WO2019144367A1 - Shared-magnetism complex magnetoelectric device - Google Patents

Abstract

Disclosed is a shared-magnetism complex magnetoelectric device composed of a pair of opposite magnetic groups and at least one coil column group. The pair of opposite magnetic groups contains two or more magnetic column groups parallel to each other and moving synchronously, each magnetic column group is composed of at least two magnetic members staggered at intervals in a movement direction and magnetized in a direction parallel to the movement direction, the same magnetic poles of adjacent end portions of adjacent magnetic members are adjacent, and the same magnetic poles, located at the same positions, of magnetic members of the opposite magnetic column groups are opposite each other; and the coil column group is composed of a first coil member and a second coil member, the first and second coil members are respectively a ㄈ-shaped body composed of a longitudinal electric body and two parallel transverse power generators, and the electric bodies of the first and second coil members reversely supply power respectively. Thus, the reciprocation of power generation and being electric can be realized, an input current can be reduced, and an output power can be improved, thereby achieving the purpose of energy saving; and during power generation, a gain of magnetic flux shared magnetism in a circuit can be shared and added, thereby increasing the quantity of generated power.

Description

Common magnetic composite magnetoelectric device Technical field

The invention relates to the technical field of electromagnetic devices, in particular to a common magnetic composite magnetic device with power generation and electric action, which can achieve the purpose of small input and large output, and has the effect of energy saving, and can be shared at the same time. The gain of the magnetic flux of the magnetic group can increase the power generation.

Background technique

Generally, an electric motor or a generator is usually operated by an electromagnetic device. The conventional electromagnetic device is mainly composed of a relatively movable magnetic group and a coil group, which are respectively composed of a rotor and a stator, and an electric motor is taken as an example. The group performs intermittent power supply to make it an electromagnet, and can generate a magnetic force that repels and attracts relative to the magnetic group, thereby driving the rotor to rotate at a high speed. As for the generator, the rotor is driven to rotate at a high speed by an external force, so that the coil group generates power by cutting the magnetic lines;

However, in practical applications, there are some problems in the conventional electromagnetic device. For example, when applied to a motor, when a power supply is suspended, a magnetic attraction is generated between the coil group and the magnetic group, and a magnetic resistance is caused to cause dynamic damage, so when it is to be started again When the input power is required to be large enough to drive, causing unnecessary energy loss, not only the operation efficiency is not good, but also the energy saving requirement cannot be achieved.

In another case, when the conventional electromagnetic device is applied to a generator, when the coil group is connected to the load to generate a current, the coil group is induced to magnetize into an electromagnet, and the coil group and the magnetic group are magnetically repulsive and magnetoresistive, so Under the load, there will be dynamic damage caused by proliferative magnetoresistance. Therefore, the traditional generator is not only difficult to be used for micro-power generation, and the operation rate is difficult to increase, which seriously affects the number of cutting lines and the cutting frequency of the magnetic lines, so the power generation efficiency is low, and the energy conversion is made. Low rate;

In other words, since the existing electromagnetic device is applied to the motor or the generator, there is a problem that the operation loss is caused by the proliferative magnetoresistance, and the energy consumption is reduced and the performance is lowered, so that the conventional electromagnetic device can only be applied. In the single-function electric equipment or power generation equipment, it is impossible to combine power generation and electric power at the same time. Therefore, how to solve the above problems is urgently needed for development in the industry.

The reason is that the inventors have in-depth discussion on the problems faced by the aforementioned conventional electromagnetic devices, and have sought to solve the problem through years of research and development experience in related industries, and have succeeded in developing a kind of research through continuous efforts in research and trials. The co-magnetic composite magnetoelectric device can overcome the inconvenience and trouble caused by the high energy consumption and low energy conversion efficiency of the existing electromagnetic device.

Summary of the invention

Therefore, the main object of the present invention is to provide a co-magnetic hybrid magnetoelectric device, which can simultaneously have both an electric mode and a power generation mode, thereby improving performance and reducing energy consumption.

In addition, the second main object of the present invention is to provide a common magnetic composite magnetoelectric device capable of improving magnetic assistance and reducing input current, and having the effects of small input and large output, thereby achieving energy saving.

Furthermore, another main object of the present invention is to provide a co-magnetic composite magnetoelectric device capable of sharing the magnetic flux gain of the opposing magnetic group and increasing the cutting angle of the magnetic lines of force, thereby increasing the number of cutting lines and the cutting frequency of the magnetic lines of force. In order to increase the amount of power generation, thereby improving energy conversion efficiency.

Based on this, the present invention achieves the above objects mainly by the following technical means.

A common magnetic composite magnetoelectric device is composed of a pair of magnetic groups and at least one coil group, wherein the opposite magnetic group and each coil group are respectively defined as relatively movable rotors or stators; The opposite magnetic group includes two or more magnetic column groups which are parallel to each other and move in synchronization, wherein each magnetic column group is at least one first magnetic member which is staggered in the moving direction and is equal in length At least one second magnetic member is formed, and each of the first and second magnetic members is magnetized in a parallel movement direction, and the adjacent first and second magnetic members or the second and the magnetic members respectively have a magnetic gap, and The magnetic poles of the adjacent first and second magnetic members or the adjacent ends of the second and the magnetic members are adjacent to the same pole, and are opposite to each other with respect to the first and second magnetic members and the magnetic gap of the magnetic array, and are opposite The magnetic poles of the first and second magnetic members of the magnetic array are in the same polarity; the coil groups are equally spaced between the relative magnetic columns, and each coil group is composed of at least one adjacent group. a first coil member and a second coil member are arranged at intervals in a moving direction, wherein The length of the adjacent first coil member and the second coil member is less than or equal to the length of any one of the first magnetic member or the second magnetic member of the magnetic array group and its adjacent magnetic gap, and is greater than or equal to the first a length of the magnetic member or the second magnetic member, and each of the first coil members is a "ㄈ" type body composed of a longitudinal first electric body and a lateral first power generating body and a second power generating body, wherein the first coil body The electric body has a longitudinal magnetic column and a set of electric coils with longitudinal magnetic columns. The electric coil of the first electric body is electrically connected to a power source, and the power supply connected to the first electric body is continuous to the first The electric coil of the electric body is forward-powered or reverse-powered, and each of the first and second power generating bodies respectively has a transverse magnetic field connected to both ends of the longitudinal magnetic column of the first electric body and parallel to the moving direction. a rod, and a transverse magnetic rod of each of the first and second power generating bodies are respectively provided with a power generating coil connected to a load, and each of the second coil parts is composed of a longitudinal second electric body and a lateral third power generating body. a "ㄈ" type body composed of a fourth power generation body, The second electric body has a longitudinal magnetic column and a set of electric coils with a longitudinal magnetic column. The electric coil of the second electric body is electrically connected to a power source, and the power supply of the second electric body is continuously connected. The electric coil of the second electric body is reversely fed or forwardly fed, and the feeding direction of the second electric body of the second coil member is opposite to the feeding direction of the first electric body of the first coil member To the power supply, each of the third and fourth power generating bodies respectively has a transverse magnetic rod connected to both ends of the longitudinal magnetic column and parallel movement direction, and respectively, the lateral magnetic rods of the third and fourth power generating bodies respectively The sleeve is provided with a power generating coil connected to a load.

Further, the opposite magnetic group is used as a rotor, and each magnetic column group of the opposite magnetic group is respectively disposed on a movable disk, and another shaft is disposed through each movable disk, and the moving disk of the magnetic group of the opposite magnetic group is The shafts rotate synchronously, and the first coil member and the second coil member of each coil array are disposed on a static disc, and each of the first coil member and the second coil member and the magnetic row group are in a position of a relative radius.

Further, each set of the first coil member and the adjacent end portion of the second coil member of the coil array group abut each other.

Further, each of the longitudinal magnetic columns of the first and second coil members of the coil array has a yoke section protruding from the lateral magnetic rod.

After adopting the above technical means, the common magnetic composite magnetoelectric device of the invention can design the mutual interaction between power generation and electric power through the structure design of the opposite magnetic group and the coil array, and can reduce the input current and improve the output power. In order to achieve the purpose of energy saving, at the same time, when generating electricity, it can share the magnetic flux gain of the opposite magnetic group and increase the cutting angle of the magnetic field lines, thereby increasing the number and frequency of cutting of the magnetic lines, effectively increasing the power generation and further improving the energy conversion efficiency. It can further achieve the purpose of self-power generation, which can effectively increase its added value and enhance its economic benefits.

DRAWINGS

FIG. 1 is a schematic structural view of a common magnetic composite magnetoelectric device according to the present invention.

2 is a perspective exploded view of a common magnetic composite magnetoelectric device of the present invention in practical use.

FIG. 3 is a schematic view showing the operation of the opposite magnetic pole to enter the coil member in the opposite magnetic pole in the first power feeding mode.

FIG. 4 is a schematic view showing the operation of the opposite magnetic pole to enter the magnetic gap of the opposite magnetic pole in the first power feeding mode according to the present invention.

FIG. 5 is a schematic view showing the operation of the opposite magnetic pole to enter the coil member in the opposite magnetic pole in the first power feeding mode.

FIG. 6 is a schematic view showing the operation of the opposite magnetic pole to enter the magnetic gap of the opposite magnetic pole in the first power feeding mode according to the present invention.

FIG. 7 is a schematic view showing the operation of the opposite magnetic pole to enter the coil member in the opposite magnetic pole in the second power feeding mode.

FIG. 8 is a schematic view showing the operation of the opposite magnetic pole to enter the magnetic gap of the opposite magnetic pole in the second power feeding mode according to the present invention.

FIG. 9 is a schematic view showing the operation of the opposite magnetic pole to enter the coil member in the opposite magnetic pole in the second power feeding mode.

FIG. 10 is a schematic view showing the operation of the opposite magnetic poles entering the magnetic gap in the opposite magnetic poles in the second power feeding mode according to the present invention.

【Symbol Description】

1 opposite magnetic group 100

10 magnetic column group 11 first magnetic piece

12 second magnetic member 15 magnetic gap

3 coil column group 300 static plate

30 first coil member 31 first electric body

32 longitudinal magnetic column 320 yoke section

33 electric coil 34 first power generation body

35 lateral magnetic rod 36 power generation coil

37 second power generating body 38 lateral magnetic rod

39 power coil 40 second coil member

41 second electric body 42 longitudinal magnetic column

420 yoke section 43 electric coil

44 third power generating body 45 lateral magnetic rod

46 power generating coil 47 fourth power generating body

48 lateral magnetic rod 49 power generation coil

500 shafts.

Detailed ways

The detailed description of the preferred embodiments of the present invention, and in the claims

The present invention is a co-magnetic composite magnetoelectric device, and the specific embodiments of the present invention and its components, as illustrated in the accompanying drawings, all relate to front and rear, left and right, top and bottom, upper and lower, and horizontal and The vertical reference is for convenience of description only and is 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.

The architecture of the preferred embodiment of the common magnetic hybrid magnetoelectric device of the present invention is as shown in FIG. 1. The common magnetic composite magnetoelectric device is composed of a pair of magnetic groups 1 and at least one coil group 3, wherein The opposite magnetic group 1 and each coil array 3 can be respectively defined as a rotor or a stator that can move relatively at a high speed;

As for the detailed construction of the co-magnetic composite magnetoelectric device of the present invention, referring to FIG. 1 and FIG. 2, in the preferred embodiment of the present invention, the opposite magnetic group 1 is used as a rotor, and the opposite magnetic group 1 includes mutual Two or more magnetic column groups 10 which are parallel and synchronously moved, when there are two or more magnetic column groups 10, are arranged at staggered intervals, and the opposite magnetic column groups 10 are equidistantly disposed with each other. The coil arrays 3, and the magnetic arrays 10 are respectively disposed on the relative radii of the movable disc 100, and the movable discs 100 are disposed through a shaft 500 to move the magnetic array 10 of the opposite magnetic group 1. The disc 100 can be rotated synchronously with the shaft 500, and each coil array 3 is disposed at a position of a static disc 300 relative to the magnetic array 10 of the movable disc 100 for pivoting the shaft 500 to the opposite magnetic group 1. The movable disc 100 can be synchronously rotated relative to the stationary disc 300;

The magnetic array 10 of the opposing magnetic group 1 is composed of at least one first magnetic member 11 and at least one second magnetic member 12 staggered in the moving direction, and each of the first and second magnetic members 11 and 12 The lengths of the first and second magnetic members 11, 12 are magnetized in parallel, and the adjacent first and second magnetic members 11, 12 or the second and second magnetic members 12, 11 respectively have a magnetic The gap 15 and the adjacent first and second magnetic members 11, 12 or the magnetic poles of the adjacent ends of the second and magnetic members 12 and 11 are adjacent to each other. For example, the end of the first magnetic member 11 is S pole. When the end of the adjacent second magnetic member 12 is the S pole, or the end of the first magnetic member 11 is the N pole, the end of the adjacent second magnetic member 12 is the N pole, and the opposite magnetic The first and second magnetic members 11 and 12 and the magnetic gap 15 of the column group 10 are in the same position, and the magnetic poles of the same end of the first and second magnetic members 11 and 12 of the magnetic array 10 are in the same polarity. When the end of the first magnetic member 11 of the magnetic array 10 is N pole, the same end portion of the first magnetic member 11 of the magnetic array 10 is N pole, or the second magnetic member 12 of the magnetic array 10 End is S pole With the end section 12 of the second magnetic member relative magnetic column group 10] also S pole;

In addition, the foregoing coil array group 3 is formed by at least one set of adjacent one first coil member 30 and one second coil member 40 spaced apart in the moving direction, wherein a group of adjacent first coil members 30 and The length of the two coil members 40 is less than or equal to the length of any one of the first magnetic member 11 or the second magnetic member 12 of the magnetic array 10 and its adjacent magnetic gap 15, and is greater than or equal to the first magnetic member 11 or the first The length of the two magnetic members 12, while the adjacent ends of the first coil member 30 and the second coil member 40 can abut each other, and the first coil member 30 is formed by a longitudinal first electric body 31 and a "ㄈ" type body formed by the first power generating body 34 and the second power generating body 37, wherein the first electric body 31 has a longitudinal magnetic column 32 and a set of electric coils 33 provided with longitudinal magnetic columns 32. The electric coil 33 is electrically connected to a power source for continuously feeding forward or reverse power, and each of the first and second power generating bodies 34 and 37 has a parallel motion of two ends of the longitudinal magnetic column 32. The transverse magnetic guiding rods 35 and 38 of the direction and the lateral magnetic guiding rods 35 and 38 respectively are respectively provided with an electrical connection and a negative The power generating coils 36, 39, and the two ends of the longitudinal magnetic conductive column 32 respectively have a yoke section 320 protruding from the lateral magnetic guiding rods 35, 38, so that the first electric body 31 of the first coiling member 30 can approach two The magnetic arrays 10 on the side are used to increase the magnetic permeability between each other. The second coil member 40 is a "ㄈ" type body composed of a longitudinal second electric body 41 and a lateral third power generating body 44 and a fourth power generating body 47, wherein the second electric body 41 has a The longitudinal magnetic conductive column 42 and a set of electric coils 43 provided with longitudinal magnetic conductive columns 42 are electrically connected to a power source for continuous reverse power feeding or forward power feeding, and the second coil member 40 is The power supply direction of the second motor body 41 is opposite to the power supply direction of the first motor body 31 of the first coil member 30 (that is, when the first motor body 31 is forwardly powered, the second motor body 41 is In the reverse direction, when the first electric body 31 is reversely powered, the second electric body 41 is forwardly powered, and each of the third and fourth electric power generating bodies 44 and 47 has a longitudinal magnetic connection. The lateral magnetic rods 45, 48 at both ends of the column 42 and in the parallel moving direction, and the lateral magnetic conducting rods 45, 48 are respectively sleeved with a power generating coil 46, 49 electrically connected to a load, and the longitudinal magnetic conducting column The two ends 42 respectively have a yoke section 420 protruding from the lateral magnetic bars 45, 48, so that the second electric body 4 of the second coil member 40 1 can access the magnetic array 10 on both sides to improve the mutual magnetic interaction;

Thereby, the group constitutes a common-mode hybrid magnetoelectric device that can share the gain of the magnetic group magnetic flux and improve the energy conversion efficiency.

As shown in FIG. 3 to FIG. 6 or FIG. 7 to FIG. 10, in the actual operation of the common-mode magnetic composite magnetoelectric device of the present invention, FIGS. 3 to 6 show that the first coil member 30 is positively energized, and The second coil member 40 reversely supplies the first power-on mode of operation, and FIG. 7 to FIG. 10 show that the first coil member 30 is reversely powered, and the second coil member 40 is forwardly powered. The operating state of electricity.

As shown in FIGS. 3-6, the first coil member 30 continues to positively supply the electric coil 33 of the first electric body 31, and the second coil member 40 continues to reverse the electric coil 43 of the second electric body 41. Electric, so that the magnetic flux directions of the first electric body 31 and the longitudinal magnetic columns 32, 42 of the second electric body 41 are different, and when the magnetic column group 10 of the opposite magnetic group 1 is opposite to the coil array 3 by the right Moving to the left, and when the first magnetic member 11 of the relative magnetic column group 10 having the N-pole magnetic pole at the entry end corresponds to any one of the adjacent first coil member 30 and the second coil member 40 of the coil array group 3, The electric coil 33 of the first electric body 31 of the first coil member 30 is magnetized in the forward direction, and the first electric body 31 is magnetized to form magnetic fluxes at both ends of the magnetic poles from the bottom to the north, and second. The electric coil 43 of the second electric body 41 of the coil member 40 is reversely energized, and the second electric body 41 is magnetized to form magnetic fluxes at both ends of the magnetic poles from the top to the bottom of the S pole to the N pole to form a clockwise direction. The internal magnetic flux circuit allows the first and second power generating bodies 3 to be further added to the internal magnetic flux of the first electric body 31 and the second electric body 41 in addition to the magnetic flux itself. 4, 37 and the magnetic fluxes of the third and fourth power generating bodies 44, 47, and the external magnetic currents of the first and second magnetic members 11, 12 of the magnetic row group 10 opposite to each other are also introduced, thereby greatly improving the internal magnetic flux. The magnetic flux of the circuit can reduce the input current of the electric coils 33 and 43 under the same requirement specifications, and the magnetic force can be increased if the input current is maintained, and the first and second magnetic members 11 of the relative magnetic array 10 are also allowed. The external magnetic current of 12 is randomly and rapidly magnetically guided, and the first and second coil members 30 and 40 are flowed through the internal magnetic flux circuit and recirculated to form a smooth magnetic flux circuit connected to the middle, and the middle portion The first and second power generating bodies 34, 37 of the coil member 30 and the third and fourth power generating bodies 44, 47 of the second coil member 40 generate a large amount of magnetic flux induction power generation, and let the first magnetic row group 10 on both sides The external magnetic lines of force formed by the outer magnetic lines of the magnetic members 11 and 12 and the first and second power generating bodies 34 and 37 of the first coil member 30 and the external magnetic lines of force formed by the third and fourth power generating bodies 44 and 47 of the second coil member 40 are Three groups of the same direction repelled, a group of anisotropic phases, due to the same direction of repulsive magnetic After the force and the magnetic resistance of the opposite phase attract each other, there is still more magnetic assistance in the same direction, so that the magnetic force assisting the moving direction can be obtained, and the opposite magnetic field is improved again. The speed of the group 1 and the magnetic fluxes of the third and fourth power generating bodies 44, 47 of the first and second power generating bodies 34, 37 and the second coil member 40 of the foregoing first coil member 30 are greatly increased, so that the opposite magnetic group The rotational speed of 1 is further improved, so that the cutting frequency and the number of cuts of the first and second power generating bodies 34, 37 and the third and fourth power generating bodies 44, 47 can be greatly improved, so that the power generation amount can be increased, and even more After the power generation amount of the coil member 30 and the second coil member 40 is increased, the magnetic fluxes of the first, second, third, and fourth power generating bodies 34, 37, 44, and 47 are again increased, and the magnetic assisting force can be further improved, so that the magnetic boosting force can be greatly improved. Its energy conversion rate achieves the purpose of generating electricity and electric power.

As shown in FIG. 7 to FIG. 10, the first coil member 30 continues to reversely supply the electric coil 33 of the first electric body 31, and the second coil member 40 continues to feed the electric coil 43 of the second electric body 41. The power is supplied so that the magnetic flux directions of the longitudinal magnetic poles 32, 42 of the first electric body 31 and the second electric body 41 are different, and when the magnetic column group 10 of the opposite magnetic group 1 is opposite to the coil array 3 Moving to the right and left, and when the first magnetic member 11 of the relative magnetic array 10 having the N poles of the input end corresponds to any one of the adjacent first coil members 30 and the second coil member 40 of the coil array group 3, Since the electric coil 33 of the first electric motor 31 of the first coil member 30 is reversely energized, the first electric body 31 is magnetized to form magnetic fluxes at both ends of the magnetic poles from the top to the bottom of the S pole to the N pole, and the second The electric coil 43 of the second electric body 41 of the coil member 40 is positively energized, and the second electric body 41 is magnetized to form magnetic fluxes at both ends of the magnetic pole from the bottom to the upper pole to form an inverse time. In the internal magnetic flux circuit of the direction, the internal magnetic flux of the first electric body 31 and the second electric body 41 can be further added with the first and second electric power in addition to the magnetic flux of the second electric body 41. The magnetic fluxes of the bodies 34, 37 and the third and fourth power generating bodies 44, 47, and the external magnetic fluxes of the first and second magnetic members 11, 12 of the magnetic column group 10 opposite to each other are also introduced, thereby greatly improving the internal magnetic flux. The magnetic flux of the circuit can reduce the input current of the electric coils 33 and 43 under the same requirement specifications, and the magnetic force can be increased if the input current is maintained, and the first and second magnetic members 11 of the relative magnetic array 10 are also allowed. The external magnetic current of 12 is randomly and rapidly magnetically guided, and the first and second coil members 30 and 40 are flowed through the internal magnetic flux circuit and recirculated to form a smooth magnetic flux circuit connected to the middle, and the middle portion The first and second power generating bodies 34, 37 of the coil member 30 and the third and fourth power generating bodies 44, 47 of the second coil member 40 generate a large amount of magnetic flux induction power generation, and let the first magnetic row group 10 on both sides The external magnetic lines of force formed by the outer magnetic lines of the magnetic members 11 and 12 and the first and second power generating bodies 34 and 37 of the first coil member 30 and the external magnetic lines of force formed by the third and fourth power generating bodies 44 and 47 of the second coil member 40 are Three groups of the same direction repelled, a group of anisotropic phases, due to the same direction of repulsive magnetic After the magnetic resistance of the opposite phase attracts the magnetic resistance, there is still more magnetic assistance in the same direction, so that the magnetic force assisting the moving direction can be obtained, and the opposite magnetic field is improved again. The speed of the group 1 and the magnetic fluxes of the third and fourth power generating bodies 44, 47 of the first and second power generating bodies 34, 37 and the second coil member 40 of the foregoing first coil member 30 are greatly increased, so that the opposite magnetic group The rotational speed of 1 is further improved, so that the cutting frequency and the number of cuts of the first and second power generating bodies 34, 37 and the third and fourth power generating bodies 44, 47 can be greatly improved, so that the power generation amount can be increased, and even more After the power generation amount of the coil member 30 and the second coil member 40 is increased, the magnetic fluxes of the first, second, third, and fourth power generating bodies 34, 37, 44, and 47 are multiplied, and the magnetic assisting force can be increased again, so that the magnetic flux can be greatly increased. Improve its energy conversion rate to achieve the purpose of power generation and electric sharing.

And the longitudinal magnetic poles 32, 42 of the first and second coil members 30, 40 have the yoke sections 320, 420 close to the magnetic array 10, so that the magnetic distance is shortened, and a better magnetic permeability effect can be produced and reduced. Magnetic interference, which increases the number of flux common magnets, can effectively increase the operating speed.

The lateral magnetic rods (35, 38, 45, 48) of the first and second coil members 30, 40 can be separated from the magnetic array 10 to lengthen the magnetic distance, and more magnetic lines can be effectively cut. Increasing the number of magnetic line cuts can effectively increase the amount of electricity generated.

As can be seen from the above description, the present invention can not only continuously achieve the effect of adding and multiplying the magnetic assist force, but also increase the rotational speed while using the magnetic flux control of the relative magnetic array 10 and the first electric body 31 and the second electric body 41. To the design, an effective magnetic flow management is formed, and at the same time, the magnetic flux of the whole magnetic flux and the magnetic flux of the first and second coil members 30 and 40 can be improved to form a small input and a large output, and when the magnetic assist is improved, The rotation speed can be further increased, and the cutting frequency and the number of cuttings can be increased, so that the overall power generation amount is greatly increased, thereby improving the energy conversion efficiency, and even more, the purpose of self-power generation can be achieved.

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. A common magnetic composite magnetoelectric device, which is composed of a pair of magnetic groups and at least one coil group, wherein the opposite magnetic group and each coil group are respectively defined as relatively movable rotors Or stator;

   The opposite magnetic group includes two or more magnetic column groups which are parallel to each other and synchronously move, wherein each magnetic column group is at least one first magnetic member which is staggered in the moving direction and is equal in length. And at least one second magnetic member, wherein each of the first and second magnetic members is magnetized in a parallel movement direction, and the adjacent first and second magnetic members or the second and the magnetic members respectively have a magnetic gap, and The magnetic poles of adjacent first and second magnetic members or the adjacent ends of the second magnetic member are adjacent to the same pole, and are opposite to each other with respect to the first and second magnetic members and the magnetic gap of the magnetic array; The magnetic poles of the same end of the first and second magnetic members of the magnetic group are opposite poles;

   Further, the coil arrays are equally spaced between the relative magnetic array groups, and each coil array is formed by at least one adjacent one of the first coil members and one second coil member spaced apart in the moving direction, one of which is The length of the adjacent first coil member and the second coil member is less than or equal to the length of any one of the first magnetic member or the second magnetic member of the magnetic array group and its adjacent magnetic gap, and is greater than or equal to the first a length of the magnetic member or the second magnetic member, and each of the first coil members is a "ㄈ" type body composed of a longitudinal first electric body and a lateral first power generating body and a second power generating body, wherein the first coil body The electric body has a longitudinal magnetic column and a set of electric coils with longitudinal magnetic columns. The electric coil of the first electric body is electrically connected to a power source, and the power supply connected to the first electric body is continuous to the first The electric coil of the electric body is forward-powered or reverse-powered, and each of the first and second power generating bodies respectively has a transverse magnetic field connected to both ends of the longitudinal magnetic column of the first electric body and parallel to the moving direction. a rod, and a transverse magnetic rod of each of the first and second power generating bodies A power generating coil connected to a load is disposed, and each of the second coil members is a "ㄈ" type body formed by a longitudinal second electric body and a lateral third power generating body and a fourth power generating body. The second electric body has a longitudinal magnetic column and a set of electric coils with a longitudinal magnetic column. The electric coil of the second electric body is electrically connected to a power source, and the power supply connected to the second electric body continuously The electric coil of the second electric body is reversely fed or forwardly fed, and the feeding direction of the second electric body of the second coil member is opposite to the feeding direction of the first electric body of the first coil member In the power supply, each of the third and fourth power generating bodies respectively has a transverse magnetic guiding rod connected to both ends of the longitudinal magnetic conductive column and parallel movement direction, and the lateral magnetic guiding rods of each of the third and fourth power generating bodies are separately sleeved. A power generating coil connected to a load is provided.
2. The common magnetic composite magnetoelectric device according to claim 1, wherein the opposite magnetic group is used as a rotor, and each of the magnetic groups of the opposite magnetic group is respectively disposed on a moving plate, and another shaft is disposed. Each of the moving disks, the moving plate of the magnetic group of the opposite magnetic group rotates synchronously with the shaft, and the first coil member and the second coil member of each coil group are disposed on a static disk, and the first coil members are respectively The second coil member and the magnetic column group are in a position opposite to each other.
3. The common magnetic hybrid magnetoelectric device according to claim 1, wherein each of the first coil members and the adjacent ends of the second coil member of the coil array group abut each other.
4. The common magnetic hybrid magnetoelectric device according to claim 1, wherein each of the longitudinal magnetic columns of the first and second coil members of the coil array has a yoke protruding from the lateral magnetic rod. segment.