TWI678862B - Electric device with magnetic group opposite to magnetic pole - Google Patents

Abstract

The invention refers to an electric device with a magnetic group opposite to a magnetic pole. The induction device has an induction coil group, and a horizontal magnetic group and a perpendicular magnetic group can be arranged on both sides of the induction coil group. The horizontal magnetic group is composed of at least one first magnetic member having magnetization in the direction of movement, and the perpendicular magnetic group is composed of at least one second magnetic member having magnetization direction and the direction of movement. The first and second magnetic pieces are arranged in a relative arrangement, and a switch group for selectively electrifying the coil is provided 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 generate dual magnetic assistance during power transmission to increase the output kinetic energy and achieve the purpose of greatly improving the energy conversion rate.

Description

Electric device with magnetic group opposite to magnetic pole

The invention belongs to the field of electromagnetic technology for energy conversion, and specifically refers to an electric device capable of eliminating induced voltage and increasing the total magnetic assistance of the magnetic group relative to the magnetic pole, so as to achieve the effect of micro-electric start-up and effectively utilize it. At the same time, it can increase magnetic power and increase output power, thereby improving its energy conversion efficiency.

In general, the structure of a general electric motor is composed of a stator and a rotor that can move relative to each other. Among them, a plurality of coils are provided on the inner edge of the stator, and a plurality of corresponding coils are provided on the outer edge of the rotor. The intermittent power supply causes the coil to be magnetized, and generates magnetic forces that repel and attract the magnetic parts of the rotor, thereby driving the rotor to rotate at high speed.

When the motor is in operation, it uses intermittent power supply and captures the required magnetic force to drive the rotor. However, due to the configuration of its coil and magnetic parts, the coil will still be subject to inertia at the moment of power suspension. The influence of the magnetic line cutting of the magnetic part in the medium will generate the induced electromotive force and form an internal voltage. Therefore, the general motor requires a large input power and wastes unnecessary energy. It is also affected by the magnetic attraction effect, which increases the magnetic resistance between the rotor and the stator, which is not conducive to movement, slows down the overall operating rate, resulting in poor output power and low energy conversion efficiency.

In other words, if the induced voltage before power feeding can be effectively eliminated, and the magnetic assist force during power feeding can be increased, the effect of low energy consumption and high output will be produced, and if How to achieve this goal is the industry's desperate developers.

In view of this, the inventor has in-depth discussion on the problems encountered in the application of the aforementioned existing electric devices, and through years of research and development experience in related industries, actively seeks a solution. After continuous research and trial work, he finally succeeds Has developed an electric device with a magnetic group opposite to the magnetic pole, to overcome the inconvenience and distress caused by the existing ones due to the large induced voltage and large accretive magnetic resistance.

Therefore, the main object of the present invention is to provide an electric device whose magnetic group is opposite to the magnetic pole. By eliminating the induced voltage, it can reduce the input power and further improve its energy conversion efficiency.

In addition, the main object of the present invention is to provide an electric device with a magnetic group opposite to a magnetic pole, which can reduce the loss of kinetic energy, increase forward magnetic assistance, effectively increase the operating speed, and further increase its output power.

Based on this, the present invention mainly achieves the foregoing objectives and its effects through the following technical means. The electric device includes an induction coil group, a horizontal magnetic group, a vertical alternating magnetic group, and a switch group, of which the horizontal magnetic group And the perpendicular magnetic group can move relative to the induction coil group synchronously: the induction coil group has at least one coil piece, and each of the coil pieces has a magnet guide extending in a vertical direction of movement and at least one ring arranged on the magnet guide; The horizontal magnetic group is composed of at least one first magnetic member magnetized in a moving direction, and each of the first magnetic members is horizontally front and rear ends. A first magnetic pole is formed at an end of the corresponding movement direction near the induction coil group, and a second magnetic pole is formed at an end of the corresponding movement direction away from the induction coil group; In another aspect, the perpendicular magnetic group is composed of at least one second magnetic member with magnetization in a vertical direction of movement, and one end of each of the second magnetic members corresponding to the induction coil group forms a third A fourth magnetic pole is formed at one end of the magnetic pole, which is different from the induction coil group. Furthermore, the first magnetic member of the horizontal magnetic group and the second magnetic member of the perpendicular magnetic group are of equal length and are arranged opposite to each other. The first magnetic pole of the first magnetic piece of the group and the third magnetic pole of the second magnetic piece of the perpendicular magnetic group are the same magnetic pole; as for the switch group, it is composed of a power-on switch, a power-off switch and two induction elements. Structure, where the induction elements can be located at the ends of the coils of the induction coil group corresponding to the two ends of the horizontal magnetic group and the perpendicular magnetic group, and the first magnetic member set in the horizontal magnetic group is shifted into the induction coil. The first magnetic extreme part of the group, and the power-off switch is set on the central axis of the third magnetic pole side of the second magnetic piece of the perpendicular magnetic group, so as to form a state of front-end power supply.

Thus, the electric device of the magnetic group of the present invention with relative magnetic poles is realized through the foregoing technical means. It can use the horizontal magnetic group to magnetize in the moving direction, and the perpendicular magnetic group to magnetize in the relative vertical moving direction, so that The magnetic lines of force of the two are relatively compressed to form a magnetic beam parallel to the direction of movement, so that the magnetic lines of force do not cause cutting, but can eliminate the induced voltage, so that they can be driven by low power input, effectively use energy, and open and close through the switch group. It can obtain comprehensive magnetic assistance at the same time, enabling high output power under low input power, which can effectively improve the efficiency of its energy conversion, so it can greatly increase its added value and improve its economic benefits.

In order to make your reviewers better understand the composition, features, and other purposes of the present invention, the following is a description of the preferred embodiments of the present invention, which will be described in detail with reference to the drawings, and will be implemented by those familiar with the technical field.

(10) ‧‧‧Induction coil group

(11) ‧‧‧Coil parts

(12) ‧‧‧Magnetic guide

(13) ‧‧‧Coil

(20) ‧‧‧Horizontal Magnetic Group

(21) ‧‧‧The first magnetic piece

(211) ‧‧‧First magnetic pole

(212) ‧‧‧Second magnetic pole

(30) ‧‧‧Vertical Magnetic Group

(31) ‧‧‧Second magnetic part

(311) ‧‧‧Third magnetic pole

(312) ‧‧‧Fourth magnetic pole

(40) ‧‧‧Switch group

(41) ‧‧‧Power switch

(42) ‧‧‧Power Off Switch

(45) ‧‧‧Sensor

(46) ‧‧‧Sensor

FIG. 1 (A) is a schematic structural diagram of the first embodiment of the electric device of the magnetic group relative to the magnetic poles of the present invention, for explaining the state of the power supply terminal in front of the magnetic group.

FIG. 1 (B) is a schematic structural diagram of the second embodiment of the electric device of the magnetic group with respect to the magnetic poles of the present invention, for explaining the state of the other power supply terminal in front of the magnetic group.

FIG. 2 (A) is a schematic structural diagram of the third embodiment of the electric device of the magnetic group with respect to the magnetic poles of the present invention, for explaining the state of the power supply terminal at the back of the magnetic group.

FIG. 2 (B) is a schematic structural diagram of the fourth embodiment of the electric device of the magnetic group of the present invention in which the magnetic poles are different from each other, for illustrating the state of the other power supply terminal at the rear stage of the magnetic group.

Figures 3 (A) ~ (C) are schematic diagrams of the operation of the first embodiment of the present invention in the previous stage.

Figures 4 (A) ~ (C) are schematic diagrams of the operation of the second embodiment of the present invention in the previous stage of power supply.

Figures 5 (A) ~ (C) are schematic diagrams of the operation of the third embodiment of the present invention in the latter stage.

Figures 6 (A) ~ (C) are schematic diagrams of the power supply operation in the fourth embodiment of the present invention.

FIG. 7 is a schematic structural diagram of a fifth embodiment of an electric device with a magnetic group opposite to a magnetic pole of the present invention, for explaining two horizontal magnetic groups and perpendicular magnetic groups or Two or more are connected in series to the previous stage power supply state.

FIG. 8 is a schematic structural diagram of a sixth embodiment of an electric device with a magnetic pole opposite to a magnetic pole according to the present invention, for explaining a state of power supply after two or more horizontal magnetic groups and perpendicular magnetic groups are connected in series.

The present invention is an electric device with a magnetic group opposite to a magnetic pole, and the attached drawings illustrate the specific embodiments of the present invention and its components, all of which are front and rear, left and right, top and bottom, upper and lower, and horizontal. The reference to vertical is for convenience of description only, and does not limit the invention, nor limit its components to any position or spatial direction. The dimensions specified in the drawings and the description can be changed according to the design and requirements of the specific embodiments of the present invention without departing from the scope of the patent application of the present invention.

The structure of the electric device of the magnetic group relative to the magnetic pole of the present invention is shown in Figs. 1 and 2. The electric device has an induction coil group (10), and is divided 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 moving direction, and the horizontal magnetic group (20) and the perpendicular magnetic group (30) can be synchronously opposed to the induction coil. Group (10) moves, and there is a switch group (40) between the induction coil group (10), the horizontal magnetic group (20), and the perpendicular magnetic group (30), and the switch group (40) can be operated Whether to selectively electrify the induction coil group (10); and for the detailed structure of the first embodiment of the electric device of the magnetic group of the present invention in which the magnetic poles are different from each other, please refer to those disclosed in Figures 1 (A) and (B). The induction coil group (10) can be defined as a stator, and the induction coil group (10) is composed of one or more coil parts (11) [for more than one, please refer to Section 7 The embodiment shown in FIGS. 8 and 8], and each of the coil parts (11) is formed by a conductive magnet (12) extending in a vertical movement direction and at least one coil (13) looped around the conductive magnet (12), The coils (13) are connected to an electric power source, and when the electric power is supplied to the coil (13), the coil parts (11) can be magnetized, and the horizontal magnetic group (20) and the perpendicular magnetic group (30) as the rotor are synchronously driven. ); And the horizontal magnetic group (20) is formed by serially connecting at least one first magnetic member (21) magnetized in a moving direction [more than one please refer to the embodiments shown in FIGS. 7 and 8], And the end of the first magnetic piece (21) horizontally corresponding to the direction of movement near the induction coil group (10) can be defined as the first magnetic pole (211) [ie, N pole or S pole], and corresponding movement The end far from the induction coil group (10) can be defined as the second magnetic pole (212) [that is, S pole or N pole]; and the perpendicular magnetic group (30) is magnetized by at least one first The two magnetic pieces (31) are composed of one or more [please refer to the embodiments shown in Figs. 7 and 8], and each of the second magnetic pieces (31) has a corresponding sense in the upper and lower ends. One end of the coil group (10) can be defined as the third magnetic pole (311) [ie, N pole or S pole], and one end different from the induction coil group (10) can be defined as the fourth magnetic pole (312) [ie S Pole or N pole], and the first and second magnetic pieces (21, 31) are of equal length and oppositely arranged, and the first magnetic pole (211) of the first magnetic piece (21) of the horizontal magnetic group (20) and The third magnetic pole (311) of the second magnetic member (31) of the perpendicular magnetic group (30) may be the same magnetic pole [such as the first and second embodiments of the first paragraph (A) and (B) of the first figure]) or different Magnetic poles [such as the third and fourth embodiments of the second section of Figures (A), (B) after power supply]; as for the switch group (40) is a power switch (41), a power switch (42) ) And two sensing elements (45, 46), as shown in Figure 1 The first and second embodiments of (A) and (B), wherein the inductive element (45, 46) may be a coil component (11) axis of the induction coil group (10) corresponding to the horizontal magnetic group (20) and The two ends of the perpendicular magnetic group (30), and the power supply switch (41) of the switch group (40) are located on the first magnetic piece (21) of the horizontal magnetic group (20) and are displaced into the first of the induction coil group (10). An end of a magnetic pole (211), and a power-off switch (42) is provided on the central axis of the third magnetic pole (311) side of the second magnetic piece (31) of the perpendicular magnetic group (30), and is used as a horizontal The magnetic group (20) is moved close to the coil component (11), and when the power supply switch (41) on the first magnetic component (21) detects the relative induction element (45) on the coil component (11), it can communicate with the power supply. The power supply and the coil (13) of the coil component (11) are powered to form a state of previous power supply. When the horizontal magnetic group (20) enters the coil component (11), and when the second magnetic component (31) is in the center, When the power-off switch (42) detects the relative induction element (46) on the coil component (11), it can cut off the connection between the power supply and the coil component (11) and the coil (13) to form a power failure; The third and fourth embodiments of Figures (A) and (B), wherein the sensing element (45, 4 6) The axis of the coil component (11) provided 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 (41) of the switch group (40) ) Is located on the central axis of the third magnetic pole (311) of the second magnetic piece (31) of the perpendicular magnetic group (30), and the power-off switch (42) is located on the second magnetic piece (31) of the horizontal magnetic group (20). A magnetic piece (21) is displaced away from the end of the second magnetic pole (212) of the induction coil group (10), and is used to move the perpendicular magnetic set (30) into the coil piece (11), and when the second magnetic piece (31) When detecting the relative induction element (45) on the coil component (11), the power supply switch (41) on) can communicate with the power supply and the coil (13) of the coil component (11) for power supply. (20) Leave the coil component (11), and when the power-off switch (42) on the first magnetic component (21) is on the detection line When the relative induction element (46) on the ring piece (11) can cut off the connection between the power supply source and the coil piece (11) and the coil (13) to cause a power failure, a state of rear-stage power supply is formed; thereby, the group constitutes a An electric device that can eliminate induced voltage and increase the magnetic assist of the magnetic group relative to the magnetic pole.

As for the electric device of the present invention, in the actual use, the previous stage power supply is taken as an example. Its operation is as shown in Figs. 3 (A) ~ (C) and 4 (A) ~ (C). As the horizontal magnetic group (20 ) Is composed of a series of first magnetic pieces (21) magnetized in the direction of movement, and a perpendicular magnetic group (30) is formed of second magnetic pieces (31) that are oppositely and magnetized in the direction of vertical movement. Therefore, in the first half (also known as the electric area), due to the conflict of the magnetic field lines of the two, the magnetic flux is sharply reduced, and the magnetic field lines are compressed to form a magnetic beam parallel to the direction of movement, that is, the horizontal magnetic group (20) and the perpendicular magnetic group ( 30) The sparse magnetic lines of force are compressed horizontally, so that it does not cause cutting of the coils (11) and coils (13) that are perpendicular to the induction coil group (10), and can effectively eliminate the induced voltage, so that the horizontal magnetic group (20) and The perpendicular magnetic group (30) can be driven with low input power to reduce energy consumption; and when the horizontal magnetic group (20) and the perpendicular magnetic group (30) move synchronously to the induction coil group (10), and when the horizontal magnetic group (10) 20) When the power switch (41) of the switch group (40) on the first magnetic part (21) corresponds to the induction element (45) on the coil part (11) of the induction coil group (10) [such as the third, As shown in (A) and (B) of FIG. 4], the coil (13) of the coil component (11) and the power supply can be made conductive to form a power supply condition, and the coil component (11) corresponds to the first magnetic property. One end of the piece (21) is formed with the same polarity as the first magnetic pole (211) for generating repulsive thrust in the direction of movement, and the coil piece (11) corresponds to the second magnetic piece (31) of the perpendicular magnetic group (30). The third magnetic pole (311) of the second magnetic pole is of a different polarity, and is used to generate a pulling force in the direction of movement, so that the moving horizontal magnetic group (20) and the perpendicular magnetic group (30) can simultaneously obtain two magnetic assist forces. The aforementioned elimination of the induced voltage can greatly increase the output power and the energy conversion rate at a low input power. When the horizontal magnetic group (20) enters the coil component (11), and when the power-off switch (42) in the center of the second magnetic component (31) detects the relative induction element (46) on the coil component (11), [As shown in Figures 3 and 4 (C)], it can cut off the connection between the power supply and the coil (11) and the coil (13) to form a power failure. Otherwise, when the perpendicular magnetic group (30) is the second magnetic piece (31) When the third magnetic pole (311) crosses the center line of the coil coil (11) of the induction coil group (10), for example, the coil coil (13) of the coil coil (11) of the induction coil group (10) continues to be magnetized because the coil element (11) corresponds to The third magnetic pole (311) of the second magnetic piece (31) of the perpendicular magnetic group (30) is of a different polarity, resulting in the generation of a reverse tensile force different from the direction of movement, forming a kind of magnetic resistance, but because 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 perform inertia operation.

In addition, when the electric device of the present invention is used in practice, the power is supplied in the latter stage as an example. Its operation is as shown in Figures 5 (A) ~ (C) and Figures 6 (A) ~ (C). 20) It is formed by cascading the first magnetic pieces (21) magnetized in the moving direction, and the perpendicular magnetic group (30) is made by the second magnetic pieces (31) that are opposite and magnetized in the vertical moving direction. Structure, so it is located in the second half (also known as the electric zone) due to the conflict of the magnetic lines of force between the two, which sharply reduces the magnetic flux, and the magnetic lines of force compress each other to form a magnetic beam parallel to the direction of movement. (30) The sparse magnetic lines of force are compressed horizontally, so that it does not cause cutting of the coil pieces (11) coils (13) that are perpendicular to the induction coil group (10), and can effectively eliminate the induced voltage, making the horizontal magnetic group (20) It can be driven by low input electric power with perpendicular magnetic group (30) , Reducing energy consumption; and when the horizontal magnetic group (20) and the perpendicular magnetic group (30) move relative to the induction coil group (10), and when the second magnetic piece (31) of the perpendicular magnetic group (30) When the power supply switch (41) of the switch group (40) corresponds to the induction element (45) on the coil component (11) of the induction coil group (10) [as shown in (A) and (B) of Figures 5 and 6], The coil (13) of the coil component (11) and the power supply source can be made conductive to form a power supply condition, and one end of the coil component (11) corresponding to the second magnetic component (31) and the third magnetic pole (311) can be formed. It has the same polarity for generating repulsive thrust along the direction of movement, and makes the second magnetic pole (212) of the coil component (11) corresponding to the first magnetic piece (21) of the horizontal magnetic group (20) have a different polarity for generating edge The phase attracts the pulling force in the moving direction, so that the moving horizontal magnetic group (20) and the perpendicular magnetic group (30) can obtain two magnetic assists at the same time, so that it can eliminate the induced voltage in the foregoing, and can greatly improve the output at low input power. Power to increase its energy conversion rate. In addition, when the horizontal magnetic group (20) is far from the coil component (11), and when the power-off switch (42) of the first magnetic component (21) and the second magnetic pole (212) detects the relative induction element on the coil component (11) (46) [as shown in Figures 5 and 6 (C)], the power supply can be cut off from the connection between the coil (11) and the coil (13) to form a power failure. Otherwise, when the horizontal magnetic group (20) is the first magnetic component ( When the second magnetic pole (212) of 21) crosses the center line of the coil component (11) of the induction coil group (10), for example, the coil (13) of the coil component (11) of the induction coil group (10) continues to be electromagnetic, because the coil component (11 ) The second magnetic pole (212) corresponding to the first magnetic piece (21) of the horizontal magnetic group (20) is of a different polarity, resulting in the generation of a reverse tensile force different from the direction of movement, forming a kind of magnetic resistance, but because 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 perform inertia operation.

As mentioned above, the induction coil group (10) of the present invention may have two Two or more coil components (11), and the horizontal magnetic group (20) and the perpendicular magnetic group (30) may have two or more first magnetic components (21) and second magnetic components ( 31) serially connected, as shown in Figs. 7 and 8, the horizontal magnetic group (20) is formed by serially connecting two or more first magnetic members (21) having magnetization in a moving direction, And the adjacent first magnetic pieces (21) are in the same polarity opposite [that is, the S pole of the first first magnetic piece corresponds to the S pole of the adjacent next first magnetic piece, and the N pole of the previous first magnetic piece corresponds to The N pole of the adjacent first magnetic piece], and the perpendicular magnetic group (30) is formed by cascading two or more second magnetic pieces (31) with magnetization in the vertical direction, And the third magnetic pole (311) of the adjacent second magnetic piece (31) is a different magnetic pole [that is, when the third magnetic pole of the current second magnetic piece is S pole, the third magnetic pole of the second second magnetic piece is N Pole, and when the third magnetic pole of the current second magnetic piece is N pole, the third magnetic pole of the latter second magnetic piece is S pole], and as shown in FIG. 7, the induction of the switch group (40) The components (45, 46) can be arranged in the induction coil group (10). The axis of the ring piece (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 set to the first magnetic of the horizontal magnetic group (20) The piece (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 provided in the third of the second magnetic piece (31) of the perpendicular magnetic group (30). The central axis on one side of the magnetic pole (311) forms the front section power supply. Or as shown in FIG. 8, the inductive element (45, 46) may be arranged on the axis of the coil component (11) of the inductive coil group (10) corresponding to the perpendicular magnetic group (30) and the horizontal magnetic group (20). The power supply switch (41) of the switch group (40) is located on the central axis of the third magnetic pole (311) side of the second magnetic piece (31) of the perpendicular magnetic group (30), and the power is turned off. The switch (42) is disposed on the horizontal magnetic group (20), and the first magnetic piece (21) is displaced away from the end of the second magnetic pole (212) of the induction coil group (10), and Form the back section to supply electricity.

Through the foregoing description, the electric device of the magnetic group of the present invention with a different magnetic pole position uses a horizontal magnetic group (20) which is a series connection of a first magnetic member (21) magnetized in a moving direction, and a perpendicular magnetic group ( 30) It is composed of a second magnetic piece (31) that is opposite and magnetized in the vertical direction of movement, so that the electric area (meaning the first part of the first picture and the second part of the second picture) is opposite due to the conflict of the magnetic lines of force, so that the magnetic flux Sharply reduced, and the magnetic lines of force compress each other to form a magnetic beam parallel to the direction of movement, so that the magnetic lines of force do not cause cutting of the coils (11) and the coils (13) perpendicular to the induction coil group (10), which can effectively eliminate the induced voltage and make the horizontal The magnetic group (20) and the perpendicular magnetic group (30) can be driven with low input power to reduce energy consumption. At the same time, the horizontal magnetic group (20) and the perpendicular magnetic group (30) can be moved at the same time through the action of the switch group (40). Obtain two forward magnetic assistances, and can produce high output power with low input power, which can effectively improve the efficiency of energy conversion.

In this way, it can be understood that the present invention is an excellent creative creation. In addition to effectively solving the problems faced by practitioners, it has greatly improved the efficacy, and has not seen the same or similar product creation or public use in the same technical field. At the same time, it has the improvement of efficacy. Therefore, the present invention has already met the requirements of "newness" and "progressiveness" of the invention patent, and has applied for an invention patent in accordance with the law.

Claims (4)

An electric device with a magnetic group opposite to a magnetic pole. The electric device includes an induction coil group, a horizontal magnetic group, a perpendicular magnetic group, and a switch group. The horizontal magnetic group and the perpendicular magnetic group can be synchronously opposed to the induction coil group. Movement: The said induction coil group has at least one coil component, and each of the coil components is composed of a conductive magnet extending in a vertical movement direction and at least one coil provided around the conductive magnet, and these coils are connected to an electric power source. The horizontal magnetic group is also composed of at least one first magnetic member magnetized in the direction of movement, and each of the first magnetic members is formed near one end of the induction coil group corresponding to the direction of movement of the first magnetic member and the second magnetic member horizontally. A first magnetic pole, and a second magnetic pole formed at an end corresponding to a moving direction away from the induction coil group; the perpendicular magnetic group is further composed of at least one second magnetic member having magnetization in a vertical moving direction, and each A third magnetic pole is formed on one end of the second magnetic member corresponding to the induction coil group, and a fourth magnetic pole is formed on one end different from the induction coil group. The first magnetic piece and the second magnetic piece of the perpendicular magnetic group are of equal length and oppositely arranged, and the first magnetic pole of the first magnetic piece of the horizontal magnetic group and the third magnetic pole of the second magnetic piece of the perpendicular magnetic group are opposite to each other. They have the same magnetic poles. As for the switch group, it consists of a power switch, a power-off switch and two induction elements, where the induction elements can be arranged on the coils of the induction coil group corresponding to the horizontal magnetic axis The first magnetic part of the horizontal magnetic group is shifted into the first magnetic extreme part of the induction coil group, and the power-off switch is located at the second of the vertical magnetic group. The central axis of the third magnetic pole side of the magnetic piece forms a state of front-end power supply. The electric device with a magnetic group opposite to the magnetic pole as described in item 1 of the scope of the patent application, wherein the horizontal magnetic group of the electric device is connected in series by two or more first magnetic members having magnetization in the moving direction. And the adjacent first magnetic pieces are opposite to the same pole, and the perpendicular magnetic group is formed by concatenating two or more second magnetic pieces with magnetization in the vertical direction, and the adjacent first magnetic pieces are connected in series. The third magnetic poles of the two magnetic pieces are different magnetic poles. An electric device with a magnetic group opposite to a magnetic pole. The electric device includes an induction coil group, a horizontal magnetic group, a perpendicular magnetic group, and a switch group. The horizontal magnetic group and the perpendicular magnetic group can be synchronously opposed to the induction coil group. Movement: The said induction coil group has at least one coil component, and each of the coil components is composed of a conductive magnet extending in a vertical movement direction and at least one coil provided around the conductive magnet, and these coils are connected to an electric power source. The horizontal magnetic group is also composed of at least one first magnetic member magnetized in the direction of movement, and each of the first magnetic members is formed near one end of the induction coil group corresponding to the direction of movement of the first magnetic member and the second magnetic member horizontally. A first magnetic pole, and a second magnetic pole formed at an end corresponding to a moving direction away from the induction coil group; the perpendicular magnetic group is further composed of at least one second magnetic member having magnetization in a vertical moving direction, and each A third magnetic pole is formed on one end of the second magnetic member corresponding to the induction coil group, and a fourth magnetic pole is formed on one end different from the induction coil group. The first magnetic piece and the second magnetic piece of the perpendicular magnetic group are of equal length and oppositely arranged, and the first magnetic pole of the first magnetic piece of the horizontal magnetic group and the third magnetic pole of the second magnetic piece of the perpendicular magnetic group are opposite to each other. The magnetic poles are different. As for the switch group, it consists of a power switch, a power-off switch and two induction elements, where the induction elements can be arranged on the axis of the coils of the induction coil group corresponding to the vertical The two ends of the alternating magnetic group and the horizontal magnetic group, the power-on relationship is set on the central axis of the third magnetic pole side of the second magnetic piece of the perpendicular magnetic group, and the power-off open relationship is set on the first magnetic group of the horizontal magnetic group. The element moves away from the second magnetic pole of the induction coil group, and forms a state of rear-stage power supply. As described in item 3 of the scope of the patent application, an electric device with a magnetic group opposite to a magnetic pole is located, 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 pieces are opposite to the same pole, and the perpendicular magnetic group is formed by concatenating two or more second magnetic pieces with magnetization in the vertical direction, and the adjacent second magnetic pieces The third magnetic pole of the magnetic piece is a different magnetic pole.