“THE GENERAL THEORY KINETIC MAGNETIC “ by: Juan Carlos Aviles Moran
|“THE GENERAL THEORY KINETIC MAGNETIC ” by: Juan Carlos Aviles Moran
This theory is based on the physical virtues presented by the magnets (The Stone “lover” It was so poetic name the Chinese gave the natural magnet or lodestone. The stone mistress (tshu-shi) – the Chinese say – attracts the iron , as well as a loving mother brings her children. It is interesting that the French, who inhabit the opposite end of the Old World, the imam gave a similar name, because in French the word “aimant” means “magnet” and “lover”. The strength of this love of natural magnets is very small and it seems naive to the Greeks call the Lodestone “Stone of Hercules.” If the inhabitants of ancient Hellas were amazed at both the modest attraction natural magnet.) or magnets (The name of magnetism probably derives from the city of Magnesia in ancient Asia Minor, where it would proceed first natural magnets or Iman, Sweden, in the Ural mountains, in North America, is are large masses of a mineral called lodestone iron ferrous ferric oxide, magnetic oxide, Fe3O4).
These virtues natural or physical phenomenon rather “Natural” present in the magnet or magnets, are to attract or repel depending on their magnetic polarity, ie the magnet is formed by a set of molecular magnets, neatly arranged with all north poles In the same direction (magnets is to sort the molecular magnets).
The molecular magnets are grouped one after another in rows that are called magnetic fillets.
The magnetized iron locks, according to this view, molecular magnets grouped in no particular order.
Imanes elementales orientados al azar ; son propios de sustancias no magneticas. Randomly oriented elementary magnets, are typical of magnetic substances. No existe atracción ; la polaridad de algunos compensa la de otros, quedando el conjunto no magnetico There is no attraction, the polarity of some offsets the other, leaving all non-magnetic
In a magnet all elementary magnets are oriented in the same way.
In a magnetic substance the elementary magnets are randomly oriented.
We could then say that a magnet to a magnet is made up of many electric charges in motion . Microscopic level we think that the atoms that form the magnet behave like elementary magnets arranged and oriented with their respective poles.
Imam Al breaking a magnet, each piece retains the properties of the magnet original.Un magnet is formed by many elementary magnets. Each of the pieces obtained by breaking a magnet retains the same properties as the original magnet, also with two poles.
In the steel without imanitos magnetize these atoms are in disorder, so the action of each of them is overridden by the other located on the reverse.
In the magnet, on the contrary, all elementary magnets are arranged, all the poles of the same name are headed in the same direction .
Un imán es pues un cuerpo o masa ferrica con un campo magnético significativo, de forma que tiende a alinearse con otros imanes. A magnet is then a body or mass of iron with a magnetic field significantly, so that tends to align with other magnets.
The ends of the magnet are called magnetic poles (Poles: The two ends of the magnet where the attractive forces are more intense. These poles are the North Pole and South Pole.)
One of the main features that distinguishes the magnet is the force of attraction or repulsion exerted on other metals, the magnetic lines that form between its polos.Cuando face two or more independent magnets approach each at both ends, if facing the poles have different polarities are attracted (eg conpolo north pole south), but if the polarities are the same (north pole north or south pole south), are rejected.
When approaching the poles of two magnets, immediately establishing a number of lines of magnetic force of attraction or repulsion, acting directamentesobre opposing poles. The lines of force of attraction or repulsion established between these poles are invisible, but their existence can be visually checked dehierro sprinkle filings on paper or cardboard and place it over one or more magnets.
Under this premise (magnetic strengths of the magnets or magnets) I base my “General Theory of Magnetic Kinetic” Kinetic understood the enegia displacement generated by a body (The kinetic energy of a body is an energy that arises in the phenomenon movement. It is defined as work needed to accelerate a body of a given mass from rest to the speed it has. Having gained this energy during acceleration, the body maintains its kinetic energy unless its speed changes. For the body back to its state of rest is required work of the same magnitude negative its kinetic energy).
. The adjective “kinetic” energy in the name comes from the ancient Greek word (kinesis “movement”). The term kinetic energy and work and scientific meanings of the nineteenth century.
The kinetics can be best understood with examples that demonstrate how it is transformed from other forms of energy and other types of energy. For example a cyclist will use energy chemical which provided food to accelerate his bicycle at a speed chosen. . Its speed can be maintained without much work , except for the resistance of air and friction. The energy converted into the energy of movement , known as kinetic energy but the process is not completely efficient and the cyclist also produces heat .
Taking as an example we compare the energy kinetics of the rider’s pedaling, comparing it with the thrust generated by the shock of the same polarity magnetic fields, (the magnetic fields that interact with other like polarity magnetic fields do not suffer from variations in temperature maintain a temperature that is stable or constant. remember no friction in this system rotating so there is no heat loss or heat gain). Thus the kinetic energy gained by the force of magnetic repellency is an efficient process.
Magnetic fields are usually represented by “magnetic field lines” or “lines of force . “ At any point, the direction of the magnetic field is equal to the direction of the lines of force, and the field strength is inversely proportional to the space between the lines.
the lines of force emerging from one end and bend to reach the other end, these lines can be considered as closed loops, with a portion of the loop in the magnet and away matches. At the ends of the magnet, where the force lines are closer, the magnetic field is more intense, on the sides of the magnet, where lines of force are farther apart, the magnetic field is weaker. According to its shape and magnetic force, the different types of magnets produce different patterns of lines of force. The structure of the lines of force created by a magnet or by any object that generates a magnetic field can be visualized using a compass or filings of iron . The magnets tend to be oriented along the magnetic field lines. Therefore, a compass, a small magnet that can rotate freely, will be oriented in the direction of the lines. Making a compass direction that points to put in different spots around the magnetic field source may be inferred the pattern of lines of force. Similarly, if iron filings are agitated on a sheet of paper or plastic over an object that creates a magnetic field, the filings are oriented along the lines of force and thus can display its structure.
It is the application of so-called drag lines or attraction of the magnetic field generated by bodies of different magnetic polarity which would slow a perpetual rotation system, which is why the cancellation of these lines of drag (magnetic attraction) gives way to new study kinetics directed magnetic repellency creating artificial monopoles that serve to unify the magnetic fields in order to use repellent collisions between like polarity magnetic fields to produce a continuous motion or mobile “perpetual.” the inclination of the rotor magnet inserts it into wedge in the cascade of rotating magnetic repellency Magnetical kinetics thermodynamics does not contradict because the magnetic fields that interact with other like polarity magnetic fields do not suffer from variations in temperature is kept stable or constant temperature. remember there is no friction in the rotary sitem therefore no heat loss or increased calor.Aislante magnetic shield is a forwarder or flow of the magnetic fields, you disable the faces of your selection, making the artificial monopolar magnet. : without shielding the magnets are turned repel and attract magneticos.Resumen thereby balancing the fields of the project URM (unit of magnetic repellency)? system called magnetic repellency unit taking into account certain parameters that they had not given much before:
. 1) The magnetic repellency when confronted result in the displacement of the lower body mass.
2) Using a ring or circle which is a geometric shape that manages power efficiently we can manage the repellency contained within the Aro towards thus creating a continuous movement and inside the ring if there is a succession of artificial magnets whether individual or a single that are part of the same polarity magnetic reject or repel the magnets placed on the ends of a shaft or rotor inside the ring will be given an imbalance or shock like polarity magnetic fields, this transfer of a magnet to another created a movement.
3) for the above is possible should be taken into account that there will only ring in magnetic repellency ie we shield or insulate the sides and edges of attraction to achieve this absolute repellency inside the ring
4) in the middle of the rotor shaft or give a twisting force whose strength and speed depends on the alloy and the mass of artificial magnets.
5) the force of torsion will be used to rotate or boost the shaft of a generator and thus generate electricity for free and without consumption of other energy repellency because it gives me unlimited power. MIS insights and opinions are personal and while this issue of the unit of magnetic repellency in swaddling clothes, I published on the internet in an attempt to work with an alternative system of electric generation that deserves to be researched and developed.
I firmly believe that the unit of magnetic repellency will be in the very near future a reality that is why I promote that there is still much we do not know in alloys and better insulation and being that the youth is the future I leave you all the proposed analysis and make their own guesses. Le annoying again to ask me to analyze magnetic repellency unit (MRU) in a thorough and impartial, I’ll tell certain parameters that govern my URM dispocicion or shock angle between magnetic fields of like polarity is critical in my URM as well as the disposition from the magnetic shielding or insulation ie these redirect the rotor, there is a multiplicity of variables to consider, such as artificial magnet alloy shield either the rotor or stator forms and surfaces of the magnets are reflected in magnetic repellency rather than its magnetic attraction. And do not forget the active unipolarity is an important factor seems easy but the MRU is a constant power imbalance repellency than willing to work the right way. . PLEASE discuss this project with friends URM professors and professionals. I demand of myself Remember the MRU that enhances or rotate the shaft of a dynamo The MRU is exactly like the traditional mills used just that URM repellency constant magnetic repellency funcionar.unidad name him that way because they have joined same design geometric shapes and physical effects of repellency long time ago trying to create a perpetual motion but it is until you discover the shielding has been possible to say this is artificial magnet magnetic fields give a boost magnified in proportion to their alloy if we add the suitable shield to prevent the distortion or deformation of one-pointed path repellency (CRM cascade of magnetic repellency) continually gets a movement. Magnetic Field = increased artificially magnified optimal shielding magnet alloys and interrupt lines drag force between the shielding imanesel must have a density greater than block the magnetic field of attraction of the magnets thus establishing a cascade of magnetic repellency is a path like a road along which the magnets of the shaft to be pushed back any bad positioning the ring is equivalent to a road bump magnets so no rotaranel shaft shielding should be proportional to the magnetic field of attraction remember but they are brought magnets the same polarity and repel at the same time trying to attract the attraction is there eliminarSI that you can create a continuous movement to generate electric power as knowing if you can I have my project for the unit of magnetic repellency and if If you can create a perpetual motion machine look visit my blog http : / / energia.obolog. com /
How can you stop a magnetic field? Is there anything that can prevent the passage of an electromagnetic field?
You can not completely stop a magnetic field, but you can reducir.Un alternating magnetic field, such as that produced by a transmitter of radio or resulting from an electric current (AC) in a transmission line or transformer may be
reduced by magnetic fields inside a container are electrically conductive, like a box or cylinder, induce currents in the container. By careful design, these containers can be constructed so that they cancel the magnetic field. These containers are usually made of copper or aluminum . Containers made from most types of steel static magnetic fields reduced (from a permanent magnet) and the fields changing (alternating) time, since the field prefer to travel to through the steel walls and not by the aire.La magnetic permeability is a measure of the amount of magnetism that material available in an applied magnetic field. For specialized applications, for example, some oscilloscopes tubes, magnetic fields are constructed using materials with very high magnetic permeability. One of these materials is & μmetal (mu metal), which has a magnetic permeability much higher than steel, copper or aluminum. Deformation (folding, for example) from & μmetal can dramatically reduce the magnetic permeability. The heating (annealing) at temperatures above 400 ° C can do to recover the magnetic properties & μmetal special.
Some materials are diamagnetic, which means that when exposed to a magnetic field, these materials in turn induce a weak magnetic field in the opposite direction. Es decir rechazan débilmente a un imán fuerte. That is weakly reject a strong magnet. Bismuth (Bi) and graphitic carbons are strong examples of diamagnetic materials. Other weaker diamagnetic materials are the water , the diamond and the tissue alive. Because of this property diamagnetic materials are capable of being used in so-called magnetic levitation, in which objects made of these materials can get to float on a strong magnet.
Ferromagnetic materials are those that are strongly attracted by magnetic force. Ejemplos de materiales ferromagnéticos son: el hierro (Fe), níquel (Ni), cobalto (Co), gadolino (Gd). Examples of ferromagnetic materials include iron (Fe), nickel (Ni), cobalt (Co), Gadolin (Gd). The reason that these metals with a strong magnetic attraction lies in the configuration e of its atoms, so that the atoms quickly alienate the magnetic field direction giving rise to domains, or groups of atoms alienated by the magnetic field. . Some ferromagnetic materials like iron alloys, nickel, cobalt and certain ceramic materials, magnetic properties may retain these for a long time can become permanent magnets or magnetic materials. In the case of carbon materials nanofoam of carbon has interesting magnetic properties and ferromagnetic.
Paramagnetic materials are metals that have a weak attraction to magnets. El aluminio (Al) y el cobre (Cu) son ejemplos de estos materiales. Aluminum (Al) and copper (Cu) are examples of these materials. These materials can become very weak magnets, but its attractive force can be measured only with sensitive instruments. The strength of a Paramagnetic magnet is about a million times smaller than that of a ferromagnetic, so these materials are considered non-magnetic.
Temperature affects the magnetic properties of a material. So paramagnetic materials can become magnetic at very low temperatures, whereas at high temperatures can reach ferromagnetic materials lose their magnetic properties. The temperature at which a material loses its magnetic properties is called the Curie temperature.
Juan Carlos Avilés Moran Juan Carlos Aviles Moran