11-02-2012, 12:29 PM
Fuel Energizer
INTRODUCTION
Today’s hydrocarbon fuels leave a natural deposit of carbon residue that clogs carburetor, fuel injector, leading to reduced efficiency and wasted fuel. Pinging, stalling, loss of horsepower and greatly decreased mileage on cars are very noticeable. The same is true of home heating units where improper combustion wasted fuel (gas) and cost, money in poor efficiency and repairs due to build-up.
Most fuels for internal combustion engine are liquid, fuels do not combust until they are vaporized and mixed with air. Most emission motor vehicle consists of unburned hydrocarbons, carbon monoxide and oxides of nitrogen. Unburned hydrocarbon and oxides of nitrogen react in the atmosphere and create smog. Smog is prime cause of eye and throat irritation, noxious smell, plat damage and decreased visibility. Oxides of nitrogen are also toxic.
Generally fuels for internal combustion engine is compound of molecules. Each molecule consists of a number of atoms made up of number of nucleus and electrons, which orbit their nucleus. Magnetic movements already exist in their molecules and they therefore already have positive and negative electrical charges. However these molecules have not been realigned, the fuel is not actively inter locked with oxygen during combustion, the fuel molecule or hydrocarbon chains must be ionized and realigned. The ionization and realignment is achieved through the application of magnetic field created by ‘Fuel Energizer’.
Fuel mainly consists of hydrocarbon and when fuel flows through a magnetic field, such as the one created by the fuel energizer, the hydrocarbon change their orientation and molecules of hydrocarbon change their configuration. At the same time inter molecular force is considerably reduced or depressed. These mechanisms are believed to help disperse oil particles and to become finely divided. This has the effect of ensuring that fuel actively interlocks with oxygen producing a more complete burn in the combustion chamber. The result is higher engine out put, better fuel economy and reduction in hydrocarbons, carbon monoxide and oxides of nitrogen that are emitted though exhaust. The ionization fuel also helps to dissolve the carbon build-up in carburetor, jets, fuel injector and combustion chamber, there by keeping the engines clear condition. Also it works on any vehicle or device (cooking gas stove) using liquid or gas fuel.
WHAT FUEL ENERGIZER DOES?
• More mileage (up to 28% increase) per liter due to 100% burning fuel.
• No fuel wastage.
• Increased pick-up.
• Reduced engine noise.
• Reduced smoke.
• Faster A/C cooling.
• Smooth running, long term maintenance free engine.
• 30% extra life for expensive catalytic converter.
HOW IT INSTALL?
Magnetizer Fuel Energizer (eg:- Neodymium super conductor – NSCM) is installed on cars, trucks immediately before carburetor or injector on fuel line. On home cooking gas system it is installed just before burner.
THE MAGNETIZER & HYDROCARBON FUEL
The simplest of hydrocarbons, methane, (CH4) is the major (90%) constituent of natural gas (fuel) and an important source of hydrogen. Its molecule is composed of one carbon atom and four hydrogen atoms, and is electrically neutral. From the energy point of view, the greatest amount of releasable energy lies in the hydrogen atom. Why? In octane (C8H18) the carbon content of the molecule is 84.2%. When combusted, the carbon portion of the molecule will generate 12,244 BTU (per pound of carbon). On the other hand, the hydrogen, which comprises only 15.8% of the molecular weight, will generate an amazing 9,801 BTU of heat per pound of hydrogen.
Hydrogen, the lightest and most basic element known to man, is the major constituent of hydrocarbon fuels (besides carbon and smaller amount of sulphur and inert gases). It has one positive charge (proton) and one negative charge (electron), i.e. it possesses a dipole moment. It can be either diamagnetic or paramagnetic (weaker or stronger response to the magnetic flux) depending on the relative orientation of its nucleus spins. Even though it is the simplest of all elements, it occurs in two distinct isomeric varieties (forms) - para and ortho. It is characterized by the different opposite nucleus spins. In the para H2 molecule, which occupies the even rotation levels (quantum number), the spin state of one atom relative to another is in the opposite direction ("counterclockwise", "antiparallel", "one up & one down"), rendering it diamagnetic; whereas in the ortho molecule, which occupies the odd rotational levels, the spins are parallel ("clockwise", "coincident", "both up"), with the same orientation for the two atoms; therefore, is paramagnetic and a catalyst for many reactions. Thus, the spin orientation has a pronounced effect on physical properties (specific heat, vapor pressure) as well as behavior of the gas molecule. The coincident spins render orthohydrogen exceedingly unstable. In fact, orthohydrogen is more reactive than its parahydrogen counterpart. The liquid hydrogen fuel that is used to power the space shuttle or rockets is stored, for safety reasons, in the less energetic, less volatile, less reactive parahydrogen form. During the start of the shuttle, the orthohydrogen form is beneficial since it allows to intensify the combustion processes. To secure conversion of para to ortho state, it is necessary to change the energy of interaction between the spin state of the H2 molecule.
ATOM OF HYDROGEN IN ITS PARA AND
ORTHO STATE
Any utility patent must be proven operable and scientifically correct before issuance. The same principle has been utilized, and the same effect has been achieved by the action of the Magnetizer where a strong enough flux field was developed to substantially change the hydrocarbon molecule from its para state to the higher energized ortho state. The spin effect of the fuel molecules can be ascertained optically, based on refraction of light rays passing through liquid fuel as had been demonstrated by scientists while using infrared cameras installed, e.g. in metallurgical ovens where the Magnetizer’s had been effectively working. Furthermore, the conversion of hydrogen into ortho H2 (taking place very fast in this strong & unique magnetic field, with the simultaneous transformation of the system from a symmetrical into highly active anti-symmetrical molecular state of increased reactivity and catalytic ability) has been found highly advantageous in many technologies, especially those where hydrogen is used.
Hydrocarbons have basically a "cage-like" structure. That is why oxidizing of their inner carbon atoms during the combustion process are hindered. Furthermore, they bind into larger groups of pseudo-compounds. Such groups form clusters (associations). The access of oxygen in the right quantity to the interior of the groups of molecules is hindered. (It has nothing to do with incoming air from the manifold in the fuel mixture when even though there may be excess of it, this will not provide the required hydrocarbon-oxygen binding.) and stemming from this shortage of oxygen to the cluster that hinders the full combustion. In order to combust fuel, proper quantity of oxygen from air is necessary for it to oxidize the combustible agents.
For many years, designers of the internal combustion engines have had one goal: to oppose the effect of molecular association of the hydrocarbon fuel and to optimize the combustion process. The peculiar problem in designing engines for air pollution is that in order to fully burn all the hydrocarbons in the combustion chamber, operating temperatures of the cylinders have had to be increased. While older engines may have produced relatively large quantities of unburned hydrocarbons and carbon monoxide, they produced low quantities of oxides of nitrogen. Also, with the renewed interest in performance engines, compression ratios are creeping upward again, and once again the mechanism for producing higher levels of nitrogen toxins is increased. Similarly, turbo charging effectively alters the compression ratio of a vehicle, further adding to the nitrogen problem.
The feed and exhaust systems have been perfected, the ignition controlling electronics has been perfected, the fuel/air mix metering devices have been brought to perfection, and finally the catalytic converters (see below) have been found indispensable. But even then, fumes that leave the "afterburners" are not ideally clean - engine still burns only part of the fuel (or precisely the incompletely oxidized carbon atoms in the form of CO). The rest is discharged as polluting emissions (HC, CO, NOx) or is deposited on the internal engine walls as black carbon residue. All this has been caused by the incomplete combustion process. The reasons for it being that:
• Hydrocarbons form the so-called associations, close molecular groups, interior of which is deprived of access of the suitable amount of air; the lack of oxygen impedes the full combustion.
Note: The tendency of HC molecules to cluster causes local macro-groupings (condensing) of molecules to clog the pipes and fuel nozzles. The excess of air in the fuel mixture will not provide for the complete combustion. Hence, the exhaust fumes contain considerable amounts of unburned CO, HC, and soots.
• Oxygen with negative 2 valence is negative, and hydrocarbon has neutral molecular structures, which by passing through steel fuel lines gets negatively (micro) charged. Therefore, when these two atoms come together with the same potential in a combustion chamber, they repel, which result in incomplete combustion. Therefore, all serious research has been aimed at bringing about fuel reactivity with oxygen (oxygenated fuels); since increased oxidation means increased combustion, and the following rules had to be taken into consideration:
Rule 1: Unburned hydrocarbon (HC) as well as carbon monoxide (CO) emitted from a vehicle's exhaust system can be viewed as the additional fuel reserve, since, if proper conditions are met, HC & CO can be further burned in the combustion chamber. Therefore, creating such proper combustion conditions is paramount.
Rule 2: Hydrogen's chemical reaction, determined by its valence (the electron "surplus" in the "outer" orbital shell), is affected by a magnetic field since proper magnets are the prime source of control of the position of electrons.
Rule 3: he application of a proper magnetic field enforces beneficial changes in fuel structure and enhances its general reactivity in the combustion process.
Rule 4: If a hydrocarbon molecule could better bind with oxygen molecules
(be more completely oxidized), then the toxicity of fumes would be considerably limited and in principle, one could dispense with catalytic converters
INTRODUCTION
Today’s hydrocarbon fuels leave a natural deposit of carbon residue that clogs carburetor, fuel injector, leading to reduced efficiency and wasted fuel. Pinging, stalling, loss of horsepower and greatly decreased mileage on cars are very noticeable. The same is true of home heating units where improper combustion wasted fuel (gas) and cost, money in poor efficiency and repairs due to build-up.
Most fuels for internal combustion engine are liquid, fuels do not combust until they are vaporized and mixed with air. Most emission motor vehicle consists of unburned hydrocarbons, carbon monoxide and oxides of nitrogen. Unburned hydrocarbon and oxides of nitrogen react in the atmosphere and create smog. Smog is prime cause of eye and throat irritation, noxious smell, plat damage and decreased visibility. Oxides of nitrogen are also toxic.
Generally fuels for internal combustion engine is compound of molecules. Each molecule consists of a number of atoms made up of number of nucleus and electrons, which orbit their nucleus. Magnetic movements already exist in their molecules and they therefore already have positive and negative electrical charges. However these molecules have not been realigned, the fuel is not actively inter locked with oxygen during combustion, the fuel molecule or hydrocarbon chains must be ionized and realigned. The ionization and realignment is achieved through the application of magnetic field created by ‘Fuel Energizer’.
Fuel mainly consists of hydrocarbon and when fuel flows through a magnetic field, such as the one created by the fuel energizer, the hydrocarbon change their orientation and molecules of hydrocarbon change their configuration. At the same time inter molecular force is considerably reduced or depressed. These mechanisms are believed to help disperse oil particles and to become finely divided. This has the effect of ensuring that fuel actively interlocks with oxygen producing a more complete burn in the combustion chamber. The result is higher engine out put, better fuel economy and reduction in hydrocarbons, carbon monoxide and oxides of nitrogen that are emitted though exhaust. The ionization fuel also helps to dissolve the carbon build-up in carburetor, jets, fuel injector and combustion chamber, there by keeping the engines clear condition. Also it works on any vehicle or device (cooking gas stove) using liquid or gas fuel.
WHAT FUEL ENERGIZER DOES?
• More mileage (up to 28% increase) per liter due to 100% burning fuel.
• No fuel wastage.
• Increased pick-up.
• Reduced engine noise.
• Reduced smoke.
• Faster A/C cooling.
• Smooth running, long term maintenance free engine.
• 30% extra life for expensive catalytic converter.
HOW IT INSTALL?
Magnetizer Fuel Energizer (eg:- Neodymium super conductor – NSCM) is installed on cars, trucks immediately before carburetor or injector on fuel line. On home cooking gas system it is installed just before burner.
THE MAGNETIZER & HYDROCARBON FUEL
The simplest of hydrocarbons, methane, (CH4) is the major (90%) constituent of natural gas (fuel) and an important source of hydrogen. Its molecule is composed of one carbon atom and four hydrogen atoms, and is electrically neutral. From the energy point of view, the greatest amount of releasable energy lies in the hydrogen atom. Why? In octane (C8H18) the carbon content of the molecule is 84.2%. When combusted, the carbon portion of the molecule will generate 12,244 BTU (per pound of carbon). On the other hand, the hydrogen, which comprises only 15.8% of the molecular weight, will generate an amazing 9,801 BTU of heat per pound of hydrogen.
Hydrogen, the lightest and most basic element known to man, is the major constituent of hydrocarbon fuels (besides carbon and smaller amount of sulphur and inert gases). It has one positive charge (proton) and one negative charge (electron), i.e. it possesses a dipole moment. It can be either diamagnetic or paramagnetic (weaker or stronger response to the magnetic flux) depending on the relative orientation of its nucleus spins. Even though it is the simplest of all elements, it occurs in two distinct isomeric varieties (forms) - para and ortho. It is characterized by the different opposite nucleus spins. In the para H2 molecule, which occupies the even rotation levels (quantum number), the spin state of one atom relative to another is in the opposite direction ("counterclockwise", "antiparallel", "one up & one down"), rendering it diamagnetic; whereas in the ortho molecule, which occupies the odd rotational levels, the spins are parallel ("clockwise", "coincident", "both up"), with the same orientation for the two atoms; therefore, is paramagnetic and a catalyst for many reactions. Thus, the spin orientation has a pronounced effect on physical properties (specific heat, vapor pressure) as well as behavior of the gas molecule. The coincident spins render orthohydrogen exceedingly unstable. In fact, orthohydrogen is more reactive than its parahydrogen counterpart. The liquid hydrogen fuel that is used to power the space shuttle or rockets is stored, for safety reasons, in the less energetic, less volatile, less reactive parahydrogen form. During the start of the shuttle, the orthohydrogen form is beneficial since it allows to intensify the combustion processes. To secure conversion of para to ortho state, it is necessary to change the energy of interaction between the spin state of the H2 molecule.
ATOM OF HYDROGEN IN ITS PARA AND
ORTHO STATE
Any utility patent must be proven operable and scientifically correct before issuance. The same principle has been utilized, and the same effect has been achieved by the action of the Magnetizer where a strong enough flux field was developed to substantially change the hydrocarbon molecule from its para state to the higher energized ortho state. The spin effect of the fuel molecules can be ascertained optically, based on refraction of light rays passing through liquid fuel as had been demonstrated by scientists while using infrared cameras installed, e.g. in metallurgical ovens where the Magnetizer’s had been effectively working. Furthermore, the conversion of hydrogen into ortho H2 (taking place very fast in this strong & unique magnetic field, with the simultaneous transformation of the system from a symmetrical into highly active anti-symmetrical molecular state of increased reactivity and catalytic ability) has been found highly advantageous in many technologies, especially those where hydrogen is used.
Hydrocarbons have basically a "cage-like" structure. That is why oxidizing of their inner carbon atoms during the combustion process are hindered. Furthermore, they bind into larger groups of pseudo-compounds. Such groups form clusters (associations). The access of oxygen in the right quantity to the interior of the groups of molecules is hindered. (It has nothing to do with incoming air from the manifold in the fuel mixture when even though there may be excess of it, this will not provide the required hydrocarbon-oxygen binding.) and stemming from this shortage of oxygen to the cluster that hinders the full combustion. In order to combust fuel, proper quantity of oxygen from air is necessary for it to oxidize the combustible agents.
For many years, designers of the internal combustion engines have had one goal: to oppose the effect of molecular association of the hydrocarbon fuel and to optimize the combustion process. The peculiar problem in designing engines for air pollution is that in order to fully burn all the hydrocarbons in the combustion chamber, operating temperatures of the cylinders have had to be increased. While older engines may have produced relatively large quantities of unburned hydrocarbons and carbon monoxide, they produced low quantities of oxides of nitrogen. Also, with the renewed interest in performance engines, compression ratios are creeping upward again, and once again the mechanism for producing higher levels of nitrogen toxins is increased. Similarly, turbo charging effectively alters the compression ratio of a vehicle, further adding to the nitrogen problem.
The feed and exhaust systems have been perfected, the ignition controlling electronics has been perfected, the fuel/air mix metering devices have been brought to perfection, and finally the catalytic converters (see below) have been found indispensable. But even then, fumes that leave the "afterburners" are not ideally clean - engine still burns only part of the fuel (or precisely the incompletely oxidized carbon atoms in the form of CO). The rest is discharged as polluting emissions (HC, CO, NOx) or is deposited on the internal engine walls as black carbon residue. All this has been caused by the incomplete combustion process. The reasons for it being that:
• Hydrocarbons form the so-called associations, close molecular groups, interior of which is deprived of access of the suitable amount of air; the lack of oxygen impedes the full combustion.
Note: The tendency of HC molecules to cluster causes local macro-groupings (condensing) of molecules to clog the pipes and fuel nozzles. The excess of air in the fuel mixture will not provide for the complete combustion. Hence, the exhaust fumes contain considerable amounts of unburned CO, HC, and soots.
• Oxygen with negative 2 valence is negative, and hydrocarbon has neutral molecular structures, which by passing through steel fuel lines gets negatively (micro) charged. Therefore, when these two atoms come together with the same potential in a combustion chamber, they repel, which result in incomplete combustion. Therefore, all serious research has been aimed at bringing about fuel reactivity with oxygen (oxygenated fuels); since increased oxidation means increased combustion, and the following rules had to be taken into consideration:
Rule 1: Unburned hydrocarbon (HC) as well as carbon monoxide (CO) emitted from a vehicle's exhaust system can be viewed as the additional fuel reserve, since, if proper conditions are met, HC & CO can be further burned in the combustion chamber. Therefore, creating such proper combustion conditions is paramount.
Rule 2: Hydrogen's chemical reaction, determined by its valence (the electron "surplus" in the "outer" orbital shell), is affected by a magnetic field since proper magnets are the prime source of control of the position of electrons.
Rule 3: he application of a proper magnetic field enforces beneficial changes in fuel structure and enhances its general reactivity in the combustion process.
Rule 4: If a hydrocarbon molecule could better bind with oxygen molecules
(be more completely oxidized), then the toxicity of fumes would be considerably limited and in principle, one could dispense with catalytic converters