WO2018205216A1 - Electric actuator having magnetic groups misaligned relative to magnetic pole - Google Patents

Abstract

An electric actuator having magnetic groups misaligned relative to a magnetic pole. The electric actuator comprises an induction coil group (10), and a horizontal magnetic group (20) and a vertical magnetic group (30) which may synchronously move relative to each other are respectively disposed at two sides of the induction coil group; the horizontal magnetic group consists of at least one first magnetic member (21) magnetized along a moving direction, and the vertical magnetic group consists of at least one second magnetic member (31) having a magnetizing direction vertical to the moving direction; the first magnetic member and the second magnetic member are arranged opposite to each other; a switch group (40) is disposed between the induction coil group and the horizontal magnetic group, and between the induction coil group and the vertical magnetic group for selectively supplying power to the coils. In virtue of the above, an induced voltage can be eliminated when no power is supplied, the electric actuator is driven by lower power, and magnetic aid can be generated during power transmission driving, so that output kinetic energy is enhanced, and the purpose of significantly improving the energy conversion rate is achieved.

Description

Electric device with magnetic group eccentricity Technical field

The invention relates to the field of electromagnetic technology for energy conversion, in particular to an electric device capable of eliminating the induced voltage and increasing the relative magnetic pole eccentricity of the magnetic group, so that the micro-electricity starting effect can be achieved to effectively By making good use of energy, it can enhance magnetic power and increase output power, thus improving its energy conversion efficiency.

Background technique

Generally, the structure of the motor is composed of a stator and a rotor which are relatively rotatable, wherein a plurality of coils are provided as inner edges of the stator, and a plurality of magnetic members corresponding to the coils are provided as outer edges of the rotor. 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 the moment of suspending the power supply. In the inertia, the influence of the magnetic line cutting of the magnetic component generates an induced electromotive force to form an intrinsic voltage, so that the input demand of the electric motor is generally 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 the induced voltage before power-on and the magnetic boosting force during power-on can be effectively eliminated, the effect of low energy consumption and high output can be produced, and how to achieve this goal is urgently needed for development in the industry.

In view of this, the present inventors have intensively discussed the problems faced by the aforementioned existing electric devices, and actively pursued solutions through years of research and development experience in related industries, and have been continuously researching and trialing, and finally The invention has been successfully developed to overcome the inconvenience and trouble caused by the large induced voltage and the large magnetic reluctance of the existing one.

Summary of the invention

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

It is still another object of the present invention to provide an electric device in which a magnetic group is eccentrically opposed to a magnetic pole, which can reduce kinetic energy loss, increase forward magnetic assistance, effectively increase operating speed, and further increase its output power.

Based on this, the present invention mainly adopts the following technical means to achieve the above object.

An electric device with a magnetic group eccentrically opposite 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 relative to the induction coil Group movement: the induction coil set has at least one coil member, and each coil member has a magnetizer extending in a vertical movement direction and at least one coil disposed on the magnetizer, the coil is connected and powered The horizontal magnetic group is composed of at least one first magnetic member having magnetization in a moving direction, and the first and second ends of the first magnetic member are horizontally adjacent to the end of the induction coil group to form a first a 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 of the second magnetic members is erected One end of the corresponding induction coil group in the upper and lower ends forms a third magnetic pole, and one end different from the induction coil group forms a fourth magnetic pole, and the first magnetic member of the horizontal magnetic group and the perpendicular magnetic field The second magnetic members are of equal length and are oppositely arranged, and the first magnetic poles of the first magnetic group of the opposite horizontal magnetic group and the third magnetic pole of the second magnetic member of the perpendicular magnetic group have the same magnetic pole; The switch group is composed of a power supply switch, a power-off switch and first and second sensing elements. The first and second sensing elements can be respectively disposed on the axis of the coil component of the induction coil group corresponding to the horizontal magnetic group and the two ends of the perpendicular magnetic group. And the first magnetic member of the power switch 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 on the third magnetic pole side of the second magnetic member of the perpendicular magnetic group The central axis forms a state in which the front section is powered.

The horizontal magnetic group of the electric device is formed by two or more first magnetic members having magnetization in the moving direction, and the adjacent first magnetic members are opposite poles, and the perpendicular magnetic group is composed of two Two or more second magnetic members having a vertical direction of magnetization are connected in series, and the third magnetic poles of the adjacent second magnetic members are different magnetic poles.

An electric device with a magnetic group eccentrically opposite 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 relative to the induction coil Group movement: the induction coil set has at least one coil member, and each coil member has a magnetizer extending in a vertical movement direction and at least one coil disposed on the magnetizer, the coil is connected and powered The horizontal magnetic group is composed of at least one first magnetic member having magnetization in a moving direction, and the first and second ends of the first magnetic member are horizontally adjacent to the end of the induction coil group to form a first a 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 of the second magnetic members is erected One end of the corresponding induction coil group in the upper and lower ends forms a third magnetic pole, and one end different from the induction coil group forms a fourth magnetic pole, and the first magnetic member of the horizontal magnetic group and the perpendicular magnetic field The second magnetic members are of equal length and arranged opposite each other, and the first magnetic poles 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 have different magnetic poles; The switch group is composed of a power supply switch, a power-off switch and first and second sensing elements. The first and second sensing elements can be respectively arranged on the axis of the coil component of the induction coil group corresponding to the two of the perpendicular magnetic group and the horizontal magnetic group. And the power switch is disposed on a central axis of the third magnetic pole side of the second magnetic component of the perpendicular magnetic group, and the first magnetic member of the power interruption switch disposed in the horizontal magnetic group is displaced from the second magnetic pole of the induction coil group The extreme part forms a state in which the rear section is powered.

The horizontal magnetic group of the electric device is formed by two or more first magnetic members having magnetization in the moving direction, and the adjacent first magnetic members are opposite poles, and the perpendicular magnetic group is composed of two Two or more second magnetic members having a vertical direction of magnetization are connected in series, and the third magnetic poles of the adjacent second magnetic members are different magnetic poles.

Thereby, the electric device with the magnetic pole eccentricity of the magnetic group of the present invention can be magnetized by the horizontal magnetic group in the moving direction by using the above technical means, and the perpendicular magnetic group is magnetized in the relative vertical moving direction to make the magnetic lines of force of the two. Relative compression forms a magnetic beam parallel to the direction of motion, so that the magnetic lines of force do not cause cutting, but can eliminate the induced voltage, so that it can be driven by low power input, effectively use energy, and at the same time, can be comprehensively obtained through the opening and closing of the switch group. Magnetic assist enables high output power at low input power, which can effectively improve the efficiency of energy conversion, so it can greatly increase its added value and improve its economic efficiency.

DRAWINGS

1 is a schematic structural view of a first embodiment of an electric device in which a magnetic group is eccentrically opposed to a magnetic pole according to the present invention, for explaining a state in which the electric terminal is in a front portion of the magnetic group.

2 is a schematic structural view of a second embodiment of the electric device with respect to the magnetic pole eccentricity of the magnetic group according to the present invention, for explaining the state of the other power supply end in the front portion of the magnetic group.

3 is a schematic structural view of a third embodiment of the electric device with respect to the magnetic pole eccentricity of the magnetic group according to the present invention, for explaining the state of the electric terminal in the rear stage of the magnetic group.

4 is a schematic structural view of a fourth embodiment of an electric device with respect to a magnetic pole eccentricity according to the present invention, for explaining the state of another power supply end in the rear stage of the magnetic group.

5, FIG. 6, and FIG. 7 are schematic diagrams showing the operation of power supply in the front stage according to the first embodiment of the present invention.

FIG. 8, FIG. 9, and FIG. 10 are schematic diagrams showing the operation of power supply in the front stage according to the second embodiment of the present invention.

11, FIG. 12 and FIG. 13 are schematic diagrams showing the operation of power supply in the rear stage according to the third embodiment of the present invention.

FIG. 14, FIG. 15, and FIG. 16 are schematic diagrams showing the operation of powering in the rear stage according to the fourth embodiment of the present invention.

FIG. 17 is a schematic structural view of a fifth embodiment of an electric device with a magnetic pole eccentricity relative to a magnetic pole according to the present invention, for explaining a power supply state of a front section of two or more serial strings of a horizontal magnetic group and a perpendicular magnetic group.

FIG. 18 is a schematic structural view of a sixth embodiment of an electric device with a magnetic pole eccentricity according to the present invention, for explaining a power supply state of two or more serially connected horizontal magnetic groups and perpendicular magnetic groups.

【Symbol Description】

10 induction coil set 11 coil parts

12-conductor magnet 13 coil

20 horizontal magnetic group 21 first magnetic member

211 first magnetic pole 212 second magnetic pole

30 perpendicular magnetic group 31 second magnetic member

311 third magnetic pole 312 fourth magnetic pole

40 switch group 41 power switch

42 power off switch 45 first sensing element

46 second sensing element.

detailed description

The following detailed description of the preferred embodiments of the present invention,

The present invention is an electric device in which a magnetic group is eccentrically opposed to a magnetic pole, and in the specific embodiment of the present invention and its components exemplified by the drawings, all relate to front and rear, left and right, top and bottom, upper and lower, and The horizontal and vertical references are for convenience of description only and are not intended to limit the invention, nor to limit its components to any position or spatial orientation. The drawings and the dimensions specified in the specification can be varied in accordance with the design and needs of the specific embodiments of the present invention without departing from the scope of the invention.

In the configuration of the electric device with respect to the magnetic pole eccentricity of the present invention, as shown in FIG. 1, FIG. 2, FIG. 3 and FIG. 4, the electric device has an induction coil group 10, and one side 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 synchronously movable relative to the induction coil assembly 10, and the induction coil assembly A switch group 40 is disposed between the horizontal magnetic group 20 and the vertical magnetic group 30, and the switch group 40 is operable to selectively supply power to the induction coil group 10;

The detailed configuration of the first embodiment of the present invention is also disclosed in FIG. 1 and FIG. 2, wherein the induction coil assembly 10 can be defined as a stator, and the induction coil assembly 10 is One or more coil members 11 are formed [more than one embodiment shown in FIGS. 17 and 18], and each coil member 11 has a magnetizer 12 extending in a vertical direction and at least one ring is disposed therein. The coil 13 of the magnetizer 12 is configured to be connected to an electric power source. 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 field as the rotor. Group 30;

The horizontal magnetic group 20 is formed by at least one first magnetic member 21 having magnetization in the moving direction. [One or more embodiments refer to the embodiment shown in FIG. 17 and FIG. 18], and each of the first magnetic members 21 is horizontal. One end of the front and rear ends corresponding to the moving direction of the induction coil group 10 may be defined as a first magnetic pole 211 [ie, an N pole or an S pole], and an end corresponding to the moving direction away from the induction coil group 10 may be defined as a second magnetic pole. 212 [ie S pole or N pole];

Further, the perpendicular magnetic group 30 is composed of at least one second magnetic member 31 magnetized in a vertical direction of movement [more than one embodiment shown in FIGS. 17 and 18], and each of the second magnetic members 31 is erected. One end of the corresponding induction coil group 10 in the upper and lower ends may be defined as a third magnetic pole 311 [ie, N pole or 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 pole 21 of the first magnetic member 21 and the perpendicular magnetic group 30 of the second magnetic member 31 The third magnetic pole 311 can be the same magnetic pole [the first and second embodiments of the power supply of the front section of FIG. 1 and FIG. 2] or the different magnetic poles. The third and fourth embodiments of the power supply of the rear section of FIG. 3 and FIG. 】;

The switch group 40 is composed of a power switch 41, a power-off switch 42 and first and second sensing elements 45, 46, as shown in the first and second embodiments of FIG. 1 and FIG. The second sensing elements 45, 46 can be disposed on the axis of the coil member 11 of the induction coil group 10 corresponding to the horizontal magnetic group 20 and the perpendicular magnetic group 30, and the power supply switch 41 of the switch group 40 is disposed on the horizontal magnetic group 20. The first magnetic member 21 is displaced into the end of the first magnetic pole 211 of the induction coil assembly 10, and the power-off switch 42 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. When the horizontal magnetic group 20 moves closer to the coil member 11, and when the power supply switch 41 on the first magnetic member 21 detects the first sensing element 45 opposite to the coil member 11, the electric power source and the coil member 11 can be communicated. The coil 13 is 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 power-off switch 42 in the center of the second magnetic member 31 is opposite on the detecting coil member 11, When the second sensing element 46 is turned off, the connection between the power supply and the coil 13 of the coil member 11 can be cut off to form a power failure; The third and fourth embodiments of FIG. 3 and FIG. 4, wherein the first and second sensing elements 45, 46 can be disposed on the axis of the coil member 11 of the induction coil assembly 10 corresponding to the ends of the perpendicular magnetic group 30 and the horizontal magnetic group 20, The power supply switch 41 of the switch group 40 is disposed on the central axis of the third magnetic pole 311 of the second magnetic member 31 of the perpendicular magnetic group 30, and the power-off switch 42 is disposed on the first magnetic member 21 of the horizontal magnetic group 20. Displaced away from the end of the second magnetic pole 212 of the inductive coil assembly 10 for moving the perpendicular magnetic group 30 into the coil member 11, and when the power supply switch 41 on the second magnetic member 31 is opposite on the detecting coil member 11 When the first sensing element 45 is connected, the electric power source and the coil 13 of the coil member 11 can be connected to each other, and when the horizontal magnetic group 20 leaves the coil member 11, and the power-off switch 42 on the first magnetic member 21 is inspected. When the second sensing element 46 on the coil member 11 is known, the connection between the power supply and the coil 13 of the coil member 11 can be cut off to cause a power failure, and a state in which the rear stage is powered is formed;

Thereby, the group constitutes an electric device capable of eliminating the induced voltage and increasing the magnetic assisted magnetic group with respect to the magnetic pole.

As for the electric device of the present invention in actual use, the previous stage power supply is taken as an example, and the action thereof is as shown in FIG. 5 to FIG. 7 and FIG. 8 to FIG. 10, because the horizontal magnetic group 20 is magnetized by the first magnetic piece in the moving direction. 21 is connected in series, and the perpendicular magnetic group 30 is composed of a second magnetic member 31 which is magnetized in a relatively vertical direction, so that the first half (also referred to as an electric region) is relatively opposed by the magnetic lines of the two. The magnetic flux is sharply reduced, and the magnetic lines of force are mutually compressed to form a magnetic beam parallel to the moving direction, that is, since the magnetic lines of the sparse magnetic field between the horizontal magnetic group 20 and the perpendicular magnetic group 30 are compressed, the coil member 11 which is not perpendicular to the inductive coil group 10 is formed. The coil 13 generates a cut, 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, thereby reducing energy consumption;

When the horizontal magnetic group 20 and the perpendicular magnetic group 30 are synchronized with respect to the induction coil assembly 10, and when the first magnetic member 20 of the horizontal magnetic group 20 is on the first magnetic member 21, the power supply switch 41 of the switch group 40 corresponds to the coil member of the induction coil assembly 10. When the first sensing element 45 is turned on [as shown in FIG. 5, FIG. 6, FIG. 8, FIG. 9], the coil 13 of the coil member 11 can be electrically connected to the power supply source to form a power supply state. One end of the coil member 11 corresponding to the first magnetic 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 is corresponding to the second magnetic member 31 of the perpendicular magnetic group 30. The third magnetic poles 311 are of different polarities 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 induced voltage can be eliminated in the foregoing Under low input power, the output power is greatly increased and the energy conversion rate is improved. 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 second sensing element 46 on the coil member 11, [Fig. 7, Fig. 10], The connection between the electric power source and the coil 13 of the coil member 11 is cut off to form a power failure. Otherwise, when the third magnetic pole 311 of the second magnetic member 31 of the perpendicular magnetic group 30 passes over the center line of the coil member 11 of the induction coil assembly 10, such as the induction coil group 10 The coil 13 of the coil member 11 continues to be electromagneticized, because the coil member 11 corresponds to the perpendicular magnetic group 30, and the third magnetic pole 311 of the second magnetic member 31 has a different polarity, resulting in a reverse tension which is different from the moving direction, forming a magnetic The resistance, however, is due to the fact that this magnetic resistance is not generated at this time, so that the horizontal magnetic group 20 and the perpendicular magnetic group 30, which are the rotors, can be inertially operated.

In addition, when the electric device of the present invention is actually used, the power supply in the subsequent stage is taken as an example, and the operation thereof is as shown in FIG. 11 to FIG. 13 and FIG. 14 to FIG. 16, because the horizontal magnetic group 20 is magnetized by the first magnetic field in the moving direction. The pieces 21 are connected in series, and the perpendicular magnetic group 30 is composed of the second magnetic members 31 which are magnetized in opposite directions and which are magnetized in the vertical direction. Therefore, the second half (also referred to as the electric area) is relatively opposed due to the magnetic lines of the two. The magnetic flux is sharply reduced, and the magnetic lines of force are mutually compressed to form a magnetic beam parallel to the moving direction, that is, since the magnetic lines of the sparse magnetic field between the horizontal magnetic group 20 and the perpendicular magnetic group 30 are compressed, the coils are not perpendicular to the induction coil group 10. The coil 13 of the piece 11 is cut, and the induced voltage can be effectively eliminated, so that the horizontal magnetic group 20 and the perpendicular magnetic group 30 can be driven with low input power, thereby reducing energy consumption;

When the horizontal magnetic group 20 and the perpendicular magnetic group 30 are synchronized with respect to the induction coil assembly 10, and when the second magnetic member 31 of the perpendicular magnetic group 30 is on the second magnetic member 31, the power supply switch 41 of the switch group 40 corresponds to the coil of the induction coil assembly 10. When the first sensing element 45 is on the device 11, as shown in FIG. 11, FIG. 12, FIG. 14, and FIG. 15, the coil 13 of the coil member 11 can be electrically connected to the power supply to form a power supply state. One end of the coil member 11 corresponding to the second magnetic member 31 is formed to have the same polarity as the third magnetic pole 311 for generating a repulsive thrust in the moving direction, and the coil member 11 is corresponding to the horizontal magnetic group 20 of the first magnetic member 21. The second magnetic poles 212 are of different polarities 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 induced voltage can be eliminated in the foregoing Under low input power, the output power is greatly increased and the energy conversion rate is improved. In addition, when the horizontal magnetic group 20 is away from the coil member 11, and when the power-off switch 42 of the second magnetic pole 212 of the first magnetic member 21 detects the opposite second sensing element 46 on the coil member 11, [Fig. 13, Fig. 16] The connection between the power supply and the coil 13 of the coil member 11 can be cut off to form a power failure. Otherwise, when the second magnetic pole 212 of the first magnetic member 21 of the horizontal magnetic group 20 passes over the center line of the coil member 11 of the induction coil assembly 10, such as the induction coil assembly 10 The coil 13 of the coil member 11 continues to be electromagneticized, because the coil member 11 corresponds to the horizontal magnetic group 20, and the second magnetic pole 212 of the first magnetic member 21 has a different polarity, resulting in a reversal force which is different from the moving direction, forming a magnetoresistance. However, since the power is off at this time, the 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 induction coil assembly 10 of the present invention may have two 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, respectively. 21 is formed in series with the second magnetic member 31. As shown in FIG. 17 and FIG. 18, 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 pole opposite direction [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 is adjacent to each other. The N pole of the first magnetic member, and the perpendicular magnetic group 30 are formed by two or more second magnetic members 31 magnetized in a vertical direction, and adjacent to the second magnetic member The third magnetic pole 311 of the 31 is a different magnetic pole [that is, when the third magnetic pole of the current second magnetic component is S pole, the third magnetic pole of the second magnetic component is N pole, and the current second magnetic component When the three magnetic poles are N poles, the third magnetic pole of the second magnetic component is S poles, and as shown in FIG. 17, the first and second sensing elements 45, 46 of the switch group 40 can The axis of the coil member 11 disposed on the induction coil group 10 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 in the first magnetic member 21 of the horizontal magnetic group 20 to be inductively sensed. The first magnetic pole 211 end of the coil assembly 10 is disposed, and the power-off switch 42 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 to form a front section to supply power. Or as shown in FIG. 18, the first and second sensing elements 45, 46 may be disposed on the axis of the coil member 11 of the induction coil group 10 corresponding to both ends of the perpendicular magnetic group 30 and the horizontal magnetic group 20, and the switch group 40 is given. The electric switch 41 is disposed on a central axis of the third magnetic pole 311 of the second magnetic member 31 of the perpendicular magnetic group 30, and the first magnetic member 21 of the power-off switch 42 disposed on the horizontal magnetic group 20 is displaced away from the induction coil assembly 10. The end of the second magnetic pole 212 is formed to supply power to the rear section.

Through the foregoing description, the electric device of the magnetic group of the present invention with respect to the magnetic pole eccentricity is formed by the horizontal magnetic group 20 being serially connected by the first magnetic member 21 magnetized in the moving direction, and the perpendicular magnetic group 30 is opposite and The second magnetic member 31 is magnetized in the vertical direction of movement, so that the electric field (meaning the front portion of FIGS. 1 and 2 and the rear portion of FIGS. 3 and 4) is caused by the magnetic lines of the two colliding with each other, and the magnetic flux is sharply reduced. And the magnetic lines of force are mutually compressed to form a magnetic beam parallel to the moving direction, so that the magnetic lines of force 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, so that the horizontal magnetic group 20 and the perpendicular magnetic group 30 are It can be driven by low input power to reduce energy consumption. At the same time, the moving horizontal magnetic group 20 and the perpendicular magnetic group 30 can simultaneously obtain two forward magnetic assistance through the switch group 40, and can output at low input power. High output power, which can effectively improve the efficiency of energy conversion.

In this way, it can be understood that the present invention is an innovative creation, in addition to effectively solving the problems faced by the practitioners, and greatly improving the efficacy, and the same or similar product creation or public use is not seen in the same technical field. At the same time, it has an improvement in efficacy.

Claims (4)

1. An electric device with a magnetic pole eccentricity with respect to a magnetic pole, wherein 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 be Synchronous relative induction coil group motion:

   The inductive coil assembly has at least one coil member, and each coil member has a magnetizer extending in a vertical direction of movement and at least one coil disposed on the magnetizer, the coil being 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 a first magnetic pole is formed at one end of the front and rear ends of each of the first magnetic members adjacent to the induction coil group. And a second magnetic pole is formed at one end of the corresponding moving direction away from the induction coil group;

   Further, the perpendicular magnetic group is composed of at least one second magnetic member that is 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 magnetic pole, and different Forming a fourth magnetic pole at one end of the induction coil group, and further, 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 first magnetic group of the horizontal magnetic group is opposite. The first magnetic pole of the piece has the same magnetic pole as the third magnetic pole of the second magnetic piece of the perpendicular magnetic group;

   The switch group is composed of a power supply switch, a power-off switch, and first and second sensing elements. The first and second sensing elements can be respectively disposed on the axis of the coil component of the induction coil group corresponding to the horizontal magnetic group and the perpendicular magnetic component. At both ends of the group, the first magnetic member of the power switch 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 member of the perpendicular magnetic group. The central axis of one side of the magnetic pole forms a state in which the front section is energized.
2. The electromagnetism device according to claim 1, wherein the horizontal magnetic group of the electric device is formed by connecting two or more first magnetic members having magnetization directions in series. And the adjacent first magnetic members are opposite poles, and the perpendicular magnetic group is formed by two or more second magnetic members magnetized in a vertical direction, and adjacent second magnetic The third magnetic pole of the piece is a distinct magnetic pole.
3. An electric device with a magnetic pole eccentricity with respect to a magnetic pole, wherein 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 be Synchronous relative induction coil group motion:

   The inductive coil assembly has at least one coil member, and each coil member has a magnetizer extending in a vertical direction of movement and at least one coil disposed on the magnetizer, the coil being 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 a first magnetic pole is formed at one end of the front and rear ends of each of the first magnetic members adjacent to the induction coil group. And a second magnetic pole is formed at one end of the corresponding moving direction away from the induction coil group;

   Further, the perpendicular magnetic group is composed of at least one second magnetic member that is 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 magnetic pole, and different Forming a fourth magnetic pole at one end of the induction coil group, 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 then phase The first magnetic pole of the first magnetic member of the pair of horizontal magnetic groups and the third magnetic pole of the second magnetic member of the perpendicular magnetic group have different magnetic poles;

   The switch group is composed of a power supply switch, a power-off switch, and first and second sensing elements. The first and second sensing elements can be respectively disposed on the axis of the coil component of the induction coil group. The magnetic switch is disposed at both ends of the horizontal magnetic group, and the power switch is disposed at a central axis of the third magnetic pole side of the second magnetic member of the perpendicular magnetic group, and the power switch is disposed at the first magnetic member of the horizontal magnetic group The displacement is separated from the second pole end portion of the induction coil group to form a state in which the rear section is energized.
4. The electromagnet device according to claim 3, wherein the horizontal magnetic group of the electric device is formed by connecting two or more first magnetic members having magnetization in a moving direction. And the adjacent first magnetic members are opposite poles, and the perpendicular magnetic group is formed by two or more second magnetic members magnetized in a vertical direction, and adjacent second magnetic members The third magnetic pole is a distinct magnetic pole.