TWM568556U - Concentric common electromagnetic power device - Google Patents

Abstract

The present invention relates to a concentric common electromagnetic device comprising at least two magnetic columns, at least one parallel, and a plurality of inductive switch groups disposed between the opposing magnetic groups, and the magnetic column group The first and second magnetic members are magnetized in a moving direction and have a magnetic gap, and the other coil group is composed of at least one coil member, each of the coil members has a magnetizer, and the length of the magnetizer is a magnetic member is added with a length of a magnetic gap, and the conductive magnet is provided with a power supply coil connecting the power supply and an inductor connected to the load on the side away from the end of the corresponding moving direction, and the sensing switch group can control the power supply of the coil group Whether the coil is powered or not, thereby achieving the purpose of increasing the rotational speed throughout the entire process, further improving the output power and generating power, thereby improving the energy conversion efficiency and fully utilizing the structure.

Description

Concentric electromagnetic device

This creation belongs to the technical field of a magnetoelectric device, specifically a concentric common electromagnetic device with both power generation and electric action, so as to achieve the purpose of full acceleration, to increase output power, and increase power generation efficiency, thereby improving energy Conversion efficiency.

Generally, whether the motor or the generator is usually operated by a magnetoelectric device, the magnetic group and the coil group which are two relatively movable bodies are respectively composed of a rotor and a stator, and the motor is taken as an example. The intermittent power supply is made into an electromagnet, and a magnetic force that repels and attracts relative to the magnetic group is generated, thereby driving the rotor to rotate at a high speed. As for the generator, the rotor is driven by an external force to rotate at a high speed, so that the coil group is generated by the magnetic flux cutting. However, in practical applications, there are some problems, such as when applied to the motor, affected by the coil group and the magnetic group configuration. The coil group is still cut by the rotating magnetic group, and the induced electromotive force is generated, so that the coil group needs a large input power to drive enough to cause unnecessary energy loss.

Another example is when applied to a generator, when the coil assembly is connected to the load to generate a current, the coil group is induced to magnetize into an electromagnet, and the magnetic stress phenomenon in the opposite motion direction is generated at both ends of the coil assembly and the magnetic group, and the magnetic stress is The direction of motion is opposite Magnetoresistance, so there will be kinetic energy loss caused by proliferative magnetoresistance under load. Therefore, the operation rate of traditional power generation equipment is difficult to increase, which seriously affects the frequency of cutting, so the power generation efficiency is low, and its energy conversion rate is low. In view of this, this The creators have in-depth discussions on the problems faced by the aforementioned existing magnetoelectric devices, and actively pursued solutions through years of research and development experience in related industries. After continuous efforts in research and trials, they finally succeeded in developing a concentric electromagnetic motor. The device can overcome the problem of low energy conversion rate and structural utilization of the existing magnetoelectric device.

Therefore, the main purpose of this creation is to provide a concentric common electromagnetic device, which can simultaneously have both an electric mode and a power generation mode, so that the structure can be fully utilized, further achieving the purpose of self-power generation, and self-sufficiency in energy.

In addition, the second main objective of the present invention is to provide a concentric common electromagnetic device capable of increasing magnetic assist and inertial force, thereby reducing the generation of magnetic resistance and thereby increasing the relative rotational speed.

Moreover, another main purpose of the present invention is to provide a concentric common electromagnetic device with an electric mode, which can reduce the induced electromotive force, achieve the purpose of inputting small driving power, and improve its output power, thereby further improving its energy conversion efficiency. .

Furthermore, another main object of the present invention is to provide a concentric common electromagnetic device with a power generation mode, which can increase the number and angle of cutting of magnetic lines of force, improve the utilization of magnetic force, and improve the performance of operation.

Based on this, this creation is mainly through the following technical means. The foregoing objects and effects thereof are composed of two or more magnetic arrays, one or more coil arrays, and at least one inductive switch group, wherein a parallel row of relatively parallel magnetic columns is provided. a group of coils, wherein the groups of magnetic groups and the groups of coils can be respectively defined as rotors or stators that can move relative to each other; and the groups of magnetic columns are made of permanent magnets and are arranged in the direction of motion. The at least one first magnetic member and the at least one second magnetic member are formed, and the lengths of the first and second magnetic members are equal, and the first and second magnetic members are magnetized in a parallel motion direction and adjacent The opposite ends of the first and second magnetic members or the second and the magnetic members are adjacent to the same pole, and a magnetic gap is respectively disposed between the adjacent first and second magnetic members or the second and the magnetic members. The ratio of the width of the gap to the length of the first and second magnetic members is 0.8 to 1.2:2, and the first, the second magnetic members and the magnetic gap of the magnetic array are opposite, and the first of the relative magnetic arrays is The opposite magnetic poles of the two magnetic members are in the same pole opposite shape; More than one coil member, each of the coil members has a magnet extending in a parallel movement direction, and the length of the magnetizer is 2.8~3.2:2 with respect to the length of the first and second magnetic members, and the guide The magnet is provided with a power supply coil connecting the power source and an inductor connected to the load on the exiting end side of the corresponding moving direction, and the length of the power feeding coil and the inductor coil and the length of the first and second magnetic members are 0.6~1. : 2, and wherein the distance between the opposite ends of the electric coil and the inductor coil corresponds to the length of both ends of the first magnetic member or the second magnetic member; wherein the sensing switch group is composed of at least one path switch and at least one circuit breaker The at least one path sensing element and the at least one circuit breaking sensing element are configured, wherein the path switch is disposed in the relative movement direction of the first and second magnetic members The end end portion, and the circuit breaker is disposed at a position away from the end portion of the first and second magnetic members, wherein the path sensing element is disposed at a direction away from the end of the feeding coil, and the breaking sensor element is divided into Provided in the opposite direction of movement of the power feeding coil into the end portion; and when the path switch of the first and second magnetic members of the magnetic column group corresponds to the path sensing element of the power feeding coil, the power supply can be supplied to the power feeding coil by the power source, and when the first and second When the disconnecting switch of the magnetic member corresponds to the disconnecting sensing element of the power feeding coil, the power supplied from the power supply to the power feeding coil is temporarily interrupted to form an intermittent power supply in the electric mode.

In summary, the creation of the above-mentioned technical means enables the concentric common electromagnetic device of the present invention to utilize the magnetic poles of the first and second magnetic members of the magnetic poles at both ends of the magnets of the coil member and the adjacent magnetic arrays. The sucking front magnetic assist or the back magnetic repulsion with the same polarity repels to form a double magnetic assist effect, and the coil component of the coil array is magnetized without excitation and no power generation, so that By the inertial motion of the magnetic array, the acceleration is continued without being blocked, so that the creation can increase the rotational speed throughout the whole process, and the output power and the power can be further improved; and in the electric mode, since the work is not generating electricity The area can reduce the induced electromotive force to achieve the purpose of inputting small driving power and increasing its output power. In the power generation mode, since it works in the power generation area, it can increase the number and angle of cutting of the magnetic lines, and improve the magnetic utilization rate. Further improve its energy conversion efficiency; and even more so, because this creation can have both electric and power generation modes, the structure is fully utilized. Step up to the purpose of self-generation, can further increase their added value, and can improve its economic efficiency.

In order to enable the review board to further understand the composition, characteristics and other purposes of the creation, the following are some of the preferred embodiments of the creation, together with the schema. The detailed description will be followed by the implementation of the technical field.

(10) ‧‧‧Magnetic group

(100)‧‧‧‧

(11)‧‧‧First magnetic parts

(12)‧‧‧Second magnetic parts

(15)‧‧‧ Magnetic gap

(30)‧‧‧ coil group

(300)‧‧‧Dry

(31)‧‧‧Circle parts

(32)‧‧‧ Magnets

(36)‧‧‧Power coil

(38)‧‧‧Inductance coil

(40)‧‧‧Induction switch set

(41)‧‧‧Path switch

(42) ‧‧‧Disconnect switch

(45)‧‧‧Path sensing elements

(46) ‧‧‧Disconnection sensing elements

(500)‧‧‧ shaft

Fig. 1 is a schematic view showing the structure of a preferred embodiment of the present concentric coaxial electromagnetic device.

Fig. 2 is a three-dimensional exploded view of the concentric electromagnetic electric device of the present invention in practical application.

Figures 3 and 4 are schematic views of the operation of the preferred embodiment of the present concentric coaxial electromagnetic device in the start-up electric mode.

Fig. 5 and Fig. 6 are schematic diagrams showing the operation of the preferred embodiment of the concentric electromagnetic device of the present invention in the stop of the electric mode.

Fig. 7 is a schematic view showing the operation of the preferred embodiment of the present concentric coaxial electromagnetic device for simultaneously stopping the electric mode and the power generation mode.

Figures 8 and 9 are diagrams showing the action of the preferred embodiment of the present concentric coaxial electromagnetic device to activate the electric mode under different magnetic poles.

Fig. 10 and Fig. 11 are diagrams showing the action of the preferred embodiment of the present concentric coaxial electromagnetic device for stopping the electric mode under different magnetic poles.

Fig. 12 is a schematic view showing the operation of the preferred embodiment of the present concentric coaxial electromagnetic device for simultaneously stopping the electric mode and the power generation mode under different magnetic poles.

Figure 13 is a block diagram showing another preferred embodiment of the present concentric coaxial electromagnetic device.

Figures 14 and 15 are schematic views showing the action of another preferred embodiment of the present concentric coaxial electromagnetic device in starting the electric mode.

Figure 16: Another preferred embodiment of the present concentric coaxial electromagnetic device is stopped. Schematic diagram of the action of the electric mode.

Figures 17 and 18 are schematic views showing the operation of simultaneously stopping the electric mode and the power generating mode in another preferred embodiment of the present concentric coaxial electromagnetic device.

19 and 20 are schematic views showing the action of starting the electric mode under different magnetic poles in another preferred embodiment of the present concentric coaxial electromagnetic device.

Fig. 21 is a schematic view showing the action of stopping the electric mode under different magnetic poles in another preferred embodiment of the present concentric coaxial electromagnetic device.

Fig. 22 is a schematic view showing the operation of simultaneously stopping the electric mode and the power generation mode under different magnetic poles in another preferred embodiment of the present concentric coaxial electromagnetic device.

Fig. 23 is a schematic view showing the structure of a disc matrix embodiment in the present concentric coaxial electromagnetic device.

Figure 24 is a perspective exploded view of a disc matrix embodiment of the present concentric coaxial electromagnetic device.

Figure 25: Schematic diagram of the architecture of the ring matrix in the present concentric coaxial electromagnetic device.

Figure 26 is a perspective exploded view of a ring matrix embodiment of the present concentric coaxial electromagnetic device.

This creation is a concentric common electromagnetic device, with reference to the specific embodiment of the creation and its components, as illustrated in the accompanying drawings, all references to front and rear, left and right, top and bottom, upper and lower, and horizontal and vertical. , for convenience of description only, does not limit the creation, nor restricts its components to any position or space. The drawings and the dimensions specified in the instructions, if you can leave the application without this creation Within the scope of the patent, changes are made in accordance with the design and needs of the specific embodiments of the present invention.

The composition of the concentric common electromagnetic device of the present invention is as shown in FIG. 1 , which is composed of two or more magnetic columns (10), one or more coil rows (30) and at least one. The inductive switch group (40) is configured, wherein the coil array group (30) is disposed between the opposite magnetic column groups (10), and each of the magnetic column groups (10) and each of the coil row groups (30) are parallel to each other. Further, the sets of magnetic columns (10) and the sets of coils (30) can be defined as a rotor or a stator, respectively, such that the sets of magnetic groups (10) can be synchronously linear with respect to the set of coils (30) or Rotating motion; as for the detailed configuration of the preferred embodiment of the present concentric electromagnetic device, please refer to Figures 1 and 2, the magnetic column group (10) and the coil group (30) are respectively arranged in a motion a relative radius of the disk (100) and a static disk (300), and is provided for a shaft (500), and wherein the moving plate (100) of the magnetic array (10) is rotatable synchronously with the shaft (500), and The static disk (300) of the coil array (30) is relatively pivoted with the shaft (500), so that the magnetic array (10) can synchronously drive the shaft (500) to rotate in the electric mode, and in the power generation mode The shaft (500) can drive the magnetic array (10) The magnetic array (10) is formed by a permanent magnet and at least one first magnetic member (11) and at least one second magnetic member (12) are arranged at intervals in the moving direction. The lengths of the first and second magnetic members (11, 12) are equal, and the first and second magnetic members (11, 12) are magnetized in a parallel motion direction, and the adjacent first and second magnetic members are adjacent. (11, 12) or the opposite ends of the second and first magnetic members (12, 11) are adjacent to the same pole [for example, when the first magnetic member (11) is N pole, then the adjacent second magnetic member (12) is also When the N pole, or the first magnetic member (11) is the S pole, The adjacent second magnetic member (12) is an S pole], and the adjacent first and second magnetic members (11, 12) or the second and the magnetic members (12, 11) respectively have a magnetic gap (15) The ratio of the width of the magnetic gap (15) to the length of the first and second magnetic members (11, 12) is 0.8 to 1.2:2, and the preferred embodiment of the present invention is 1:2, and the magnetic group is opposite ( 10) The first and second magnetic members (11, 12) and the magnetic gap (15) are opposite, and the relative magnetic poles of the first and second magnetic members (11, 12) of the magnetic array (10) are in the same polarity. And the coil array (30) is composed of one or more coil members (31) disposed on the static disk (300), each of the coil members (31) having a guide extending in a parallel motion direction. a magnet (32), and a length ratio of the length of the magnetizer (32) to the first and second magnetic members (11, 12) is 2.8 to 3.2:2, and the preferred embodiment of the present invention is 3:2, and wherein The conductive magnet (32) is provided with a power feeding coil (36) connected to the power source and an inductor coil (38) connected to the load, and the power feeding coil (36) and the inductor coil (38). The length of the first and second magnetic members (11, 12) is 0.6~1 2, the preferred embodiment of the present invention is 1:2, and wherein the distance between the opposite ends of the electric coil (36) and the inductor coil (38) corresponds to the length of both ends of the first and second magnetic members (11, 12); The inductive switch group (40) is composed of at least one path switch (41), at least one circuit breaker (42), at least one path sensing element (45) and at least one circuit breaking sensing element (46), as shown in FIG. As shown, the path switch (41) of the inductive switch group (40) is disposed in the magnetic column group (10), and the first and second magnetic members (11, 12) enter the end portion with respect to the moving direction, and the disconnect switch (42) The first and second magnetic members (11, 12) are respectively disposed in the magnetic array (10) away from the end portion in the relative movement direction, and the passage sensing element (45) of the inductive switch group (40) is disposed on the coil. The power feeding coils (36) of the coil members (31) in the column group (30) are separated from the end portions with respect to the moving direction, and the circuit breaking sensing members (46) are respectively disposed in the coil group (30) for each of the coil members (31). The feeding coil (36) enters the end portion with respect to the moving direction, and is used for the path switch of the first and second magnetic members (11, 12) when the magnetic column group (10) moves relative to the coil group (30). (41) When the coil member (31) is provided with the path sensing element (45) of the power supply coil (36) away from the terminal [as shown in Figures 3 and 8], the power supply can be supplied from the power supply to the power supply coil (36) to make the coil member (31) The magnetization generates a magnetic assisting effect, and the disconnecting switch (42) when the first and second magnetic members (11, 12) are at the exit end corresponds to the disconnecting sensing element (46) of the coiling member (31) of the feeding coil (36). When [as shown in Figures 5 and 10], the power supply to the power supply coil (36) is temporarily interrupted to form an intermittent power supply in the electric mode, and the inductive coil (38) connected to the load can be subjected to magnetic line cutting due to the penetration. a magnetic gap (15), so that the inductance coil (38) of the coil member (31) can generate electricity by the induced electromotive force; thereby, the group constitutes an electric mode and a power generation mode , And can accelerate the full electromagnetic power of the apparatus by the concentric co.

As for the preferred embodiment of the present concentric coaxial electromagnetic device, when it is actually actuated, as shown in Figures 3 to 12, when the shaft (500) drives the magnetic array (10) on the moving plate (100) relatively static. The coil array (30) on the disk (300) moves at a high speed, and enters the sensing switch group on the end of the first magnetic member (11) or the second magnetic member (12) of the magnetic array (10) (40) The path switch (41) corresponds to the coil array (30) coil member (31) when the power coil (36) is away from the path sensing element (45) [as shown in Figures 3 and 8], the coil group (30) The power feeding coil (36) on each coil member (31) is in communication with a power source, such that the power feeding coil (36) is magnetized to be the same magnetic pole as the first magnetic member (11), for example, the third portion The power supply coil (36) of the figure is opposite to the S pole, the power supply coil (36) of Fig. 8 is N pole opposite, and the inductance coil (38) on each coil component (31) of the coil array (30). The magnetic flux is cut in the magnetic gap (15) to generate electricity and connected to the load, so that the inductor (38) is magnetized to the same magnetic pole as the first magnetic member (11). For example, the inductance coil (38) of FIG. 3 is N. In the opposite direction, the inductor coil (38) of Fig. 8 is S pole opposite, and since the magnetizer (32) of the coil member (31) extends to the adjacent second magnetic member (12) [as shown in Fig. 3] Or the adjacent ends of the first magnetic member (11) [as shown in Fig. 8], the magnetic poles are also extended to the adjacent ends, and the magnetic poles (32) of the coil member (31) are magnetically poled at the other end. The magnetic poles of the adjacent second magnetic member (12) [as shown in FIG. 3] or the first magnetic member (11) [as shown in FIG. 8] are opposite poles, for example, the coil member of FIG. The other end N pole magnetic pole of (31) corresponds to the N pole magnetic pole of the adjacent second magnetic member (12), and the other end S pole magnetic pole of the coil member (31) of Fig. 8 corresponds to the adjacent first magnetic member (11) The S pole magnetic pole enables the coil member (31) of the coil row group (30) to be opposite to the magnetic column group (10) The first and second magnetic members (11, 12) generate a magnetic repulsive force after repulsion [as shown in Figures 4 and 9], which can increase the output power and increase the rotational speed; and the first in the magnetic array (10) The relative movement direction of the magnetic member (11) or the second magnetic member (12) leaves the inductive switch group on the end (40). The disconnect switch (42) corresponds to the coil array (30) coil member (31) to the electric coil (36) When entering the open circuit sensing element (46) [as shown in Figures 5 and 10], the power supply coil (36) on each coil component (31) of the coil array (30) is disconnected from the power supply, avoiding power supply. The coil (36) will cut the induced electromotive force due to the magnetic flux (15) magnetic field lines, and the power feeding coil (36) will not be magnetized without magnetic stress, and the coil members (31) of the coil group (30) are on the coil member (31). The connected inductor (38) is still connected Inductive magnetization caused by magnetic flux (15) magnetic line cutting power generation, so that the inductor coil (38) is induced relative to the second magnetic member (12) [as shown in Fig. 6] or the first magnetic member (11) [such as the eleventh The figure shows a dissimilar magnetic pole. For example, the inductive coil (38) of Fig. 6 has an S pole at the exit end and an N pole at the entry end, and the exit end of the inductor coil (38) in Fig. 11 is an N pole and enters The end is an S pole, and the magnetic poles of the magnetic poles (32) of the coil member (31) are close to the magnetic poles of the first and second magnetic members (11, 12) of the magnetic array (10) before the opposite poles are attracted. Pulling magnetic assistance [as shown in Figures 6 and 11] can further increase the rotational speed and increase the cutting frequency; and the second magnetic member (12) or the first magnetic member adjacent to the magnetic array (10) ( 11) When it is completely overlapped with the coil component (31) of the coil array (30) (as shown in Figs. 7 and 12), the coil (31) is connected to the load inductor (38). Located in the non-power generation area, no magnetic line cutting power generation, so that the inductor coil (38) is not magnetized due to the power generation load. At this time, the coil member (31) has no induced polarity at the two ends of the magnet (32), and the magnetic column group (10) can be in the absence. In the case of magnetoresistance hyperactive damage The inertial motion continues to operate, improving its energy conversion efficiency.

Still another preferred embodiment of the present invention is as shown in Fig. 13, which is for energizing the power supply coil (36) and the inductor on the magnetizer (32) of the coil assembly (31) of the coil assembly (30). The length of the coil (38) is proportional to the length of the first and second magnetic members (11, 12) of 0.75:2. When the preferred embodiment is actually actuated, as shown in Figures 14 to 22, when the magnetic column group (10) moves at a high speed relative to the coil array (30), and is first in the magnetic column group (10) The inductive switch group (40) of the magnetic member (11) or the second magnetic member (12) is in the opposite direction of movement (40). The path switch (41) corresponds to the coil train (30) coil member (31) feed coil (36) When leaving the channel sensing element (45) [as shown in Figures 14 and 19], the coil column group (30) The power feeding coil (36) on each of the coil members (31) is in communication with a power source, so that the power feeding coil (36) is magnetized to a magnetic member opposite to the first magnetic member (11), for example, the power feeding coil of FIG. (36) is opposite to the S pole, the power supply coil (36) of Fig. 19 is N pole opposite, and the inductance coil (38) and the magnetic gap on the coil member (31) of the coil array (30) are 15) The medium magnetic force line cuts power generation and connects the load, so that the inductor coil (38) is magnetized to be the same magnetic pole as the first magnetic member (11), for example, the inductor coil (38) of Fig. 14 is N pole opposite, The inductor coil (38) of Fig. 19 is S pole opposite, and since the magnetizer (32) of the coil member (31) extends to the adjacent second magnetic member (12) [as shown in Fig. 14] or the first magnetic The adjacent end of the piece (11) [as shown in Fig. 19], the magnetic pole is also extended to the adjacent end portion, and the magnetic pole of the other end of the magnetizer (32) of the coil member (31) is opposite to the phase. The magnetic poles of the adjacent second magnetic member (12) [as shown in Fig. 14] or the first magnetic member (11) [as shown in Fig. 19] are opposite poles, for example, the coil member (31) of Fig. 14. The other end N pole is corresponding to the N pole of the adjacent second magnetic member (12) The other end S pole magnetic pole of the coil member (31) of Fig. 19 corresponds to the S pole magnetic pole of the adjacent first magnetic member (11), so that the coil members (31) of the coil array group (30) can be opposite magnetic columns. The first and second magnetic members (11, 12) of the group (10) generate a magnetic repulsive force after the repulsive [as shown in Figs. 15 and 20], which can be used to increase the output power and increase the rotational speed; (10) The first magnetic member (11) or the second magnetic member (12) has a relative movement direction away from the inductive switch group (40) of the disconnecting switch (42) corresponding to the coil array (30) coil member (31) When the power supply coil (36) enters the open-circuit sensing element (46) of the terminal [as shown in Figures 16 and 21], the power supply coil (36) and the power supply on each coil member (31) of the coil array (30) In the form of a broken path, the avoiding power supply coil (36) will cut the induced electromotive force due to the magnetic flux, and The power feeding coil (36) is not magnetized and has no magnetic stress, and the inductive coil (38) connected to the load on each coil member (31) of the coil array (30) is still magnetized by magnetic line cutting to induce magnetization, so that the inductor The coil (38) is inductively opposite to the second magnetic member (12) [as shown in Fig. 16] or the first magnetic member (11) [as shown in Fig. 21] is a different magnetic pole, such as the inductance of Fig. 16. The exit end of the coil (38) is an S pole, and the entrance end is an N pole, and the exit end of the inductor coil (38) of FIG. 21 is an N pole, and the entry end is an S pole, and the magnet of the coil component (31) is made. (32) The magnetic poles of the magnetic poles at both ends and the first and second magnetic members (11, 12) of the magnetic array (10) are magnetically assisted before the opposite poles are attracted [as shown in Figures 16 and 21]. Further increasing the rotational speed and increasing the cutting frequency; and the second magnetic member (12) or the first magnetic member (11) adjacent to the magnetic array (10) is completely coupled with the coil member of the coil array (30) (31) When the inductive coils (38) overlap [as shown in Figures 17, 18 and 22], the inductive coil (38) connected to the load on the coil member (31) is located in the non-power generating region, and no magnetic line cutting power is generated, so that the inductor coil (38) No cause The power generation load is magnetized. At this time, the coil member (31) has no induced polarity at the two ends of the magnetizer (32), and the magnetic column group (10) can continue to operate by inertial motion without the magnetoresistance and dynamic damage, thereby improving its energy. Conversion efficiency.

Furthermore, another preferred embodiment of the present invention is shown in Figures 23 and 24, which is a concentric common electromagnetic device of a disc matrix, which is provided by at least three sub-distributed disks. The magnetic column group (10) of (100) and the coil row group (30) of at least two of the static disk (300) are alternately arranged, and the creation system has three sets of magnetic columns (10) and two. The group coil group (30) is a main embodiment, and the magnetic column group (10) of each of the moving disks (100) and the coil row group (30) of each of the static disks (300) have a coaxial radius, and further Each of the magnetic array (10) of the moving disk (100) and each The static disks (300) of the coil array (30) can be respectively defined as a rotor or a stator for synchronously moving relative to each other, and the position of the coil member (31) of each of the opposing coil rows (30) is corresponding to the magnetic column. The first and second magnetic members (11, 12) of the group (10) may be arranged in a misalignment so that the magnetic arrays (10) can be pushed by the continuous magnetic assisting force, and the opposing pairs of coils (30) The first and second magnetic members (11, 12) of the coil member (31) corresponding to the magnetic array (10) may also be aligned, so that the magnetic array (10) can improve the magnetic assistance at the same time point.

Moreover, as shown in Figures 25 and 26, a further preferred embodiment of the present invention is a concentric coaxial electromagnetic device of a ring matrix, which is composed of at least two magnetic columns (10). The movable disk (100) and at least one static disk (300) having a coil array (30), and the present invention uses two moving disks (100) and one static disk (300) as main embodiments. And the static disk (300) of each coil array (30) is disposed between the movable disks (100) of the two magnetic column groups (10), and each of the movable disks (100) is provided with at least two coaxial and different The phase of the radius is combined with the magnetic column group (10), and each of the static disks (300) is provided with at least two coaxial and different radii of phase coil groups (30), and coil groups of different radii (30) Corresponding to the magnetic column group (10) of the same radius, and further, the first magnetic members (11A, 11B) or the second magnetic members of the phase magnetic groups (10A, 10B) of the movable disk (100) Both ends of 12A, 12B) are correspondingly converged toward the axis, and both ends of the coil members (31A, 31B) of the phase coil group (30A, 30B) of each of the static disks (300) are also axially oriented. Corresponding to the convergence, and the position of the coil member (31) of each of the phase coil groups (30) corresponds to each The first and second magnetic members (11, 12) of the magnetic array (10) may be arranged in a misaligned manner, so that the magnetic arrays (10) can be pushed by the continuous magnetic assisting force, and the other combined coil groups The position of the coil member (31) of (30) corresponds to the first and second magnetic properties of each phase and magnetic column group (10) The pieces (11, 12) may also be arranged in alignment such that the magnetic arrays (10) can increase the magnetic assistance at the same point in time.

According to the above description, since the concentric common electromagnetic device of the present invention can utilize the first and second magnetic members (11, 12) of the magnetic poles and the magnetic column group (10) at both ends of the magnetizer (32) of the coil member (31). The magnetic poles that are close to each other are magnetically assisted or magnetically assisted after the same poles are repulsive, forming a double magnetic assistance effect, and the coil component (31) of the coil array (30) is in the power supply coil ( 36) In the state where the induction coil (38) is not magnetized, the magnetic array (10) can continue to operate according to the inertial motion in the case of no magnetoresistance dynamic loss, so that the creation can achieve the purpose of increasing the rotation speed throughout the process. The moving speed can be further increased; and when the power feeding coil (36) is in the electric mode of the non-power generating area, it can reduce the induced electromotive force, and can achieve the purpose of inputting small driving power and improving the output power thereof, and the inductor coil (38) In the power generation mode of the magnetic gap power generation zone, it can increase the number and angle of cutting of magnetic lines of force, improve the utilization rate of magnetic force, and further improve the energy conversion efficiency; even more, the creation can simultaneously have both the electric mode and the power generation mode, so that the structure is sufficient. Be exploited, Further reach the purpose of self-power generation.

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

Claims (9)

A concentric common electromagnetic device consisting of two or more magnetic arrays, one or more coil arrays and at least one inductive switch group, wherein a parallel parallel magnetic column group is provided with a parallel a coil array group, wherein the magnetic column groups and the coil array groups are respectively defined as rotors or stators that can be synchronously moved relative to each other; and the magnetic arrays are at least one first magnetic field arranged at intervals along a moving direction. And the at least one second magnetic member is formed, and the lengths of the first and second magnetic members are equal, and the first and second magnetic members are magnetized in a parallel motion direction, and adjacent first and second magnetic members The opposite ends of the second or a magnetic member are adjacent to the same pole, and the adjacent first and second magnetic members or the second and the magnetic members respectively have a magnetic gap, and the width of the magnetic gap is first The length ratio of the two magnetic members is 0.8~1.2:2, and the first magnetic pole and the magnetic gap of the magnetic array are opposite, and the relative magnetic poles of the first and second magnetic members of the magnetic group are opposite. Corresponding to the same pole; the coil group described above is composed of one or more a coil member, each of the coil members has a magnet extending in a parallel movement direction, and the length of the magnetizer is 2.8~3.2:2 with respect to the length of the first and second magnetic members, and wherein the magnetizer corresponds to a power supply coil connecting the power source and an inductor coil connecting the load are disposed on the side away from the end of the movement direction, and the length of the power supply coil and the inductor coil and the length of the first and second magnetic members are 0.6~1:2. Wherein the distance between the opposite ends of the power supply coil and the induction coil corresponds to the length of both ends of the first magnetic member or the second magnetic member; The sensing switch set is composed of at least one path switch, at least one circuit breaker, at least one path sensing element, and at least one circuit breaking sensing element, wherein the path switch is separately disposed on the relative movement of the first and second magnetic members. The direction enters the end portion, and the disconnecting switch is disposed at a position away from the end portion of the first and second magnetic members, and the path sensing element is disposed at a direction away from the end of the feeding coil, and the breaking sensing element It is divided into the end portion of the feeding coil in the relative movement direction. The concentric common electromagnetic device according to claim 1, wherein the magnetic column group and the coil array are respectively disposed on a relative radius of a moving plate and a static disk, and are provided for a shaft, and wherein the magnetic column The movable plate of the group can rotate synchronously with the shaft, and the static plate of the coil group and the shaft are relatively pivoted. The concentric common electromagnetic device according to claim 1, wherein a width of each of the magnetic gaps of the magnetic array is proportional to a length of the first and second magnetic members of 1:2. The concentric common electromagnetic device according to claim 1, wherein the length of the magnet of the coil component of the coil group and the length of the first and second magnetic members is 3:2. The concentric common electromagnetic device according to claim 1 or 3 or 4, wherein the length of the power supply coil and the inductor coil of the coil array is proportional to the length of the first and second magnetic members is 1:2. The concentric common electromagnetic device according to claim 2, wherein the concentric common electromagnetic device is a disc matrix structure, which is composed of at least three magnetic arrays and at least two sub-distributions arranged on the movable disc. The coil arrays of the static disks are alternately arranged, and the magnetic arrays of the movable disks and the coil rows of the static disks are coaxially opposed to each other. The concentric common electromagnetic device according to claim 6, wherein the position of the coil component of the opposite coil array of the concentric electromagnetic device of the disc matrix structure corresponds to the first and second magnetic members of the magnetic array Misaligned or aligned. The concentric common electromagnetic device according to claim 2, wherein the concentric common electromagnetic device is a ring matrix structure, which is composed of at least two moving disks with magnetic groups and at least one coil. The static disk of the column group is composed, and the static disks of each of the coil rows are disposed between the opposite two movable disks of the magnetic column group, and each of the movable disks is provided with at least two coaxial and magnetic phases of different radii. The column group, and each of the static disks is provided with at least two coaxial and different radii of phase coil groups, and the coil rows of different radii are opposite to the magnetic column groups of the same radius. The concentric common electromagnetic device according to claim 8, wherein the position of the coil component of the phase coil group of the concentric coaxial electromagnetic device of the ring matrix structure corresponds to the first and second magnetic phases of the phase and magnetic column group. Pieces can be arranged in a misaligned or aligned position.