TWI621325B - Magnetoelectric compound machine - Google Patents

Abstract

The present invention relates to a magnetoelectric multi-functional machine which is formed by interlacing at least one magnetic disk and at least one coil disk which are synchronously movable, and at least one electric module and at least one power generating die are arranged on the magnetic disk and the coil disk. The electric module is disposed on the outermost diameter of the disk and the coil disk, and one of the power modules is disposed on the innermost diameter of the disk and the coil disk, thereby being magnetically assisted by the electric module and enlarged by the force distance And the magnetic current does not interfere, which can increase the rotation rate and the motion thrust of the magnetic disk, and achieve the purpose of small electric power consumption and large thrust of the electric module, and at the same time, the coaxial power generation module generates a high cutting frequency and increases the power generation amount.

Description

Magnetoelectric compound machine

The invention belongs to the technical field of magnetoelectric, in particular to a magnetoelectric compound machine capable of generating kinetic energy and electric energy coaxially.

According to the general motor, the electromagnetic principle is mainly used to generate high-speed rotation, which is composed of a stator and a rotor that can rotate relative to each other. Taking a coil motor as an example, wherein the inner edge of the stator is provided with a plurality of coils, and the rotor is The outer edge is provided with a plurality of magnetic members corresponding to the coil, and the coil is magnetized by the power supply to the coil, thereby generating a magnetic force of repulsive and attracting magnetic force with the magnetic member of the rotor, thereby driving the rotor to rotate at a high speed, further driving an axis provided on the rotor. The rod forms a power output, such as a motor.

The general generator is an electromagnetic device composed of an induction coil component group and a magnetic array, wherein the induction coil component group is provided with at least one coil on at least one of the magnets, and the magnetic array is connected to the axis of the induction coil component. Two magnetic members are arranged at two ends, and the two magnetic members are arranged opposite to each other, and the magnetic column group and the induction coil member group can be respectively defined as a rotor and a stator, and the relative linear or rotational motion is used to make The coil of the induction coil component group generates an induced electromotive force due to the magnetic line cut of the magnetic array, thereby achieving the purpose of power generation.

From the above principle of the motor and the generator, both are achieved by the principle of magnetoelectricity. The main difference is that the connected power supply of the magnetoelectric device and the connected load are electrically charged, and the motor and the generator are respectively formed. It can be seen that it may be designed to The same mechanism, and forming a generator to provide electricity to the motor, and the motor provides power to the generator to form a device of the compound machine; but when the motor is in operation, the intermittent power supply mode is adopted to obtain the required magnetic force, In order to drive the rotor, but with the high magnetic flux and high cutting number of the coil and the magnetic member, during the period of no power supply, the coil is still subjected to the magnetic cutting phenomenon of the magnetic member with the relative motion of the inertia, and the induced electromotive force is generated. The motor needs to input a large electric drive, which will result in waste of energy, and under the same power input, the motor output power performance is not good, which also affects the generator can not generate large power.

In other words, the existing magnetoelectric device with power generation and power function cannot effectively reduce the induced electromotive force when the motor is not powered, resulting in a large energy consumption of the motor, while the magnetic resistance during operation is large and the magnetic assistance during driving is small. And how to solve the above problems, is the industry's urgent need for developers.

The inventor of the present invention has intensively discussed the problems faced by the aforementioned magnetoelectric devices of the generator and the electric motor, and actively pursues solutions through years of research and development experience in related industries, and has been continuously researching and trialing. Finally, a magnetoelectric compound machine was successfully developed to overcome the troubles and inconveniences that existing magnetoelectric devices cannot generate sufficient power and power under efficiency.

Therefore, the main object of the present invention is to provide a magnetoelectric compounding machine with a large output kinetic energy, which can generate a strong magnetic assisting force by the design of the electromagnet-driven magnetic field across the magnetic gap and the magnetic current does not interfere with each other, thereby further improving the operation. The rotation rate of the time effectively increases the output power.

Moreover, the second primary object of the present invention is to provide an energy-saving magnetic The electric compound machine can reduce the induced electromotive force of the electric module in the magnet region, and can avoid the magnetic resistance, and can be used for reducing the input power during driving and reducing the loss of electric energy.

Furthermore, another main object of the present invention is to provide a magnetoelectric compound machine capable of coaxial power generation, which can increase the rotation rate and the motion thrust of the magnetic disk due to strong magnetic assistance, force distance amplification, and magnetic current interference. The power generation module produces a high cutting frequency and increases the amount of power generated.

Based on the above, the present invention mainly achieves the foregoing objects and functions by the following technical means, which are formed by a disk that can be relatively moved and a coil disk, and the disk and the coil disk are provided with at least An electric module and at least one power generating module, wherein one electric module is disposed at an outermost diameter of the magnetic disk and the coil disk, and one of the power generating modules is disposed at an innermost diameter of the magnetic disk and the coil disk, and the disk and the The coil discs can be respectively defined as a rotor or a stator, and can generate relative motion; the electric modules are composed of a set of electric magnetic arrays disposed on the magnetic disk and a set of coils, and the electric magnetic column The group consists of an electric coil array and a set of inductive switches; wherein the electric magnetic array on the magnetic disk is arranged in the moving direction, at least one first magnetic member and at least one second magnetic member, and the first and second The lengths of the magnetic members are equal, and the first and second magnetic members are magnetized in the moving direction, and the magnetic poles of the adjacent first and second magnetic members are adjacent to the same pole, and the adjacent first and second magnetic members or Second, a magnetic member has an equal width a magnetic gap; and an electric coil array on the coil disk having at least one same axis and spaced apart induction coil members, the induction coil members respectively having a magnetizer and a coil wound around the magnetizer, and the induction coil The coils of the components can be respectively connected to a power supply for forward or reverse power supply, and the coil length of the induction coil member is The length of any one of the magnetic members of the electric magnetic column group greater than or equal to one quarter, and less than or equal to three quarters of the length of any one of the magnetic magnetic column groups, and the length of the magnet of the induction coil member is greater than or equal to the electric magnetic column The length of any magnetic member plus the adjacent magnetic gap width, and less than or equal to the length of any magnetic member of the electromagnet group plus the adjacent magnetic gap width plus the same group coil length; Having at least one power detecting device, at least one power detecting device, and at least one conducting sensor and at least one cutting sensor disposed in the electric coil group, wherein the power detecting device is Separating the magnetic pole faces of the first and second magnetic members in the moving direction relative to the inductive coil members, and the power-off detecting devices are disposed in the first and second magnetic members according to the moving direction Relative to the magnetic pole faces of the induction coil members, the conduction inductors are disposed in the coils of the induction coil members to move away from the end portions of the electromagnetism group, and the disconnecting sensors are The system is located in the sensing lines The relative movement direction of the coil of the piece enters the end of the electric magnetic array; the other power generation modules are composed of a set of electromagnetic groups disposed on the magnetic disk and a set of relative power generating coil sets disposed on the coil disk The electromagnetic group is arranged on the magnetic disk with at least one third magnetic member and at least one fourth magnetic member arranged in a moving direction, and the third and fourth magnetic members are magnetized in a parallel moving direction, and the phases are The magnetic poles at the two ends of the adjacent third and fourth magnetic members are arranged adjacent to each other in the same polarity, and the axes of the vertical movement directions of the third and fourth magnetic members are respectively associated with the first and second magnetic groups of the adjacent electromagnetic array. The axis of the member is coaxial with the axis of the disk axis, and the magnetic poles of the third and fourth magnetic members are in phase with the magnetic poles of the adjacent first and second magnetic members or the second and second magnetic members. Neighboring; the generating coil set is arranged on the coil disk along the moving direction At least one of the power generating coils connected to the load, and the power generating coils extend in a parallel motion direction, and the power generating coils corresponding to the third and fourth magnetic members of the electromagnetic group.

Thereby, the magnetoelectric composite machine of the present invention is designed to pass through the special length of the magnet in the induction coil component of the electric coil array of the electric module, and the magnetic flux of the electromagnetism group can be crossed by the magnet to enable simultaneous magnetic action. Producing complete magnetic assistance to adjacent magnetic members and avoiding magnetic resistance, and effectively reducing the induced electromotive force of the electric module in the magnet region, thereby reducing the input power of the electric coil train to the electric drive, and further The outer diameter of the disk and the coil disk is set, and the power generation module is disposed at the innermost diameter of the disk and the coil disk, and the power module is amplified by the force distance and the magnetic current is not disturbed, so that the rotation speed and the motion thrust of the disk are increased. To achieve the purpose of small electric power and large thrust of the electric module, and at the same time, the coaxial power generation module generates a high cutting frequency and increases the power generation amount, thereby greatly increasing the added value and improving the economic efficiency.

The preferred embodiments of the present invention are set forth in the accompanying drawings, and in the claims

(1)‧‧‧ Disk

(101)‧‧‧Electrical Module

(102)‧‧‧Power Module

(105)‧‧‧ shaft

(10) ‧‧‧Electromagnetic group

(11)‧‧‧First magnetic parts

(12)‧‧‧Second magnetic parts

(13)‧‧‧ Magnetic gap

(15) ‧‧‧Electromagnetic group

(16)‧‧‧ Third magnetic parts

(17)‧‧‧ Fourth magnetic parts

(2) ‧‧‧ coil disk

(205)‧‧‧Axis hole

(20)‧‧‧Electrical coil array

(21)‧‧‧Induction coil parts

(22)‧‧‧Guide magnets

(23)‧‧‧ coil

(25)‧‧‧Power coil group

(26)‧‧‧Power coil

(30)‧‧‧Induction switch set

(31)‧‧‧Power detector

(32)‧‧‧Power failure detector

(35) ‧‧‧ conduction sensor

(36)‧‧‧ cut off the sensor

The first figure is a schematic diagram of a three-dimensional structure of a preferred embodiment of the magnetoelectric composite machine of the present invention.

Fig. 2 is a schematic plan view showing the arrangement of a magnetic disk in a preferred embodiment of the magnetoelectric composite machine of the present invention.

Fig. 3 is a schematic view showing the planar arrangement of a coil disk in a preferred embodiment of the magnetoelectric composite machine of the present invention.

Fourth: a schematic diagram of the operation of the preferred embodiment of the magnetoelectric composite machine of the present invention, To explain the state of its power supply.

Fig. 5 is a schematic view showing another operation of the preferred embodiment of the magnetoelectric composite machine of the present invention for explaining the state of no power supply.

Figure 6 is a side plan view showing another preferred embodiment of the magnetoelectric composite machine of the present invention for explaining the state of the disk matrix.

The present invention is a magnetoelectric compound machine, with reference to the specific embodiments of the invention and the components thereof as illustrated in the accompanying drawings, all of which relate to front and rear, left and right, top and bottom, upper and lower, and horizontal and vertical, only It is intended to facilitate the description, not to limit the invention, and to limit its components to any position or spatial orientation. The drawings and the dimensions specified in the specification may 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.

The magnetoelectric multi-functional peripheral of the present invention is constructed as shown in the first figure, which is formed by interlacing at least one magnetic disk (1) and at least one coil disk (2), and the magnetic disk (1) and the coil disk ( 2) at least one electric module (101) and at least one power generating module (102) are disposed on the upper part, wherein one electric module (101) is disposed on the outermost diameter of the magnetic disk (1) and the coil disk (2), and One of the power generating modules (102) is disposed at an inner diameter of the magnetic disk (1) and the coil disk (2), and the magnetic disks (1) and the coil disks (2) may be respectively defined as a rotor or a stator. For the purpose of synchronizing relative motions, the present invention uses the disks (1) as rotors and the coil disks (2) as stators. For a detailed embodiment of the preferred embodiment of the present invention, please refer to As shown in the first, second and third figures, the electric modules (101) are provided by a group of electric magnetic arrays (10) arranged on the magnetic disk (1) and a set of coils (2). Relative The electric coil array (20) and the set of inductive switch groups (30) are formed; and the electromagnetic magnetic arrays (10) are as shown in the first and second figures, which are attached to the magnetic disk (1). Between the first magnetic member (11) and the at least one second magnetic member (12), the lengths of the first and second magnetic members (11, 12) are equal, and the first The two magnetic members (11, 12) are magnetized in the moving direction, and the magnetic poles of the adjacent first and second magnetic members (11, 12) or the second and second magnetic members (12, 11) are adjacent to each other, for example The N pole corresponds to the N pole or the S pole corresponds to the S pole [as shown in the second figure], and the adjacent first and second magnetic members (11, 12) or the second and a magnetic members (12, 11) have a a magnetic gap of equal width (13), and further a shaft (105) is provided at the center of each disk (1) for synchronous rotation; and the array of electric coils (20) is as shown in the first and third figures. The induction coil member (21) having at least one same axis and spaced apart from each other on the coil disk (2), the induction coil members (21) respectively having a magnetizer (22) and a winding a coil (23) of a magnet (22), and the coil (23) is connected to an electric The source, the power source can be positively fed or reversely powered, so that the coil (23) of the induction coil member (21) can be magnetized when the power source is connected, and the electric coil array (20) is actuated relative to the electromagnetic array (10). The magnetic force of the relative motion of the two, and the length of the coil (23) of the induction coil member (21) is greater than or equal to the length of the quarter magnetic member (11, 12), and the length of the coil (23) is less than or equal to four. The length of the three magnetic members (11, 12), and the optimum length of the coil (23) of the present invention is equal to the length of the two-quarter magnetic members (11, 12). In addition, the length of the magnetizer (22) of the induction coil member (21) is greater than or equal to the length of any of the magnetic members (11, 12) plus the width of the adjacent magnetic gap (13), and the length of the magnetizer (22) is less than or equal to The length of any magnetic member (11, 12) plus the width of the adjacent magnetic gap (13) plus the same set of lines The length of the circle (23), and the optimum length of the magnetizer (22) of the present invention is the length of any of the magnetic members (11, 12) plus the width of the adjacent magnetic gap (13), and the center of each coil disk (2) is formed. There is a shaft hole (205) for the shaft (105) to pivot, so that the disk (1) can be rotated relative to the coil disk (2); please refer to the second and third figures, the sensor switch group (30) The utility model comprises at least one power detector (31), at least one power failure detector (32), and an electric coil array (20) disposed on the magnetic disk (1) of the electric magnetic array (10). And at least one conduction sensor (35) and at least one cut-off inductor (36) for controlling whether the coil (23) of the electric coil array (20) is in communication with the power source. The power detectors (31) are respectively disposed in the first and second magnetic members (11, 12) and enter the magnetic pole faces of the induction coil members (21) according to the moving direction, and the power is off. The detector (32) is disposed in the first and second magnetic members (11, 12) opposite to the magnetic pole faces of the induction coil members (21) according to the moving direction, and the conduction inductors (35) Between the coils (23) of the induction coil members (21), the relative movement direction is away from the ends of the electro-magnetic arrays (10), and the cutting sensors (36) are respectively disposed on The relative movement direction of the coils (23) of the induction coil members (21) enters the end portions of the electro-magnetic arrays (10) for the conduction sensor (35) on the induction coil member (21) to be inspected. When the first and second magnetic members (11, 12) are supplied to the power detector (31), the power source and the coil (23) of the corresponding induction coil member (21) can be connected to each other to generate electricity, and magnetic force is generated due to magnetization [eg The fourth figure], as for the cut-off inductors (36), when the power-off detectors (32) of the first and second magnetic members (11, 12) are detected, the corresponding induction coil members can be 21) The coil (23) is not connected to the power source Feeding a state [not] As FIG Fifth, communication and power supply to the electric induction coil element value (21) of the coil (23) is in the first When the positions of the magnets of the first and second magnetic parts (11, 12) are opposite, the induced electromotive force can be reduced, so that the input power can be effectively reduced; and the power generating modules (102) are set on the disk (1). The electromagnetic group (15) and a set of relative power generating coils (25) disposed on the coil disk (2); wherein the electromagnetic generating groups (15) are arranged on the magnetic disk (1) in the moving direction at least a third magnetic member (16) and at least a fourth magnetic member (17), and the third and fourth magnetic members (16, 17) are magnetized in a parallel motion direction, and the adjacent third and fourth The magnetic poles of the magnetic members (16, 17) are arranged adjacent to each other in the same polarity, and the axes of the vertical movement directions of the third and fourth magnetic members (16, 17) are respectively adjacent to the adjacent electromagnetic arrays (10). The centers of the first and second magnetic members (11, 12) overlap each other with respect to the axis of the axis of the magnetic disk (1), and the two ends of the third and fourth magnetic members (16, 17) of the electromagnetic group (15) The magnetic poles are adjacent to the magnetic poles of the adjacent first and second magnetic members (11, 12) or the second magnetic members (12, 11) so that the magnetic currents do not interfere with each other and form a uniform direction. Magnetic path, free of occurrence The collapse can increase the magnetic assist strength and the amount of electromagnetic flux cut, for example, the N pole corresponds to the N pole or the S pole corresponds to the S pole [as shown in the second figure]; and the power generating coil group (25) is attached to the coil disk ( 2) at least one power generating coil (26) connected to the load is arranged in the upper direction of movement, and the power generating coils (26) extend in parallel movement direction, and the power generating coils (26) correspond to the electromagnetic generating group (15) The third and fourth magnetic members (16, 17) are provided for the third and fourth magnetic members (16, 17) of the electromagnetic group (15) and the power generating coil of the generating coil group (25) (26) When the magnetic line cutting is formed, power generation can be generated and used for load or storage; Thereby, the group constitutes a magnetoelectric compound machine capable of outputting large kinetic energy and high electric energy.

As for the preferred embodiment of the magnetoelectric composite machine of the present invention, when it is actually actuated, as shown in the fourth and fifth figures, when the magnetic magnetic array (10) of the magnetic disks (1) and the coil disks (2) The electric coil array (20) synchronously generates relative motion. For example, the present invention rotates the disk (1) as the rotor and the coil disk (2) as the stator does not move; as shown in the fourth figure, when the inductive switch group (30) is a power detecting device (31) at one end of the first magnetic member (11) or the second magnetic member (12) of the electromagnetism group (10) in the same moving direction is used to sense the coil of the electric coil group (20) (23) When the conduction sensor (35) is away from the end in the relative movement direction, the corresponding coils (23) of the electric coil array (20) are respectively reversely fed or forwardly powered, so that the magnet of the induction coil member (21) (22) Corresponding polarity is generated by the magnetization of the coil (23). When the first magnetic member (11) corresponds to the coil (23) with the S pole, the polarity of the magnet (22) of the induction coil member (22) enters the end of the movement direction. It is N pole and the polarity of the exit end is S pole. When the second magnetic member (12) corresponds to the coil (23) with the N pole, the polarity of the magnet (22) of the induction coil member (21) in the moving direction is S pole, and the polarity of the leaving end is N pole. Furthermore, at this time, the position of the magnetizer (22) of the induction coil member (21) at the entrance end in the relative movement direction is located at the next adjacent second magnetic member (12) or the first magnetic member (11), thereby The polarity of the induction coil member (21) of the electric coil array (20) at the exit end in the relative movement direction is the same as the magnetic pole of the induced first magnetic member (11) or the second magnetic member (12). And the relative movement direction forms a repulsive thrust, while the magnetizer (22) of the induction coil component (21) of the electric coil array (20) is in relative motion The polarity of the directional entrance end is opposite to the magnetic pole of the second and a magnetic member (12, 11) adjacent to the first and second magnetic members (11, 12) of the induction, so that they are opposite each other, so that they are opposite The direction of motion forms another repulsive thrust, so that the electric coil array (20) and the electric magnetic array (10) form a magnetic force of full thrust relative to the direction of motion of the electromagnetic array (10), which can effectively improve the rotational speed of the disk (1), thereby improving Output power; conversely, as shown in the fifth figure, the electric magnetic array (10) and the electric coil array (20) continue to move relative to each other when the inductive switch group (30) is in the electric magnetic array (10). a power-off detector (32) at one end of the first and second magnetic members (11, 12) for inductively supplying power to the sensing coil member (21) of the motor coil group (20) (23) When the sensor (36) is cut in the direction of the relative movement direction, the coil (23) of the electric coil array (20) is cut off, so that the induction coil member (21) of the electric coil array (20) is not formed. The magnetic field is applied to prevent the coil (23) of the induction coil member (21) from entering the magnetic gap power generation area, so that large electric power is required to be used for magnetizing the coil (23) and generating Corresponding polarity of the reluctance; and since the magnetic pole axes of the first and second magnetic members (11, 12) of the electromagnetism group (10) are parallel to the direction of motion, the electrocoil array (20) induction coil can be made The coil (23) of the member (21) can effectively reduce the induced electromotive force when the magnet region is not powered, thereby adjusting the input power of the coil (23) of the induction coil member (21) to be electrically driven, and the direction of the magnetic current is uniform. Under the enhanced magnetic assistance, the operating speed of the disk (1) can be increased to achieve the purpose of small power consumption and large thrust; and the electric module (101) is attached to the disk (1) and the coil disk (2). The outermost diameter and the power generation module (102) are disposed on the inner diameter of the magnetic disk (1) and the coil disk (2), and are affected by the magnetic module (101), magnetic force amplification, force distance amplification, and magnetic flow orientation. The power generation module can be enabled under the speed increase operation of the disk (1) The electromagnetic generating group (15) of 102) and the generating coil group (25) generate a high cutting frequency to increase the amount of power generation.

In another embodiment of the present invention, as shown in the sixth figure, the embodiment is a disk type matrix magnetoelectric composite machine, which is two or more magnetic disks opposite to each other ( 1) It is formed by interlacing two or more coil disks (2), and the opposing output magnetic energy and electric energy can be effectively improved by the opposite magnetic poles of the same pole.

In this way, it can be understood that the present invention is an excellent creation, and in addition to effectively solving the problems faced by the practitioners, the effect can be greatly improved, and the same or similar product creation or disclosure is not seen in the same technical field. The use, and at the same time, has an improvement in efficacy. Therefore, the present invention has met the requirements for "novelty" and "progressiveness" of the invention patent, and is the invention of the invention patent.

Claims (10)

A magnetoelectric multi-functional machine, which is formed by a magnetic disk and a coil disk which are relatively movable, and at least one electric module and at least one power generation module are arranged on the disk and the coil disk, wherein one electric module is provided The outer diameter of the disk and the coil disk, and one of the power modules is disposed on the innermost diameter of the disk and the coil disk, and the disk and the coil disk can be respectively defined as a rotor or a stator, which can generate relative motion; The electric module is composed of a set of electric magnetic arrays disposed on a magnetic disk and a set of electric coil arrays and a set of inductive switches disposed on the coil disc and opposite to the electromagnetic array; At least one first magnetic member and at least one second magnetic member arranged in the moving direction of the electric magnetic array on the magnetic disk, and the lengths of the first and second magnetic members are equal, and the first and second magnetic members are in motion The direction is magnetized, and the magnetic poles of the adjacent first and second magnetic members are adjacent to the same pole, and the adjacent first and second magnetic members or the second and the magnetic members have a magnetic gap of equal width; The electric coil array on the disc has at least one same axis And the sensing coil members are respectively spaced apart from each other, and the inductive coil members respectively have a magnetizer and a coil wound around the magnetizer, and the coils of the inductive coil member can be respectively connected to a power source for forward or reverse power supply, and The length of the coil of the induction coil component is greater than or equal to the length of any one of the magnetic members of the electric magnetic array, and is less than or equal to three-quarters of the length of any one of the magnetic magnetic arrays, and the guide of the induction coil member The length of the magnet is greater than or equal to the length of any magnetic member of the electromagnet group plus the adjacent gap width, and is less than or equal to the length of any magnetic member of the electromagnet group plus the adjacent gap width plus the length of the same group of coils; In addition, the sensing switch group includes at least one power detecting device, at least one power detecting device, and at least one conducting sensor and at least one cutting sensor disposed in the electric coil group. The power detecting device is disposed in the first and second magnetic members to enter the magnetic pole faces of the induction coil members according to the moving direction, and the power failure detecting devices are respectively disposed in the first The first and second magnetic members are relatively away from the magnetic pole faces of the induction coil members according to the moving direction, and the conduction inductors are disposed in the coils of the induction coil members to move away from the end of the electromagnetism group. And the cutting sensors are disposed in the coils of the induction coil members to enter the end of the electromagnetism group in a relative movement direction; and the other power generation modules are disposed on the disk by a group The electromagnetic group and a set of relative power generating coils disposed on the coil disk; wherein the electromagnetic group is arranged on the magnetic disk with at least one third magnetic member and at least a fourth magnetic member arranged in a moving direction, and the same The third and fourth magnetic parts are transported in parallel The direction is magnetized, and the magnetic poles of the adjacent third and fourth magnetic members are arranged adjacent to each other in the same polarity, and the axes of the vertical movement directions of the third and fourth magnetic members are respectively adjacent to the adjacent electromagnetic array The centers of the first and second magnetic members are coaxial with the axis of the disk axis, and the magnetic poles of the third and fourth magnetic members are adjacent to the first and second magnetic members or the second and the first The magnetic poles of the magnetic component are adjacent to the same pole; the power generating coil group is arranged on the coil disk with at least one power generating coil connected to the load in the moving direction, and the power generating coils extend in parallel movement direction, and the power generating coils And corresponding to the third and fourth magnetic members of the electromagnetic group. The magnetoelectric multi-functional machine according to claim 1, wherein the optimal length of the coil of the induction coil component of the electric coil array is equal to the length of any one of the magnetic components of the two-fourth electric magnetic array. The optimum length of the magnet is the length of any magnetic member of the electromagnetic array plus the adjacent magnetic gap width. The magnetoelectric laminating machine of claim 1, wherein the position of the inductive coil members of the coil assembly of the coil disc is aligned with the same position of the adjacent magnetic members of the electromagnet array. The magnetoelectric laminating machine of claim 1, wherein the inductive coil members of the coil assembly of the coil disc are arranged in a misaligned position corresponding to the adjacent magnetic members of the electromagnet array. The magnetoelectric laminating machine according to any one of claims 1 to 4, wherein the magnetic disk is used as a rotor, and the coil disk is used as a stator, and a shaft is disposed at a center of the disk, and a shaft for pivoting is formed at a center of the coil disk. The shaft hole allows the disk to rotate relative to the coil disk. A magnetoelectric multi-functional machine, which is formed by two or more magnetic disks that can be synchronously moved relative to each other and two or more coil disks are arranged at intervals, and the disks and the coil disks are respectively provided with at least one An electric module and at least one power generation module, wherein one electric module is disposed at an outermost diameter of the magnetic disk and the coil disk, and one of the power generation modules is disposed at an innermost diameter of the magnetic disk and the coil disk, and the disks are The coil coils can be respectively defined as a rotor or a stator, which can synchronously generate relative motions with each other; the electric modules are composed of a set of electromagnetic arrays disposed on the magnetic disk and a set of coils, and The electric magnetic array is composed of an electric coil array and a set of inductive switches; The at least one first magnetic member and the at least one second magnetic member are arranged in the moving direction of the electric magnetic array on the magnetic disk, and the lengths of the first and second magnetic members are equal, and the first and second magnetic members are The direction of motion is magnetized, and the magnetic poles of the adjacent first and second magnetic members are adjacent to the same pole, and the adjacent first and second magnetic members or the second and the magnetic members have a magnetic gap of equal width; The electric coil array on the coil disk has at least one same-axis and mutually spaced induction coil members, and the induction coil members respectively have a magnetizer and a coil wound around the magnetizer, and the coil of the induction coil member can be Connected to a power supply for forward or reverse power supply, and the length of the coil of the induction coil member is greater than or equal to the length of one of the magnetic members of the electric magnetic array, and less than or equal to three-quarters of the electric magnetic array. The length of any magnetic member, and the length of the magnet of the induction coil member is greater than or equal to the length of any magnetic member of the electromagnet group plus the adjacent gap width, and less than or equal to the length of any magnetic member of the electromagnet group plus Adjacent magnetic gap The inductive switch group includes at least one power detector disposed in the electromagnet group, at least one power failure detector, and at least one conduction layer disposed in the motor coil group The sensor and the at least one cut-off sensor, wherein the power-sensing detectors are disposed in the first and second magnetic members, and enter the magnetic pole faces of the induction coil members in the moving direction, and the power-off detection is performed. The device is disposed in the first and second magnetic members and relatively away from the magnetic pole faces of the induction coil members according to the moving direction, and the conduction inductors are respectively disposed in the relative movement directions of the coils of the induction coil members. Leaving the end of the electromagnetism group, and the cutting sensors are disposed in the coils of the inductive coil members to enter the end of the electromagnetism group in a relative movement direction; In addition, the power generating modules are composed of a set of electromagnetic groups disposed on the magnetic disk and a set of opposite power generating coils disposed on the coil disk; wherein the electromagnetic generating groups are arranged on the magnetic disk in the moving direction. At least one third magnetic member and at least one fourth magnetic member, and the third and fourth magnetic members are magnetized in a parallel movement direction, and the magnetic poles at the opposite ends of the adjacent third and fourth magnetic members are in the same polarity And the adjacent axes, and the axes of the vertical movement directions of the third and fourth magnetic members are respectively coaxial with the axes of the first and second magnetic members of the adjacent electro-magnetic arrays corresponding to the axis of the disk, and the third The magnetic poles at the two ends of the four magnetic members are adjacent to the magnetic poles of the adjacent first or second magnetic members or the magnetic members of the second and second magnetic members; and the generating coils are coupled to the coil plate along the moving direction At least one power generating coil connected to the load is arranged, and the power generating coils extend in a parallel moving direction, and the power generating coils further correspond to the third and fourth magnetic members of the electromagnetic generating group. The magnetoelectric laminating machine of claim 6, wherein the coil of the electric coil array has an optimum length of the coil equal to the length of any one of the two quarters of the electromagnet group, and The optimum length of the magnetic conductor is the length of any magnetic member of the electromagnetic array plus the adjacent magnetic gap width. The magnetoelectric laminating machine of claim 6, wherein the position of the induction coil members of the coil assembly of the coil discs is aligned with the same position of the adjacent magnetic members of the electromagnet array. The magnetoelectric laminating machine of claim 6, wherein the inductive coil members of the electric coil array of the coil discs are arranged in a misaligned position corresponding to the adjacent magnetic members of the electromagnet array. The magnetoelectric laminating machine according to any one of claims 6-9, wherein the magnetic disks are used as rotors, and the coil disks are used as stators, and a shaft is disposed at a center of each disk, and a shaft is formed at a center of each coil disk. The rods are pivoted through the pivot holes to allow the disks to rotate synchronously relative to the coils.