine and the fish is used as transportation for gas/liquid/grain and live fish, to name a few;
wherein, the fish is provided with water propeller serving as a mobile home/house/transportation under water;
wherein, the chamber is made into an elongated underwater large cylinder with compartments and further provide with compressor-ventilation air ducts extended above the water by floaters, in order to serve as a versatile underwater home; and
wherein, a plurality of the elongated underwater cylindrical chambers are link together into a form of an underwater train transportation,—seeFIG. 28.
52. A new apparatus for obtaining maximum benefits from hydrogen-deuterium fuel by the maximum efforts to produce heat to energize the hybrid fusion engine in accordance with claim-1,
wherein, large hydrogen-deuterium canon bullet bombs are successively detonated underwater, fired by a large underwater canon gun installed in an underwater pit against an underwater impact wall target in order to trap the fusion heat into the water to produce hot steam;
wherein, an underwater perforated roof is disposed a few feet above the detonation spot to spread the fusion flame into a wide area of the water in order to attain maximum capture and retention of the fusion heat energy into the water; and
wherein, a plurality of assembled heat absorbing radiator pipes containing compressed air, are installed on the water and above the water to provide heat power for a gas turbine engine, seeFIG. 23.
53. A new apparatus for obtaining maximum benefits from hydrogen-deuterium fuel by the maximum efforts to produce heat to energize the hybrid fusion engine in accordance with claim-1,
wherein, a high caliber machine gun, piercing a solid wall, successively fires deuterium bullet bombs at an impact wall target inside a detonation pit/tunnel/oven constructed in a rocky dry land or enclosed by solid walls, to detonate small scale hydrogen bombs in order to produce fusion flames; and
wherein, the detonation pit/tunnel/oven is airtight closed bottom with a small exhaust opening,—so that the fusion fire/flame is conserved and does not rise upward and the high temperature stays for a long time inside the oven,—thereby all the heat energy in the oven is absorbed to the maximum in time by the heat absorbing radiator tubes that powers the hybrid fusion gas turbine engine; and
wherein, a high pressure super-preheated deuterium fuel is jet injected into the fusion fire/flame thru a high melting point metal tube exposed to the fire,—in order to attain continuous fusion fire without additional detonation of bomb bullets,—seeFIG. 24.
54. A new apparatus for obtaining maximum benefits from hydrogen-deuterium fuel and other fuels and for maximum utilization of the hybrid fusion engine, in accordance with claim-1,
wherein, to make a house/home/building self sufficient in energy, the old house/building is retrofitted with the hybrid fusion powered engine illustrated in claim-1;
wherein, the roof of the house is overlain with a heat reflective metal sheet, one of which is aluminum sheet;
wherein, to create additional heat source, a solar trap box oven is constructed above the roof, comprising:
a lower/inner transparent water proof hot sheet that prevents hot air from escaping out from the solar trap box oven;
a upper/outer transparent water proof cold sheet, exposed to the wind, that prevents the wind from touching the lower/inner sheet and from stealing the heat from the solar box;
the solar trap box further encloses part of the house's side more often exposed to the sunlight,—creating a hot room;
wherein, a gas turbine hybrid fusion engine of claim-1, having a power exhaust turbine driving an electric generator and further driving a turbine compressor,—is installed inside the hot room, the compressor being elevated at the eve of the roof but lower than the power exhaust turbine;
wherein, a high efficiency smokeless trash burner is installed inside the hot room and resting on the ground, and being fed with various kinds of fuel easily available including trash;
wherein, a plurality of heat absorbing radiator pipes/tubes containing the cold compressed air from the compressor are made to pass thru under the heat reflective metal sheet and following the roof to the ridge,—to make the house cool;
wherein, the cold heat absorbing radiator pipes are continued back down to the roof's eves in the form of larger pipes in the form of horizontal multi-coils laid on the roof's reflective sheet;
wherein, the hot air exhaust from the power turbine is contained in a multiple hot tubes/pipes horizontally coiled and placed inside each corresponding heat absorbing cold coils of compressed air pipe,—in a reverse air flow—to preheat the compressed air;
wherein, some of the cold compressed air pipe engulf the hot exhaust tail pipes in multi-coils from the solar trap oven in reverse air flow,—to preheat the compressed air;
wherein, the preheated compressed air then proceeds inside heat absorbing multi-coiled pipes in multi-branches laid at the upper section space of the solar trap oven for final superheating;
wherein, the downstream sections of the final heating pipes are disposed at the highest space of the solar trap oven, same highest space being of the highest temperature;
wherein, the downstream ends of each final heating pipe are communicated into a hot header pipe communicated to drive the exhaust power turbine;
wherein, a fusion plasma fusion torch is made to fire fusion flames inside the downstream end of the hot header pipe approaching the power turbine;
wherein, a plurality of perforated air nuzzles are disposed downward inside the upper section of the smokeless trash burner to superheat the in-coming oxygen air blowing downward, thereby burning the trash fuel from the top and distributing superheat oxygen out from the perforations to the fumes flying around the oven and into the exit chimney;
wherein, a deuterium plasma torch is made to fire fusion flames into the exit chimney of the trash burner serving as catalytic converter oven;
wherein, the exit chimney of the trash burner discharges into and inside the solar trap oven to contribute heat therein, and, as it is hereby extremely emphasized, to recapture the heat energy spent in running the catalytic converter;
wherein, some of the hot air exhaust from the power turbine, it being a hot oxygen air, is contributed into trash burner to perfectly burn the trash fuel by passing thru the perforated oxygen distributor nuzzles; and
wherein, the electric generator is made to produce DC electricity used in running an electrolysis machine thereby producing hydrogen/deuterium fuel used into the trash burner and into the plasma torch catalytic converter for the trash burner.
US11/039,6241997-12-232005-01-20Heat energy recapture and recycle and its new applicationsAbandonedUS20050120715A1 (en)

Priority Applications (9)

Application NumberPriority DateFiling DateTitle
US11/039,624US20050120715A1 (en)1997-12-232005-01-20Heat energy recapture and recycle and its new applications
CNA2005800492077ACN101146981A (en)2005-01-202005-07-27Thermal energy recovery and new applications thereof
CA002599414ACA2599414A1 (en)2005-01-202005-07-27Heat energy recapture and recycle and its new applications
EA200701538AEA200701538A1 (en)2005-01-202005-07-27 RETURN AND RECIRCULATION OF HEAT ENERGY AND ITS NEW APPLICATIONS
US11/795,835US8051637B2 (en)1997-12-232005-07-27Heat energy recapture and recycle and its new applications
AP2007004109AAP2007004109A0 (en)2005-01-202005-07-27Heat energy recapture and recycle and its new applications
PCT/US2005/026793WO2006078315A1 (en)2005-01-202005-07-27Heat energy recapture and recycle and its new applications
EP05779535AEP1851418A4 (en)2005-01-202005-07-27Heat energy recapture and recycle and its new applications
AU2005325208AAU2005325208B2 (en)2005-01-202005-07-27Heat energy recapture and recycle and its new applications

Applications Claiming Priority (4)

Application NumberPriority DateFiling DateTitle
US08/999,729US6327994B1 (en)1984-07-191997-12-23Scavenger energy converter system its new applications and its control systems
US09/137,499US6293121B1 (en)1988-10-131998-08-20Water-mist blower cooling system and its new applications
PH1-2004-0001482004-03-25
US11/039,624US20050120715A1 (en)1997-12-232005-01-20Heat energy recapture and recycle and its new applications

Related Parent Applications (2)

Application NumberTitlePriority DateFiling Date
US08/999,729Continuation-In-PartUS6327994B1 (en)1984-07-191997-12-23Scavenger energy converter system its new applications and its control systems
US09/137,499Continuation-In-PartUS6293121B1 (en)1988-10-131998-08-20Water-mist blower cooling system and its new applications

Related Child Applications (1)

Application NumberTitlePriority DateFiling Date
US11/795,835Continuation-In-PartUS8051637B2 (en)1997-12-232005-07-27Heat energy recapture and recycle and its new applications

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Publication NumberPublication Date
US20050120715A1true US20050120715A1 (en)2005-06-09

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US11/795,835Expired - Fee RelatedUS8051637B2 (en)1997-12-232005-07-27Heat energy recapture and recycle and its new applications

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EP (1)EP1851418A4 (en)
CN (1)CN101146981A (en)
AP (1)AP2007004109A0 (en)
AU (1)AU2005325208B2 (en)
CA (1)CA2599414A1 (en)
EA (1)EA200701538A1 (en)
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US8051637B2 (en)2011-11-08
AU2005325208B2 (en)2012-03-29
WO2006078315A1 (en)2006-07-27
AU2005325208A1 (en)2006-07-27
EP1851418A4 (en)2009-05-13
AP2007004109A0 (en)2007-08-31
EA200701538A1 (en)2008-10-30
CN101146981A (en)2008-03-19
EP1851418A1 (en)2007-11-07
CA2599414A1 (en)2006-07-27
WO2006078315A8 (en)2006-11-02
US20080155985A1 (en)2008-07-03

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