Magnetic FuelSaver, other FuelSavers and Fuel Optimizers.
The combustion engine vehicle efficiency is about 9%. This means that your car consume more energy that it convert in movement. In other words, you pay more energy that you use. In this text I will describe you some methods and apparatus for improving the combustion of fluid fuel in combustion devices, such as general burners, incinerators, fuel oil boilers from appliance boilers to heat power boilers ( home or industrial heating ), combustion furnaces, and internal combustion engines in automobiles ( two-cycle and four-cycle, diesel and gasoline ), trucks, ships and jets, where the fuel employed is liquid or gaseous hydrofuels, such as gas, natural gas, propane, kerosene, gasoline, fuel oil, butane, etc...
Applying a magnetic field to ionizing fuel to be fed to combustion devices we can ensure more complete combustion, obtaining a maximization of the fuel economy, improving the fuel efficiency and reducing polluting emissions.
The fuel is subject to the lines of forces from permanent magnets mounted on fuel inlet lines. The magnet for producing the magnetic field is oriented so that its South pole (red) is located adjacent the fuel line and its North pole (blue) is located spaced apart from the fuel line.
The magnetic field strength must be at a higher Gauss level (500 Gauss) since it may be demagnetized to some extent before reaching the combustion chamber.
How it works.
Most fuels for internal combustion engines are liquid. But liquid fuels don't combust till they are vaporized and mixed with air.
Currently regulated gas emissions from motor vehicles are unburned hydrocarbon (HC), carbon monoxide (CO), and oxides of nitrogen (NOx). Unburned HC and NOx react in the atmosphere to form photo-chemical smog. Smog is highly oxidizing in the environment and is the prime cause of eye and throat irritation, bad odor, plant damage, and decreased visibility. Oxides of Nitrogen are also toxic. CO impair blood capability to carry oxygen to the brain, resulting in slower reaction times and impaired judgement.
Fuel mainly consists of hydrocarbons. Groupings of hydrocarbons, when flowing through a magnetic field, change their orientations of magnetization in a direction opposite to that of the magnetic field. The molecules of hydrocarbon change their configuration. At the same time intermolecular force is considerably reduced or depressed. These mechanisms are believed to help to disperse oil particles and to become finely divided. In addition, hydrogen ions in fuel and oxygen ions in air or steam are magnetized to form magnetic domains which are believed to assist in atomizing fuel into finer particles.
Generally a liquid or gas fuel used for an internal combustion engine is composed of a set of molecules. Each molecule includes a number of atoms, which is composed of a nucleus and electrons orbiting around their nucleus. The molecules have magnetic moments in themselves, and the rotating electrons cause magnetic phenomena. Thus, positive (+) and negative (-) electric charges exists in the fuel's molecules. For this reason, the fuel particles of the negative and positive electric charges are not split into more minute particles. Accordingly, the fuels are not actively interlocked with oxygen during combustion, thereby causing incomplete combustion. To improve the above, the fuels have been required to be decomposed and ionized. The ionization of the fuel particles is accomplished by the supply of magnetic force from a magnet.
The resultant conditioned fuel / air mixture magnetized burns more completely, producing higher engine output, better fuel economy, more power and most importantly reduces the amount of hydrocarbons, carbon monoxide and oxides of nitrogen in the exhaust. Another benefits if these devices is that magnetically charged fuel molecules with opposite polarities dissolve carbon build-up in carburetor jets, fuel injectors, and combustion chambers help to clean up the engine and maintain the clean condition.
The magnetic flux density to be imparted to fuel widely varies depending upon fuel, air or steam, and combustion equipment and conditions. In general, the preferred range of magnetic flux density is from 1000 to 3500 Gauss, and the most preferred range is from 1400 to 1800 Gauss when fuel oil is used in combination withconventional heat power boilers. The optimum range will be determined through experimental runs. The field strength is a function of the engine size based on fuel consumption.
The Ferrite magnets are the most cost effective for treating fuel. When high energy Neodymium Iron Boron Magnets are applied, we can obtain a decrease in the fuel mileage and unburned hydrocarbons and carbon monoxide.
The magnetizing apparatus is located on the pipe between pumping means and the burner, carburetor or fuel injectors, because it is unnecessary for any other parts to be magnetized. A portion of the fuel feeding system extending from a point downstream of the magnetizing apparatus to the burner must be made of non-magnetic material. In this case, magnetized fuel is directly fed to burners or atomizing nozzles with a minimum reduction of magnetism.
The magnets are embedded in a body of non-magnetic material, such as plastic, copper or aluminum, to secure they to the fuel line. No cutting of the fuel line and no hose and clamps are necessary to install this device, outside a fuel line without disconnection or modification of the fuel or ignition system for producing magnetic flux in the flow path of combustible fuel within the pipe. These units have been installed without other fuel line or ignition adjustments to treat vehicles failing required emission tests as an inexpensive retrofit accessory to give substantially immediate improvements of up to the order of 80 % reduction in hydrocarbon and carbon monoxide emissions.
In a preferred embodiment, one or more magnets are strapped to the fuel line as close as possible to the carburetor or fuel injectors with only one pole of the magnet or magnets adjacent to or in contact with the fuel line. One or more magnets are strapped to the air intake in such a way as to magnetically expose the oxygen to the magnetic field emanating from the pole opposite that of the pole used to expose the fuel.
The magnets should have a Curie temperature sufficiently high that they retain their magnetic characteristics at the operating temperatures to which they are exposed. For example, in an automobile engine, the fuel line magnets will lie above the engine block where relative heating will greatly increase their temperature. Some magnets lose much of their magnetic field strength as their temperature rise. The Curie temperature on Alnico magnet are 760\BAC to 890\BAC, on Ceramic magnets ( ferrite magnets ) 450\BAC, on Neodymium 310\BAC to 360\BAC and on Samarium 720\BAC a 825\BAC.
Examples of results.
Dust in exhaust gas from a boiler was measured by both weight and concentrate methods. It was found that at the same weight of dust contained in exhaust gas, the exhaust gas generated after the magnetizing treatment according to these devices exhibited in higher value in concentration than that generated without magnetization. This fact that dust particles after magnetization are finer than those usually found, which in turn, means that oil particles are made finer by the magnetizing treatment of these devices.
In boilers the combustion conditions are improved by applying magnetism to fuel according to these devices.
Results in automobile comsume tests:
With a magnetic field we can increase the internal energy of the fuel, to cause specific changes at a molecular level. Increasing the internal energy to obtain more easier combustion. The molecules fly apart easier, join with oxygen easier and ignite easier. 'Ionization' implies that the fuel acquires a 'charge' and molecules of like charge repel each other, this makes fuel dispersal more efficient. Then if you charge the air to the opposite polarity, then the fuel and oxygen combine far quicker than 'normal'. We can obtain about:
The resultant conditioned fuel/air mixture magnetized in opposite polarities burns more completely, producing higher engine output, better fuel economy, more power and most importantly reduces the amount of hydrocarbons, carbon monoxide and oxides of nitrogen in the exhaust. Another benefits if these devices is that magnetically charged fuel and air molecules with opposite polarities dissolve carbon build-up in carburetor jets, fuel injectors, and combustion chambers help to clean up the engine and maintain the clean condition.
VERY IMPORTANT NOTE: This material has been written and published solely for educational and amusement purposes. The author provide this information, and the reader accepts it, with the understanding that people act on it at their own risk.
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