TWM559540U - Electric motor with magnet set misaligned to magnetic device - Google Patents

Abstract

The present invention relates to an electric device with a magnetic pole eccentricity relative to a magnetic pole, which has an induction coil group, and a horizontal magnetic group and a vertical magnetic group which are synchronously movable in opposite directions are respectively arranged on both sides of the induction coil group. Wherein the horizontal magnetic group is composed of at least one first magnetic member having magnetization in a moving direction, and the perpendicular magnetic group is composed of at least one second magnetic member having a magnetization direction and a moving direction, and The first and second magnetic members are arranged in a relative arrangement, and a switch group for selectively supplying power to the coil is disposed between the induction coil group and the horizontal magnetic group and the perpendicular magnetic group, thereby eliminating the induced voltage when the power is not supplied. It can be driven with low power, and can simultaneously promote dual magnetic assistance while power transmission, and increase output kinetic energy to achieve a significant increase in energy conversion rate.

Description

Electric device with magnetic group eccentricity

This creation belongs to the field of electromagnetic technology of energy conversion, specifically refers to an electric device capable of eliminating the induced voltage and increasing the relative magnetic pole eccentricity of the magnetic group, so as to achieve the effect of micro-power startup, effectively use Energy, while enhancing magnetic assistance and increasing output power, thereby improving its energy conversion efficiency.

According to the structure of the general motor, the stator and the rotor are formed by a relative rotational movement, wherein the inner edge of the stator is provided with a plurality of coils, and the outer edge of the rotor is provided with a plurality of magnetic members corresponding to the coils, and the coils are transmitted through the pair of coils. The intermittent power supply causes the coil to be magnetized, and the magnetic member of the rotor generates a magnetic force that repels and attracts, thereby driving the rotor to rotate at a high speed.

When the motor is in operation, the intermittent power supply mode is adopted, and the required magnetic force is extracted to drive the rotor, but due to the influence of the arrangement of the coil and the magnetic member, the coil is still subjected to inertia at the moment of suspending the power supply. In the magnetic magnetic line cutting effect, the induced electromotive force is generated to form an intrinsic voltage, so the general motor input power demand is large, and unnecessary energy waste is added. Influenced by the magnetic attraction effect, the proliferation between the rotor and the stator is not conducive to the magnetic resistance of the motion, slowing down the overall operating speed, resulting in poor output power and low energy conversion efficiency.

In other words, if it can effectively eliminate the induced voltage before power supply and the magnetic assistance when accelerating power, it will produce low energy consumption and high output. How to achieve this goal is the industry's urgent need for developers.

In view of this, the creator has in-depth discussion on the problems faced by the above-mentioned existing electric devices, and has actively pursued solutions through years of research and development experience in related industries, and has succeeded in research and trials. The development of an electric device with a magnetic group opposite to the magnetic pole is used to overcome the inconvenience and trouble caused by the large induced voltage and the large magnetic reluctance.

Therefore, the main purpose of the present invention is to provide an electric device in which the magnetic group is ectopically opposed to the magnetic pole, thereby reducing the input power and further improving the energy conversion efficiency by eliminating the induced voltage.

Moreover, the main purpose of the present invention is to provide an electric device with a magnetic group eccentricity relative to the magnetic pole, which can reduce the kinetic energy loss, increase the forward magnetic assistance, effectively increase the running speed, and further enhance the output power.

Based on this, the present invention mainly achieves the foregoing objects and functions by the following technical means. The electric device comprises an induction coil group, a horizontal magnetic group, a perpendicular magnetic group and a switch group, wherein the horizontal magnetic group And the perpendicular magnetic group can synchronize the movement of the relative induction coil group: The inductive coil assembly has at least one coil member, and each of the coil members has a magnet extending in a vertical direction of movement and at least one coil disposed on the magnetizer, and the coils are connected to an electric power source; Further, the horizontal magnetic group is composed of at least one first magnetic member having magnetization in a moving direction, and one end of each of the first magnetic members at a level before and after the corresponding movement direction is close to the end of the induction coil group. a first magnetic pole, and a second magnetic pole is formed at an end of the corresponding moving direction away from the induction coil group; In addition, the perpendicular magnetic group is composed of at least one second magnetic member magnetized in a vertical direction, and one end of the corresponding upper and lower ends of each of the second magnetic members forms a third The magnetic pole, different from the one end of the induction coil group, forms a fourth magnetic pole, and the first magnetic member of the horizontal magnetic group is equal in length and oppositely arranged with the second magnetic member of the perpendicular magnetic group, and the horizontal magnetic body is opposite The first magnetic pole of the first magnetic component is the same magnetic pole as the third magnetic pole of the second magnetic component of the perpendicular magnetic component; and the switch group is composed of a power supply switch, a power-off switch and two sensing elements The sensing element may be disposed on the coil component axis of the induction coil group corresponding to the horizontal magnetic group and the perpendicular magnetic group, and the first magnetic component of the horizontal magnetic group is electrically connected to the induction coil. The first pole end portion of the group is disposed, and the power-off switch is disposed on a central axis of the third magnetic pole side of the second magnetic member of the perpendicular magnetic group to form a state in which the front portion is powered.

Thereby, the electric device of the present magnetic group relative to the magnetic pole eccentric is realized by the above-mentioned technical means, which can be magnetized by the horizontal magnetic group in the moving direction, and the perpendicular magnetic group is magnetized in the opposite vertical moving direction, so that The magnetic lines of the two are relatively compressed to form a magnetic beam parallel to the direction of motion, so that the magnetic lines of force do not cause cutting, and the induced voltage can be eliminated, so that it can be driven by low power input, effectively use energy, and simultaneously open and close through the switch group. At the same time, it can obtain comprehensive magnetic assistance, which can provide high output power under low input power, which can effectively improve the efficiency of energy conversion, so it can greatly increase its added value and improve its economic benefits.

In order to enable the reviewing committee to further understand the composition, features and other purposes of the present invention, the following is a preferred embodiment of the present invention, and the detailed description of the present invention is as follows, and the person skilled in the art can implement it.

(10)‧‧‧Induction coil set

(11)‧‧‧Circle parts

(12) ‧‧ ‧ magnets

(13)‧‧‧ coil

(20) ‧‧‧ horizontal magnetic group

(21)‧‧‧First magnetic parts

(211)‧‧‧First magnetic pole

(212)‧‧‧Second magnetic pole

(30) ‧‧‧Overhead magnetic group

(31)‧‧‧Second magnetic parts

(311)‧‧‧ Third magnetic pole

(312)‧‧‧4th magnetic pole

(40)‧‧‧ switch group

(41)‧‧‧Power switch

(42)‧‧‧Power switch

(45)‧‧‧Inductive components

(46)‧‧‧Inductive components

Fig. 1(A) is a schematic view showing the structure of the first embodiment of the electric device with respect to the magnetic poles of the present magnetic group, for explaining the state of the electric terminal in the front portion of the magnetic group.

Fig. 1(B) is a schematic view showing the structure of the second embodiment of the electric device with respect to the magnetic poles of the present magnetic group, for explaining the state of the other power supply terminal in the front portion of the magnetic group.

Fig. 2(A) is a schematic view showing the structure of the third embodiment of the electric device with respect to the magnetic poles of the present magnetic group, for explaining the state of the electric terminal in the rear stage of the magnetic group.

Fig. 2(B) is a schematic view showing the structure of the fourth embodiment of the electric device with respect to the magnetic poles of the present magnetic group, for explaining the state of the other power supply end in the rear stage of the magnetic group.

Fig. 3 (A) to (C) are diagrams showing the operation of power supply in the first stage of the first embodiment of the present invention.

Fig. 4(A) to (C) are diagrams showing the operation of the second embodiment of the present invention in the preceding stage.

Fig. 5 (A) to (C) are diagrams showing the operation of the third embodiment of the present invention in the latter stage.

Fig. 6 (A) to (C) are diagrams showing the operation of the fourth embodiment of the present invention in the latter stage.

Figure 7 is a schematic view showing the architecture of the fifth embodiment of the electric device with respect to the magnetic pole eccentricity of the present magnetic group, for explaining the horizontal magnetic group and the perpendicular magnetic group Two or more previous stages are connected to the power state.

Fig. 8 is a schematic view showing the structure of the sixth embodiment of the electric device with respect to the magnetic poles of the present magnetic group, for explaining the power supply state of the horizontal magnetic group and the perpendicular magnetic group after two or more series connection.

The present invention relates to an electric device in which a magnetic group is eccentric with respect to a magnetic pole, and in the specific embodiment of the present invention and its components, all of which relate to front and rear, left and right, top and bottom, upper and lower, and horizontal The reference to the vertical is for convenience of description only, and does not limit the creation, nor restricts its components to any position or spatial orientation. The drawings and the dimensions specified in the specification may be varied according to the design and needs of the specific embodiments of the present invention, without departing from the scope of the invention.

The electric device of the present invention is configured to be different from the magnetic pole eccentricity, as shown in Figures 1 and 2, the electric device has an induction coil group (10), and is disposed on both sides of the induction coil group (10). a horizontal magnetic group (20) magnetized in a moving direction and a perpendicular magnetic group (30) magnetized in a vertical direction, and the horizontal magnetic group (20) and the perpendicular magnetic group (30) are synchronous with each other The group (10) moves, and the induction coil group (10) is provided with a switch group (40) between the horizontal magnetic group (20) and the vertical magnetic group (30), and the switch group (40) is operable Selectively powering the induction coil group (10); and the detailed configuration of the first embodiment of the present invention is the same as that of the first embodiment (A) and (B). The induction coil group (10) may be defined as a stator, and the induction coil group (10) is composed of one or more coil members (11) [for more than one, please refer to the seventh The embodiment shown in FIG. 8 and each of the coil members (11) has a magnet (12) extending in a vertical direction of movement and at least one coil (13) disposed on the magnetizer (12). The coils (13) are connected to an electric power source, and when the electric power source is supplied to the coil (13), the coil member (11) can be magnetized to synchronously drive the horizontal magnetic group (20) and the perpendicular magnetic group (30) as the rotor. And the horizontal magnetic group (20) is formed by at least one first magnetic member (21) having magnetization in the moving direction. [For more than one, please refer to the embodiments shown in FIGS. 7 and 8] And one end of the first magnetic member (21) horizontally before and after the corresponding moving direction close to the induction coil group (10) may be defined as a first magnetic pole (211) [ie, N pole or S pole], and corresponding motion One end of the direction away from the induction coil group (10) may be defined as a second magnetic pole (212) [ie, S pole or N pole]; and the perpendicular magnetic group (30) is magnetized by at least one having a vertical motion direction. The two magnetic members (31) are formed [for more than one of the embodiments shown in Figures 7 and 8], and the corresponding sense of the upper and lower ends of each of the second magnetic members (31) One end of the coil group (10) may be defined as a third magnetic pole (311) [ie, an N pole or an S pole], and one end different from the induction coil group (10) may be defined as a fourth magnetic pole (312) [ie, S Pole or N pole], in addition, the first and second magnetic members (21, 31) are of equal length and arranged in opposite directions, and the horizontal magnetic group (20) of the first magnetic member (21) of the first magnetic member (21) and The third magnetic pole (311) of the second magnetic member (31) of the perpendicular magnetic group (30) may be the same magnetic pole (the first and second embodiments of the power supply before the first drawing (A), (B)) or different The magnetic poles [the third and fourth embodiments of power supply after the second stage (A) and (B)]; wherein the switch group (40) is composed of a power supply switch (41) and a power-off switch (42). And two sensing elements (45, 46), as shown in Figure 1. The first and second embodiments of (A) and (B), wherein the sensing element (45, 46) can be disposed on the axis of the coil component (11) of the induction coil group (10) corresponding to the horizontal magnetic group (20) and The two ends of the magnetic group (30) are perpendicular to each other, and the power supply switch (41) of the switch group (40) is disposed on the first magnetic member (21) of the horizontal magnetic group (20) and is displaced into the induction coil group (10). a magnetic pole (211) end, and the power-off switch (42) is disposed at a central axis of the third magnetic pole (311) side of the second magnetic member (31) of the perpendicular magnetic group (30) for horizontal The magnetic group (20) moves closer to the coil member (11), and when the power feeding switch (41) on the first magnetic member (21) detects the relative sensing element (45) on the coil member (11), it can be connected to the power supply. The power supply and the coil (13) of the coil member (11) are energized to form a state in which the front section is energized, and when the horizontal magnetic group (20) enters the coil member (11), and when the second magnetic member (31) is in the center When the power-off switch (42) detects the relative sensing element (46) on the coil component (11), the power supply and the coil (11) coil (13) can be disconnected to form a power-off; Third and fourth embodiments of (A) and (B), wherein the sensing element (45, 4) 6) The axis of the coil member (11) disposed in the induction coil group (10) may correspond to both ends of the perpendicular magnetic group (30) and the horizontal magnetic group (20), and the power switch of the switch group (40) (41) ) is disposed on a central axis of the third magnetic pole (311) side of the second magnetic member (31) of the perpendicular magnetic group (30), and the power-off switch (42) is disposed at the horizontal magnetic group (20) A magnetic member (21) is displaced away from the end of the second magnetic pole (212) of the induction coil assembly (10) for moving the perpendicular magnetic group (30) into the coil member (11), and when the second magnetic member (31) The power supply switch (41) on the coil member (11) detects the relative sensing element (45) on the coil member (11), and can be connected to the coil (13) of the electric power source and the coil member (11) for power supply, and then the horizontal magnetic group. (20) leaving the coil member (11), and when the power-off switch (42) on the first magnetic member (21) is on the detection line When the relative sensing element (46) on the ring member (11) is disconnected, the connection between the power supply and the coil (13) coil (13) can be cut off to generate a power-off state, thereby forming a state in which the rear section is powered; An electric device that can eliminate the induced voltage and increase the magnetic assisted magnetic group relative to the magnetic pole.

As for the electric device of the present invention, the power supply in the previous stage is taken as an example, and the operation is as shown in Fig. 3 (A) to (C) and Fig. 4 (A) to (C), due to the horizontal magnetic group (20). The first magnetic member (21) magnetized in the moving direction is connected in series, and the perpendicular magnetic group (30) is composed of a second magnetic member (31) which is magnetized in a relative vertical direction. Therefore, in the first half (also called the electric zone), the magnetic flux is sharply reduced due to the conflict of magnetic lines, and the magnetic lines are compressed to form a magnetic beam parallel to the moving direction, that is, due to the horizontal magnetic group (20) and the perpendicular magnetic group ( 30) The sparse magnetic lines are compressed horizontally, so that the coils (13) of the coils (11) that are perpendicular to the induction coil group (10) are cut, and the induced voltage can be effectively eliminated, so that the horizontal magnetic group (20) The perpendicular magnetic group (30) can be driven by low input power to reduce energy consumption; and when the horizontal magnetic group (20) and the perpendicular magnetic group (30) are synchronized with respect to the induction coil group (10), and when the horizontal magnetic group ( 20) The power switch (41) of the switch group (40) on the first magnetic member (21) corresponds to the sensing element (45) on the coil member (11) of the induction coil group (10) [eg, the third, 4 (A), (B), the coil (13) of the coil member (11) can be electrically connected to the power supply to form a power supply condition, and the coil member (11) corresponds to the first magnetic One end of the member (21) is formed to have the same polarity as the first magnetic pole (211) for generating a repulsive thrust in the moving direction, and the coil member (11) corresponds to the perpendicular magnetic group (30) of the second magnetic member (31). The third magnetic pole (311) is of a different polarity for generating a phase pulling force in the moving direction, so that the moving horizontal magnetic group (20) and the perpendicular magnetic group (30) simultaneously obtain two magnetic assisting forces, so that The aforementioned elimination of induced voltage can greatly increase the output power and increase the energy conversion rate under low input power. And when the horizontal magnetic group (20) enters the coil member (11), and when the power-off switch (42) in the center of the second magnetic member (31) detects the relative sensing element (46) on the coil member (11) [Fig. 3, 4 (C)], the connection between the power supply and the coil (11) coil (13) can be cut off to form a power failure, otherwise the vertical magnetic component (30) of the perpendicular magnetic group (30) When the third magnetic pole (311) passes over the neutral line of the coil component (11) of the induction coil group (10), the coil (13) coil (13) of the induction coil group (10) continues to be electromagneticized, because the coil component (11) corresponds The third magnetic pole (311) of the second magnetic member (31) of the perpendicular magnetic group (30) exhibits different polarities, resulting in a reversal force different from the moving direction, forming a magnetic resistance, and since the power is turned off at this time, Therefore, this magnetic resistance is not generated, so that the horizontal magnetic group (20) and the perpendicular magnetic group (30) as the rotor can be inertially operated.

In addition, when the present electric device is actually used, the power supply in the later stage is taken as an example, and the action is as shown in Fig. 5 (A) to (C) and Fig. 6 (A) to (C), due to the horizontal magnetic group ( 20) The first magnetic member (21) magnetized in the moving direction is connected in series, and the perpendicular magnetic group (30) is a second magnetic member (31) which is magnetized in a relatively vertical direction. So that it is located in the second half (also called the electric zone), because the magnetic lines of the two collide, the magnetic flux is sharply reduced, and the magnetic lines of force are compressed to form a magnetic beam parallel to the moving direction, that is, due to the horizontal magnetic group (20) and the perpendicular magnetic group. (30) The sparse magnetic lines are compressed horizontally, so that the coils (13) of the coils (11) that are perpendicular to the induction coil group (10) are cut, and the induced voltage can be effectively eliminated, so that the horizontal magnetic group (20) Low input electric drive with perpendicular magnetic group (30) , reducing energy consumption; and when the horizontal magnetic group (20) and the perpendicular magnetic group (30) are synchronously moved relative to the induction coil group (10), and when the second magnetic member (31) of the perpendicular magnetic group (30) When the power supply switch (41) of the switch group (40) corresponds to the sensing element (45) on the coil member (11) of the induction coil group (10) [as shown in Figs. 5 and 6 (A), (B)], The coil (13) of the coil member (11) can be electrically connected to the power supply source to form a power supply condition, and the coil member (11) is formed at one end of the second magnetic member (31) and the third magnetic pole (311). The same polarity for generating the repulsive thrust in the direction of motion, and the coil member (11) corresponding to the horizontal magnetic group (20) of the first magnetic member (21) of the second magnetic pole (212) is of a different polarity for the generation of The suction force of the moving direction allows the moving horizontal magnetic group (20) and the perpendicular magnetic group (30) to obtain two magnetic assists simultaneously, so that the induced voltage can be eliminated in the foregoing, and the output can be greatly improved under low input power. Motivation to increase its energy conversion rate. In addition, when the horizontal magnetic group (20) is away from the coil member (11), and the power-off switch (42) of the second magnetic pole (212) of the first magnetic member (21) is in the opposite sensing element on the detecting coil member (11) (46) [If the 5th, 6th (C)], the connection between the power supply and the coil (11) coil (13) can be cut off to form a power failure, otherwise the horizontal magnetic group (20) is the first magnetic member ( When the second magnetic pole (212) of 21) crosses the neutral line of the coil component (11) of the induction coil group (10), such as the coil assembly (10) of the induction coil group (10), the coil (13) continues to be electromagnetized due to the coil component (11) Corresponding to the horizontal magnetic group (20), the second magnetic pole (212) of the first magnetic member (21) is in a different polarity, resulting in a reversal force different from the moving direction, forming a magnetic resistance, but since the power is off at this time Therefore, this magnetic resistance is not generated, so that the horizontal magnetic group (20) and the perpendicular magnetic group (30) as the rotor can be inertially operated.

In addition, as described above, the inventive induction coil set (10) can have two One or more coil members (11), and the horizontal magnetic group (20) and the perpendicular magnetic group (30) may have two or more first magnetic members (21) and second magnetic members ( 31) being connected in series, as shown in Figures 7 and 8, the horizontal magnetic group (20) is formed by connecting two or more first magnetic members (21) having magnetization in the moving direction. And the adjacent first magnetic members (21) are in the same polarity [ie, the S pole of the first first magnetic member corresponds to the S pole of the adjacent first magnetic member, and the N pole of the previous first magnetic member corresponds to Adjacent to the N pole of the first magnetic member, the perpendicular magnetic group (30) is formed by connecting two or more second magnetic members (31) magnetized in a vertical direction. And the third magnetic pole (311) of the adjacent second magnetic member (31) is a different magnetic pole [ie, the third magnetic pole of the second magnetic pole of the current second magnetic component is the third magnetic pole of the second magnetic component. And the third magnetic pole of the second magnetic pole of the current second magnetic component is the N pole of the second magnetic component, and the sensing of the switch group (40) is as shown in FIG. The components (45, 46) can be arranged in the induction coil group (10) The axis of the ring member (11) corresponds to both ends of the horizontal magnetic group (20) and the perpendicular magnetic group (30), and the power supply switch (41) of the switch group (40) is disposed at the first magnetic field of the horizontal magnetic group (20) The member (21) is displaced into the end of the first magnetic pole (211) of the induction coil group (10), and the power-off switch (42) is disposed in the second magnetic member (31) of the perpendicular magnetic group (30). The central axis of one side of the magnetic pole (311) forms a front section to supply power. Or as shown in FIG. 8, the sensing element (45, 46) may be disposed on the axis of the coil component (11) of the induction coil group (10) corresponding to the perpendicular magnetic group (30) and the horizontal magnetic group (20). The two ends of the switch, the power switch (41) of the switch group (40) is disposed on the central axis of the third magnetic pole (311) side of the second magnetic member (31) of the perpendicular magnetic group (30), and is powered off. The switch (42) is disposed at the end of the second magnetic pole (212) of the horizontal magnetic group (20) displaced from the first magnetic pole (212) of the induction coil assembly (10), and The rear section is formed to supply electricity.

Through the foregoing description, the electric device of the present magnetic group with respect to the magnetic pole eccentricity uses the horizontal magnetic group (20) to be connected in series by the first magnetic member (21) magnetized in the moving direction, and is perpendicular to the magnetic group ( 30) is composed of a second magnetic member (31) which is magnetized in a relative direction and in a vertical direction, so that the electric field (meaning the front portion of the first figure and the second stage of the second figure) is opposite to each other due to the magnetic field lines of the two, so that the magnetic flux Sharply reducing, and the magnetic lines of force compress each other to form a magnetic beam parallel to the moving direction, so that the magnetic lines are not cut relative to the coil (13) of the coil member (11) perpendicular to the induction coil group (10), and the induced voltage can be effectively eliminated to make the level The magnetic group (20) and the perpendicular magnetic group (30) can be driven by low input power to reduce energy consumption, and at the same time, the moving horizontal magnetic group (20) and the perpendicular magnetic group (30) can be simultaneously operated by the switch group (40). Obtaining two forward magnetic assists, which can produce high output power at low input power, can effectively improve the efficiency of energy conversion.

In this way, it can be understood that this creation is an excellent creation. In addition to effectively solving the problems faced by the practitioners, the effect is greatly enhanced, and the same or similar product creation or public use is not seen in the same technical field. At the same time, it has the effect of improving the efficiency. Therefore, this creation has met the requirements of "newness" and "progressiveness" of the new patent, and is applying for a new type of patent according to law.

Claims (4)

An electric device for eccentricity of a magnetic group relative to a magnetic pole, the electric device comprising an induction coil group, a horizontal magnetic group, a perpendicular magnetic group and a switch group, wherein the horizontal magnetic group and the perpendicular magnetic group are synchronous with each other Movement: The induction coil assembly has at least one coil member, and each coil member has a magnet extending in a vertical movement direction and at least one coil disposed on the magnetizer, and the coils are connected to an electric power source. The horizontal magnetic group is further composed of at least one first magnetic member having magnetization in a moving direction, and each of the first magnetic members is formed at one end of the front and rear ends of the first magnetic member adjacent to the induction coil group. a first magnetic pole, and a second magnetic pole is formed at one end of the corresponding moving direction away from the induction coil group; and the perpendicular magnetic group is composed of at least one second magnetic member magnetized with a vertical moving direction, and each One end of the corresponding upper and lower ends of the second magnetic member forms a third magnetic pole, and one end of the induction coil group forms a fourth magnetic pole, and the horizontal magnetic group The first magnetic member is equal in length and oppositely arranged with the second magnetic member of the perpendicular magnetic group, and is further opposite to the first magnetic pole of the first magnetic member of the horizontal magnetic group and the third magnetic pole of the second magnetic member of the perpendicular magnetic group The switch group is composed of a power switch, a power-off switch and two sensing elements, wherein the sensing elements can be respectively arranged on the axis of the coil component of the induction coil group. The first magnetic member disposed in the horizontal magnetic group is displaced into the first magnetic pole portion of the induction coil group, and the power-off switch is disposed in the second magnetic pole group. The central axis of the third magnetic pole side of the magnetic member forms a state in which the front section is energized. An electric device according to the first aspect of the invention, wherein the horizontal magnetic group of the electric device is connected in series by two or more first magnetic members having magnetization in a moving direction; And the adjacent first magnetic members are in the same polarity, and the perpendicular magnetic groups are formed by two or more second magnetic members having a vertical direction of magnetization, and adjacent ones The third magnetic pole of the two magnetic members is a distinct magnetic pole. An electric device for eccentricity of a magnetic group relative to a magnetic pole, the electric device comprising an induction coil group, a horizontal magnetic group, a perpendicular magnetic group and a switch group, wherein the horizontal magnetic group and the perpendicular magnetic group are synchronous with each other Movement: The induction coil assembly has at least one coil member, and each coil member has a magnet extending in a vertical movement direction and at least one coil disposed on the magnetizer, and the coils are connected to an electric power source. The horizontal magnetic group is further composed of at least one first magnetic member having magnetization in a moving direction, and each of the first magnetic members is formed at one end of the front and rear ends of the first magnetic member adjacent to the induction coil group. a first magnetic pole, and a second magnetic pole is formed at one end of the corresponding moving direction away from the induction coil group; and the perpendicular magnetic group is composed of at least one second magnetic member magnetized with a vertical moving direction, and each One end of the corresponding upper and lower ends of the second magnetic member forms a third magnetic pole, and one end of the induction coil group forms a fourth magnetic pole, and the horizontal magnetic group The first magnetic member is equal in length and oppositely arranged with the second magnetic member of the perpendicular magnetic group, and is further opposite to the first magnetic pole of the first magnetic member of the horizontal magnetic group and the third magnetic pole of the second magnetic member of the perpendicular magnetic group Is a different magnetic pole; The switch group is composed of a power supply switch, a power-off switch and two sensing elements, wherein the sensing elements can be respectively arranged on the axis of the coil component of the induction coil group corresponding to the perpendicular magnetic group and the horizontal magnetic group. The two ends are connected to the central axis of the third magnetic pole side of the second magnetic member of the perpendicular magnetic group, and the first magnetic member of the horizontal magnetic group is displaced from the induction coil group. The second pole end portion forms a state in which the rear section is energized. An electric device for eccentricity of a magnetic group relative to a magnetic pole according to claim 3, wherein the horizontal magnetic group of the electric device is connected in series by two or more first magnetic members having magnetization in a moving direction. And the adjacent first magnetic members are in the same polarity, and the perpendicular magnetic groups are formed by two or more second magnetic members having a vertical direction of magnetization, and adjacent to the second The third magnetic pole of the magnetic member is a distinct magnetic pole.