BRPI1104158A2 - Parallel element electromagnetic system - Google Patents

Abstract

Electromagnetic system of parallel elements. The present invention combines coils (2 and 13) located on static part (1 and 12) and magnetic (4 and 8) or ferromagnetic (15) elements located on the periphery of the interacting rotating part (5, 11, 16 and 17). to each other by the action of the synchronized system (6) on the key (7) providing a rotational movement on the drive shaft (10) for direct current and direct on the rotor for alternating current. Said system consists of straight coils (2 and 13), straight section (3 and 14), magnetic elements (4 and 8), ferromagnetic (15), rotors (5 and 11), coupled to the synchronized system (6), key (7), rotors (16 and 17). Providing a rotational movement on the drive shafts (10 and 18). The combination of these devices and elements can optimize and improve electric motors.

Description

The present invention relates to an electric motor, which basically consists of the interaction between the stator formed by electromagnetic coils and the rotor formed by magnetic or ferromagnetic elements, arranged peripherally in a circumference, which tangents the coils. at both poles, providing optimum efficiency and low entropy. Notwithstanding the widespread use of electric motors, some drawbacks can be attributed to them, such as the large dispersion of the magnetic field due to their shape which requires a total excitation of static as well as induced winding, causing considerable losses with the appearance of counter electromotive force.

Another example of inconvenience is the high consumption of electricity as a function of efficiency.

In order to solve such drawbacks, the present invention has been developed, whereby the electric motor is mounted in a specific shape maximizing the magnetic flux in a straight coil model with its poles tangenting the elements, magnetic for direct current or ferromagnetic for alternating current of the rotors enabling a larger lever arm, optimizing efficiency by punctually driving the coils thereby minimizing power consumption.

This form of motor construction solves the drawbacks, since the magnetic field is punctually directed within the time needed for the movement of the rotors. The motor cycle begins when the coil has its cross-sectional area coinciding with the elements, direct current magnetic or alternating current ferromagnetic, of the rotating part of the mechanism. When the straight coil is actuated by the synchronized system key, producing electromagnetism, it moves the magnetic element over it by the magnetic reaction phenomenon, then moves the opposite pole magnetic element. As it approaches the reversal plane, the synchronized system key cuts the electrical current of the straight coil and the magnetic element travels, repeating this effect on all elements that make up the rotor producing a rotating motion. . Consequently, the same process occurs on the opposite side of the straight spool, since there is another rotor with the same characteristics as the first one. For alternating current, the straight coil is driven by the electric power switch, electromagnetism is produced, displacing the rotors by the phenomenon of magnetic reaction, repeating this effect on all the elements that form the rotors, thus producing a rotational movement. on the transmitter shaft. Consequently, the same process occurs on the opposite side of the straight spool, since the rotors are parallel to it and have the same characteristics. The invention may be better understood by the following detailed description in accordance with the accompanying drawings, where: FIGURE 1 represents the general scheme of the direct current system; FIGURE 2 is a side section of the direct current system; FIGURE 3 represents the direct current rotors; FIGURE 4 represents the general scheme of the alternating current system; FIGURE 5 is a side view of the alternating current system; FIGURE 6 represents the alternating current rotors.

With reference to these figures, we can observe, for direct current, in the static part (1) the coil (2) with its straight section (3) coinciding with the magnetic element (4) of the rotating part (5). At this moment the synchronized system (6) activates the switch (7) which activates the electric current of the coil (2) that reacts with the magnetic element (4), moving the rotor (5) from its starting point. It then moves the magnetic element (8) from the opposite pole. As the inversion plane (9) is approached, the synchronized system (6) opens the switch (7) by cutting off the electrical current from the coil (2) so that the magnetic element (8) continues in its course. After the reversal plane (9) the synchronized system (6) repeats the two-by-two magnetic element procedure until the cycle closes, producing a rotational movement on the drive shaft (10). Simultaneously, on the other side of the coil (2) in another rotor (11) with the same characteristics as rotor (5), the process is repeated. For alternating current, we can observe in static part (12) the coil (13) with its straight section (14) coinciding with the ferromagnetic elements (15) of the rotating part (16). At this moment the electric current of the coil (13) which reacts with the ferromagnetic elements (15) is activated, displacing the rotor (16) from its starting point. Simultaneously, on the other side of the coil (13) in another rotor (17) with the same characteristics as rotor (16), the process repeats, producing a rotational motion in the drive shaft (18).

Claims (3)

1a "ELECTROMAGNETIC PARALLEL SYSTEM", characterized in that they consist of coils (2 and 13) with straight section (3 and 14) that drive the system, rotors (5, 11, 16 and 17) with magnetic elements ( 4 and 8) and ferromagnetic (15) synchronized switching system (6) in conjunction with the drive shaft (10) and drive shaft (18). Parallel element electromechanical system according to claim 1, characterized in that the mechanism has a synchronized switching system (6) and rotors (5, 11, 16 and 17) which enable the rotational movement through interaction. of the coils (2 and 13) with the magnetic (4 and 8) or ferromagnetic (15) elements. Parallel element electromechanical system according to claim 2a, characterized in that the mechanism has a specific construction for direct current and alternating current, optimizing the applications.